System Basis Chip TLE9261QX Mid-Range System Basis Chip Family Body System IC with Integrated Voltage Regulators, Power Management Functions, HS-CAN Transceiver supporting CAN FD . Featuring Multiple High-Side Switches and High-Voltage Wake Inputs. Data Sheet Rev. 1.1, 2014-09-26 Automotive Power TLE9261QX Table of Contents 1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 2 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 3 3.1 3.2 3.3 3.4 Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Pin Assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Pin Definitions and Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Hints for Unused Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Hints for Alternate Pin Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 4 4.1 4.2 4.3 4.4 General Product Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Thermal Resistance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Current Consumption . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 12 14 15 16 5 5.1 5.1.1 5.1.1.1 5.1.1.2 5.1.2 5.1.3 5.1.4 5.1.5 5.1.6 5.1.7 5.2 5.2.1 5.2.1.1 5.2.1.2 5.2.2 5.2.3 5.3 System Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description of State Machine . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Device Configuration and SBC Init Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Device Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Init Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Sleep Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Restart Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Fail-Safe Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SBC Development Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wake Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cyclic Sense . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Configuration and Operation of Cyclic Sense . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cyclic Sense in Low Power Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Cyclic Wake . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Internal Timer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Supervision Features . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 20 21 22 22 24 25 26 27 28 29 30 31 31 32 35 36 37 37 6 6.1 6.2 6.3 Voltage Regulator 1 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 38 38 39 40 7 7.1 7.2 7.2.1 7.3 Voltage Regulator 2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Short to Battery Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 43 43 44 44 45 8 8.1 8.2 8.2.1 8.2.2 8.3 8.4 External Voltage Regulator 3 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . External Voltage Regulator as Independent Voltage Regulator . . . . . . . . . . . . . . . . . . . . . . . . . . . External Voltage Regulator in Load Sharing Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . External Components . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Calculation of RSHUNT . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 48 48 49 50 51 52 53 Data Sheet 2 Rev. 1.1, 2014-09-26 TLE9261QX Table of Contents 8.5 8.6 Unused Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 53 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 54 9 9.1 9.2 9.2.1 9.2.2 9.2.3 9.2.4 9.2.5 9.3 High-Side Switch . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Over and Under Voltage Switch Off . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Over Current Detection and Switch Off . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Open Load Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . HSx Operation in Different SBC Modes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . PWM and Timer Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 59 59 59 60 60 60 60 61 62 10 10.1 10.2 10.2.1 10.2.2 10.2.3 10.2.4 10.2.5 10.2.6 10.2.7 10.3 High Speed CAN Transceiver . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CAN OFF Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CAN Normal Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CAN Receive Only Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . CAN Wake Capable Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TXD Time-out Feature . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Bus Dominant Clamping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Under Voltage Detection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 63 63 63 65 65 66 66 68 68 68 69 11 11.1 11.2 11.2.1 11.2.2 11.2.2.1 11.2.2.2 11.3 Wake and Voltage Monitoring Inputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Wake Input Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Alternate Measurement Function with WK1 and WK2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 75 75 76 77 78 78 78 79 12 12.1 12.2 Interrupt Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 Block and Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 81 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 83 13 13.1 13.1.1 13.2 Fail Outputs . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Block and Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Purpose I/O Functionality of FO2 and FO3 as Alternate Function . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 84 84 85 86 14 14.1 14.1.1 14.1.2 14.2 14.2.1 14.2.2 14.2.3 14.2.4 14.2.5 14.3 14.4 Supervision Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reset Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Reset Output Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Soft Reset Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Time-Out Watchdog . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Window Watchdog . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Setting Check Sum . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog during SBC Stop Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Watchdog Start in SBC Stop Mode due to Bus Wake . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . VS Power On Reset . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Under Voltage VS and VSHS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 88 88 88 89 90 91 92 92 93 93 94 95 Data Sheet 3 Rev. 1.1, 2014-09-26 TLE9261QX Table of Contents 14.5 14.6 14.6.1 14.6.2 14.7 14.8 14.9 14.9.1 14.9.2 14.9.3 14.10 Over Voltage VSHS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 VCC1 Over-/ Under Voltage and Under Voltage Prewarning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 VCC1 Under Voltage and Under Voltage Prewarning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 95 VCC1 Over Voltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 96 VCC1 Short Circuit and VCC3 Diagnostics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 VCC2 Undervoltage and VCAN Undervoltage . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 97 Thermal Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 Individual Thermal Shutdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 98 Temperature Prewarning . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 SBC Thermal Shutdown . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 99 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 100 15 15.1 15.2 15.3 15.4 15.5 15.5.1 15.6 15.6.1 15.6.2 15.7 Serial Peripheral Interface . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Block Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Failure Signalization in the SPI Data Output . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Bit Mapping . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Control Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . SPI Status Information Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . General Status Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Family and Product Information Register . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 103 103 104 106 108 111 112 130 131 141 142 16 16.1 16.2 16.3 Application Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Application Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ESD Tests . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Thermal Behavior of Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 144 144 148 149 17 Package Outlines . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 151 18 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 152 Data Sheet 4 Rev. 1.1, 2014-09-26 Mid-Range System Basis Chip Family 1 TLE9261QX Overview Scalable System Basis Chip Family • Product family with various products for complete scalable application coverage. • Dedicated Data Sheets are available for the different product variants • Complete compatibility (hardware and software) across the family • TLE9263 with 2 LIN transceivers, 3 voltage regulators • TLE9262 with 1 LIN transceiver, 3 voltage regulators • TLE9261 without LIN transceivers, 3 voltage regulators • TLE9260 without LIN transceivers, 2 voltage regulators • Product variants for 5V (TLE926xQX) and 3.3V (TLE926xQXV33) output voltage for main voltage regulator • CAN Partial Networking variants for 5V (TLE926x-3QX) and 3.3V (TLE926x-3QXV33) output voltage PG-VQFN-48-31 Device Description The TLE9261QX is a monolithic integrated circuit in an exposed pad VQFN-48 (7mm x 7mm) power package with Lead Tip Inspection (LTI) feature to support Automatic Optical Inspection (AOI). The device is designed for various CAN automotive applications as main supply for the microcontroller and as interface for a CAN bus network. To support these applications, the System Basis Chip (SBC) provides the main functions, such as a 5V lowdropout voltage regulator (LDO) for e.g. a microcontroller supply, another 5V low-dropout voltage regulator with off-board protection for e.g. sensor supply, another 5V/3.3V regulator to drive an external PNP transistor, which can be used as an independent supply for off-board usage or in load sharing configuration with the main regulator VCC1, a HS-CAN transceiver supporting CAN FD for data transmission, high-side switches with embedded protective functions and a 16-bit Serial Peripheral Interface (SPI) to control and monitor the device. Also implemented are a configurable timeout / window watchdog circuit with a reset feature, three Fail Outputs and an under voltage reset feature. The device offers low-power modes in order to minimize current consumption on applications that are connected permanently to the battery. A wake-up from the low-power mode is possible via a message on the buses, via the bi-level sensitive monitoring/wake-up inputs as well as via cyclic wake. The device is designed to withstand the severe conditions of automotive applications. Type Package Marking TLE9261QX PG-VQFN-48-31 TLE9261QX Data Sheet 5 Rev. 1.1, 2014-09-26 TLE9261QX Overview Key Features • Very low quiescent current consumption in Stop- and Sleep Mode • Periodic Cyclic Wake in SBC Normal- and Stop Mode • Periodic Cyclic Sense in SBC Normal-, Stop- and Sleep Mode • Low-Drop Voltage Regulator 5V, 250mA • Low-Drop Voltage Regulator 5V, 100mA, protected features for off-board usage • Low-Drop Voltage Regulator, driving an external PNP transistor - 5V in load sharing configuration or 5V/3.3V in stand-alone configuration, protected features for off-board usage. Current limitation by shunt resistor (up to 350mA with 470mΩ external shunt resistor) in stand-alone configuration • High-Speed CAN Transceiver: – fully compliant to ISO11898-2 and ISO11898-5 – suitable for chokeless operation up to 500kbps – supporting CAN FD communication up to 2 Mbps • Fully compliant to “Hardware Requirements for LIN, CAN and FlexRay Interfaces in Automotive Applications” Revision 1.3, 2012-05-04 • Four High-Side Outputs 7Ω typ. • Dedicated supply pin for High-Side Outputs • Two General Purpose High-Voltage In- and Outputs (GPIOs) configurable as add. Fail Outputs, Wake Inputs, Low-Side switches or High-Side switches • Three universal High-Voltage Wake Inputs for voltage level monitoring • Alternate High-Voltage Measurement Function, e.g. for battery voltage sensing • Configurable wake-up sources • Reset Output • Configurable timeout and window watchdog • Up to three Fail Outputs (depending on configuration) • Over temperature and short circuit protection feature • Wide supply input voltage and temperature range • Software compatible to all SBC families TLE926x and TLE927x • Green Product (RoHS compliant) & AEC Qualified • PG-VQFN-48 leadless exposed-pad power package with Lead Tip Inspection (LTI) feature to support Automatic Optical Inspection (AOI) Data Sheet 6 Rev. 1.1, 2014-09-26 TLE9261QX Block Diagram VS VCC3B VS VCC3REF VSHS VCC3SH Block Diagram VCC1 2 VS VCC1 VCC3 HS1 HS2 High Side HS3 HS4 FO1 FO2 VCC2 FO3/TEST Alternative function for FO2/3: GPIO1/2 SDI SDO CLK SPI VCC2 Fail Safe SBC STATE MACHINE CSN INT Interrupt Control Window Watchdog WK1 WK2 RESET GENERATOR WK Alternative function for WK 1/2: Voltage measurement RO VCAN WK WAKE REGISTER TXDCAN CAN cell WK3 RXDCAN CANH WK CANL GND Figure 1 Data Sheet Block Diagram 7 Rev. 1.1, 2014-09-26 TLE9261QX Pin Configuration Pin Configuration 3.1 Pin Assignment 36 RXDCAN 35 TXDCAN 34 N.U. 33 N.U. 32 RO 31 INT 30 CSN 29 SDO 28 SDI 27 CLK 26 N.U. 25 N.U. 3 VCAN 37 GND 38 CANL 39 CANH 40 n.c. 41 N.U. 42 GND 43 N.U. 44 n.c. 45 n.c. 46 FO2 47 FO3/TEST 48 TLE9261 PG-VQFN-48 12 n.c. 11 HS4 10 HS3 9 HS2 8 HS1 7 n.c. 6 n.c. 5 VCC3SH 4 VCC3B 3 VCC3REF 2 n.c. 1 GND Figure 2 Data Sheet 24 WK3 23 WK2 22 WK1 21 FO1 20 GND 19 n.c. 18 VCC2 17 VCC1 16 n.c. 15 VS 14 VS 13 VSHS TLE9261 .vsd Pin Configuration 8 Rev. 1.1, 2014-09-26 TLE9261QX Pin Configuration 3.2 Pin Definitions and Functions Pin Symbol Function 1 GND Ground 2 n.c. not connected; internally not bonded. 3 VCC3REF VCC3REF; Collector connection for external PNP, reference input 4 VCC3B VCC3B; Base connection for external PNP 5 VCC3SH VCC3SH; Emitter connection for external PNP, shunt connection 6 n.c. not connected; internally not bonded. 7 n.c. not connected; internally not bonded. 8 HS1 High Side Output 1; typ. 7Ω 9 HS2 High Side Output 2; typ. 7Ω 10 HS3 High Side Output 3; typ. 7Ω 11 HS4 High Side Output 4; typ. 7Ω 12 n.c not connected; internally not bonded. 13 VSHS Supply Voltage HS and GPIO1/2 in HS configuration; Supply voltage for HighSide Switches modules and respective UV-/OV supervision; Connected to battery voltage with reverse protection diode and filter against EMC; connect to VS if separate supply is not needed 14 VS Supply Voltage; Supply voltage for chip internal supply and voltage regulators; Connected to Battery Voltage with external reverse protection Diode and Filter against EMC 15 VS Supply Voltage; Supply voltage for chip internal supply and voltage regulators; Connected to Battery Voltage with external reverse protection Diode and Filter against EMC 16 n.c. not connected; internally not bonded. 17 VCC1 Voltage Regulator Output 1 18 VCC2 Voltage Regulator Output 2 19 n.c. not connected; internally not bonded. 20 GND GND 21 FO1 Fail Output 1 22 WK1 Wake Input 1; Alternative function: HV-measurement function input pin (only in combination with WK2, see Chapter 11.2.2) 23 WK2 Wake Input 2; Alternative function: HV-measurement function output pin (only in combination with WK1, see Chapter 11.2.2) 24 WK3 Wake Input 3 25 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 26 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 27 CLK SPI Clock Input 28 SDI SPI Data Input; into SBC (=MOSI) 29 SDO SPI Data Output; out of SBC (=MISO) 30 CSN SPI Chip Select Not Input Data Sheet 9 Rev. 1.1, 2014-09-26 TLE9261QX Pin Configuration Pin Symbol Function 31 INT Interrupt Output; used as wake-up flag for microcontroller in SBC Stop or Normal Mode and for indicating failures. Active low. During start-up used to set the SBC configuration. External pull-up sets config 1/3, no external pull-up sets config 2/4. 32 RO Reset Output 33 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 34 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 35 TXDCAN Transmit CAN 36 RXDCAN Receive CAN 37 VCAN Supply Input; for internal HS-CAN cell 38 GND GND 39 CANL CAN Low Bus Pin 40 CANH CAN High Bus Pin 41 n.c. not connected; internally not bonded. 42 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 43 GND Ground 44 N.U. Not Used; Used for internal testing purpose. Do not connect, leave open 45 n.c. not connected; internally not bonded. 46 n.c. not connected; internally not bonded. 47 FO2 Fail Output 2 - Side Indicator; Side indicators 1.25Hz 50% duty cycle output; Open drain. Active LOW. Alternative Function: GPIO1; configurable pin as WK, or LS, or HS supplied by VSHS (default is FO2, see also Chapter 13.1.1) 48 FO3/TEST Fail Output 3 - Pulsed Light Output; Break/rear light 100Hz 20% duty cycle output; Open drain. Active LOW TEST; Connect to GND to activate SBC Software Development Mode; Integrated pull-up resistor. Connect to VS with pull-up resistor or leave open for normal operation. Alternative Function: GPIO2; configurable pin as WK, or LS, or HS supplied by VSHS (default is FO3, see also Chapter 13.1.1) Cooling GND Tab Cooling Tab - Exposed Die Pad; For cooling purposes only, do not use as an electrical ground.1) 1) The exposed die pad at the bottom of the package allows better power dissipation of heat from the SBC via the PCB. The exposed die pad is not connected to any active part of the IC an can be left floating or it can be connected to GND (recommended) for the best EMC performance. Note: all VS Pins must be connected to battery potential or insert a reverse polarity diodes where required; all GND pins as well as the Cooling Tab must be connected to one common GND potential; Data Sheet 10 Rev. 1.1, 2014-09-26 TLE9261QX Pin Configuration 3.3 Hints for Unused Pins It must be ensured that the correct configurations are also selected, i.e. in case functions are not used that they are disabled via SPI: • WK1/2/3: connect to GND and disable WK inputs via SPI • HSx: leave open • CANH/L, RXDCAN, TXDCAN: leave all pins open • RO / FOx: leave open • INT: leave open • TEST: connect to GND during power-up to activate SBC Development Mode; connect to VS or leave open for normal user mode operation • VCC2: leave open and keep disabled • VCC3: See Chapter 8.5 • VCAN: connect to VCC1 • n.c.: not connected; internally not bonded; connect to GND • N.U.: Not Used; Used for internal testing purposes only. Do not connect, leave open, i.e. not connected to any potential on the board. In case N.U. pins are connected on the board an open bridge has to be foreseen to avoid external disturbances. The bridge can be shorted by a 0 Ω resistance if signal is needed. 3.4 Hints for Alternate Pin Functions In case of alternate pin functions, selectable via SPI, it must be ensured that the correct configurations are also selected via SPI, in case it is not done automatically. Please consult the respective chapter. In addition, following topics shall be considered: • WK1..2: The pins can be either used as HV wake / voltage monitoring inputs or for a voltage measurement function (via bit WK_MEAS). In the second case, the WK1..2 pins shall not be used / assigned for any wake detection nor cyclic sense functionality, i.e. WK1 and WK2 must be disabled in the register WK_CTRL_2 and the level information is to be ignored in the register WK_LVL_STAT. • FO2..3: The pins can also be configured as GPIOs in the GPIO_CTRL register. In this case, the pins shall not be used for any fail output functionality. The default function after Power on Reset (POR) is FOx. Data Sheet 11 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics 4 General Product Characteristics 4.1 Absolute Maximum Ratings Table 1 Absolute Maximum Ratings1) Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. VSx, max VSx, max -0.3 – 28 V – P_4.1.1 -0.3 – 40 V Load Dump, max. 400 ms P_4.1.2 VCC1, max VCC2, max -0.3 – 5.5 V – P_4.1.3 -0.3 – 28 V VCC2 = 40V for P_4.1.4 Voltages Supply Voltage (VS, VSHS) Supply Voltage (VS, VSHS) Voltage Regulator 1 Voltage Regulator 2 Load Dump, max. 400 ms; Voltage Regulator 3 (VCC3REF) VCC3REF,max -0.3 – 28 V Load Dump, max. 400 ms; Voltage Regulator 3 (VCC3B) VCC3B,max -0.3 VS – V VCC3B = 40V for Load Dump, max. 400 ms; P_4.1.25 V – P_4.1.26 + 10 Voltage Regulator 3 (VCC3SH) VCC3SH,max Wake Inputs WK1..3 VWK, max VFO1, max VFO2_3, max Fail Pin FO1 Fail Pins FO2, FO3/TEST VCC3REF = 40V for P_4.1.5 VS VS – - 0.30 + 0.30 -0.3 – 40 V – P_4.1.6 -0.3 – 40 V – P_4.1.7 -0.3 – VS V – P_4.1.23 + 0.3 VBUS, max Logic Input Pins (CSN, CLK, VI, max CANH, CANL -27 – 40 V – P_4.1.8 -0.3 – VCC1 V – P_4.1.9 V – P_4.1.10 SDI, TXDCAN) + 0.3 Logic Output Pins (SDO, RO, VO, max INT, RXDCAN) VCAN Input Voltage High Side 1...4 VVCAN, max VHS, max -0.3 VCC1 – + 0.3 -0.3 – 5.5 V – P_4.1.11 -0.3 – VSHS V – P_4.1.12 µA 2) P_4.1.13 P_4.1.14 + 0.3 Currents Wake input WK1 Wake input WK2 IWK1,max IWK2,max 0 -500 – 0 µA 2) Tj Tstg -40 – 150 °C – P_4.1.15 -55 – 150 °C – P_4.1.16 – 500 Temperatures Junction Temperature Storage Temperature Data Sheet 12 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics Table 1 Absolute Maximum Ratings1) (cont’d) Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. -2 – 2 Unit Note / Test Condition Number kV HBM3) P_4.1.17 kV 3) P_4.1.18 4)3) P_4.1.19 ESD Susceptibility VESD,11 ESD Resistivity to GND, HSx VESD,12 ESD Resistivity to GND, VESD,13 ESD Resistivity -2 – 2 HBM -8 – 8 kV HBM -500 – 500 V CDM5) P_4.1.20 V 5) P_4.1.21 CANH, CANL ESD Resistivity to GND ESD Resistivity Pin 1, 12,13,24,25,36,37,48 (corner pins) to GND VESD,21 VESD,22 -750 – 750 CDM 1) 2) 3) 4) Not subject to production test, specified by design. Applies only if WK1 and WK2 are configured as alternative HV-measurement function ESD susceptibility, HBM according to ANSI/ESDA/JEDEC JS-001 (1.5 kΩ, 100 pF) For ESD “GUN” Resistivity 6KV (according to IEC61000-4-2 “gun test” (150pF, 330Ω)), will be shown in Application Information and test report will be provided from IBEE 5) ESD susceptibility, Charged Device Model “CDM” EIA/JESD22-C101 or ESDA STM5.3.1 Notes 1. Stresses above the ones listed here may cause permanent damage to the device. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. 2. Integrated protection functions are designed to prevent IC destruction under fault conditions described in the data sheet. Fault conditions are considered as “outside” normal operating range. Protection functions are not designed for continuous repetitive operation. Data Sheet 13 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics 4.2 Functional Range Table 2 Functional Range Parameter Symbol Supply Voltage VS,func Values Min. Typ. Max. VPOR – 28 Unit Note / Test Condition Number V 1) P_4.2.1 VPOR see section Chapter 14.10 4.75 – 5.25 V – SPI frequency VCAN,func fSPI – – 4 MHz see Chapter 15.7 P_4.2.4 for fSPI,max Junction Temperature Tj -40 – 150 °C – CAN Supply Voltage P_4.2.3 P_4.2.5 1) Including Power-On Reset, Over- and Under voltage Protection Note: Within the functional range the IC operates as described in the circuit description. The electrical characteristics are specified within the conditions given in the related electrical characteristics table. Device Behavior Outside of Specified Functional Range: • 28V < VS,func < 40V: Device will still be functional including the state machine; the specified electrical characteristics might not be ensured anymore. The regulators VCC1/2/3 are working properly, however, a thermal shutdown might occur due to high power dissipation. HSx switches might be turned OFF depending on VSHS_OV configurations. The specified SPI communication speed is ensured; the absolute maximum ratings are not violated, however the device is not intended for continuous operation of VS >28V. The device operation at high junction temperatures for long periods might reduce the operating life time; • VCAN < 4.75V: The undervoltage bit VCAN_UV will be set in the SPI register BUS_STAT_1 and the transmitter will be disabled as long as the UV condition is present; • 5.25V < VCAN < 5.50V: CAN transceiver still functional. However, the communication might fail due to out-ofspec operation; • VPOR,f < VS < 5.5V: Device will still be functional; the specified electrical characteristics might not be ensured anymore. – The voltage regulators will enter the low-drop operation mode (applies for VCC3 only if bit VCC3_VS_ UV_OFF is set), – A VCC1_UV reset could be triggered depending on the Vrtx settings, – HSx switch behavior will depend on the respective configuration: - HS_UV_SD_EN = ‘0’ (default): HSx will be turned OFF for VSHS < VSHS_UV and will stay OFF; - HS_UV_SD_EN = ‘1’: HSx stays on as long as possible. An unwanted over current shut down may occur. OC shut down bit set and the respective HSx switch will stay OFF; – FOx outputs will remain ON if they were enabled before VS > 5.5V, – The specified SPI communication speed is ensured. Data Sheet 14 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics 4.3 Thermal Resistance Table 3 Thermal Resistance1) Parameter Symbol Junction to Soldering Point RthJSP RthJA Junction to Ambient Values Min. Typ. Max. – 6 – – 33 – Unit Note / Test Condition Number K/W Exposed Pad P_4.3.1 K/W 2) P_4.3.2 1) Not subject to production test, specified by design. 2) According to Jedec JESD51-2,-5,-7 at natural convection on FR4 2s2p board for 1.5W. Board: 76.2x114.3x1.5mm³ with 2 inner copper layers (35µm thick), with thermal via array under the exposed pad contacting the first inner copper layer and 300mm2 cooling area on the bottom layer (70µm). Data Sheet 15 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics 4.4 Current Consumption Table 4 Current Consumption Current consumption values are specified at Tj = 25°C, VS = 13.5V, all outputs open (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. – 3.5 6.5 Unit Note / Test Condition Number mA P_4.4.1 VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode Normal Mode current consumption INormal VCC2, CAN, VCC3, HSx = OFF SBC Stop Mode Stop Mode current consumption IStop_1,25 – 44 60 µA 1) Stop Mode current consumption IStop_1,85 – 50 70 µA 1)2) Stop Mode current consumption (high active peak threshold) IStop_2,25 – 64 90 µA 1) Stop Mode current consumption (high active peak threshold) IStop_2,85 – 70 100 µA 1)2) Tj = 85°C; VCC2/3, HSx = OFF; CAN, WKx not wake capable; Watchdog = OFF; no load on VCC1; I_PEAK_TH = ‘1’ P_4.4.36 Sleep Mode current consumption ISleep,25 – 15 25 µA VCC2/3, HSx = OFF; CAN, WKx not wake capable P_4.4.5 Sleep Mode current consumption ISleep,85 – 25 35 µA 2) P_4.4.6 VCC2/3, HSx = OFF; P_4.4.2 CAN, WKx not wake capable; Watchdog = OFF; no load on VCC1; I_PEAK_TH = ‘0’ Tj = 85°C; VCC2/3, HSx = OFF; CAN, WKx not wake capable; Watchdog = OFF; no load on VCC1; I_PEAK_TH = ‘0’ P_4.4.3 VCC2/3, HSx = OFF; P_4.4.35 CAN, WKx not wake capable; Watchdog = OFF; no load on VCC1; I_PEAK_TH = ‘1’ SBC Sleep Mode Data Sheet 16 Tj = 85°C; VCC2/3, HSx = OFF; CAN, WKx not wake capable Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics Table 4 Current Consumption (cont’d) Current consumption values are specified at Tj = 25°C, VS = 13.5V, all outputs open (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Feature Incremental Current Consumption Current consumption for CAN ICAN,rec module, recessive state – 2 3 mA SBC Normal/Stop Mode; CAN Normal Mode; VCC1 connected to VCAN; VTXDCAN = VCC1; no RL on CAN P_4.4.7 Current consumption for CAN ICAN,dom module, dominant state – 3 4.5 mA 2) SBC Normal/Stop Mode; CAN Normal Mode; VCC1 connected to VCAN; VTXDCAN = GND; no RL on CAN P_4.4.8 Current consumption for CAN ICAN,RcvOnly module, Receive Only Mode – 0.9 1.2 mA 2) P_4.4.9 Current consumption for WK1..3 wake capability (all wake inputs) IWake,WKx,25 – 0.2 2 µA 3)4)5) SBC Sleep Mode; P_4.4.13 WK1..3 wake capable (all WKx enabled); CAN = OFF Current consumption for WK1..3 wake capability (all wake inputs) IWake,WKx,85 – 0.5 3 µA 2)3)4)5) SBC Normal/Stop Mode; CAN Receive Only Mode; VCC1 connected to VCAN; VTXDCAN = VCC1; no RL on CAN P_4.4.14 SBC Sleep Mode; Tj = 85°C; WK1..3 wake capable; (all WKx enabled); CAN = OFF Current consumption for CAN IWake,CAN,25 wake capability – 4.5 6 µA 3) SBC Sleep Mode; CAN wake capable; WK1..3 P_4.4.17 Current consumption for CAN IWake,CAN,85 wake capability – 5.5 7 µA 2)3) P_4.4.18 SBC Sleep Mode; Tj = 85°C; CAN wake capable; WK1..3 VCC2 Normal Mode current consumption INormal,VCC2 – 2.5 3.5 mA VS = 5.5 V to 28 V; P_4.4.32 Tj = -40 °C to +150 °C; VCC2 = ON (no load) Current consumption for VCC2 in SBC Sleep Mode Data Sheet ISleep,VCC2,25 – 25 17 35 µA 1)3) SBC Sleep Mode; P_4.4.19 VCC2 = ON (no load); CAN, WK1..3 = OFF Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics Table 4 Current Consumption (cont’d) Current consumption values are specified at Tj = 25°C, VS = 13.5V, all outputs open (unless otherwise specified) Parameter Symbol Values Min. Current consumption for VCC2 in SBC Sleep Mode ISleep,VCC2,85 – Typ. Max. 30 40 Unit Note / Test Condition Number µA 1)2)3) SBC Sleep Mode; P_4.4.20 Tj = 85°C; VCC2 = ON (no load); CAN, WK1..3 = OFF Current consumption for ISleep,VCC3,25 – VCC3 in SBC Sleep Mode in stand-alone configuration 40 60 µA 1)3) Current consumption for ISleep,VCC3,85 – VCC3 in SBC Sleep Mode in stand-alone configuration 50 70 µA 1)2)3) SBC Sleep Mode; P_4.4.22 Tj = 85°C; VCC3 = ON (no load, stand-along config.); CAN, WK1..3 = OFF Current consumption for HSx IStop,HSx,25 in SBC Stop Mode – 525 650 µA 3)6) SBC Stop Mode; Cyclic Sense & HSx= ON (no load); CAN, WK1..3 = OFF P_4.4.33 Current consumption for HSx IStop,HSx,85 in SBC Stop Mode – 575 700 µA 2)3)6) P_4.4.34 SBC Sleep Mode; VCC3 = ON (no load, stand-along config.); CAN, WK1..3 = OFF SBC Stop Mode; P_4.4.21 Tj = 85°C; Cyclic Sense & HSx = ON (no load); CAN, WK1..3 = OFF 3)7)8) Current consumption for cyclic sense function IStop,CS25 – 20 26 µA SBC Stop Mode; WD = OFF Current consumption for cyclic sense function IStop,CS85 – 24 35 µA 2)3)7)8) SBC Stop Mode; P_4.4.27 Tj = 85°C; WD = OFF Current consumption for watchdog active in Stop Mode IStop,WD25 – 20 26 µA 2) SBC Stop Mode; Watchdog running P_4.4.30 Current consumption for watchdog active in Stop Mode IStop,WD85 – 24 35 µA 2) P_4.4.31 Current consumption for active fail outputs (FO1..3) IStop,FOx SBC Stop Mode; P_4.4.23 Tj = 85°C; Watchdog running – 1.0 2.0 mA 2) all SBC Modes; P_4.4.24 Tj = 25°C; FOx = ON (no load); 1) If the load current on VCC1 will exceed the configured VCC1 active peak threshold IVCC1,Ipeak1,r or IVCC1,Ipeak2,r, the current consumption will increase by typ. 2.9mA to ensure optimum dynamic load behavior. Same applies to VCC2. For VCC3 the current consumption will increase by typ. 1.4mA. See also Chapter 6, Chapter 7, Chapter 8. 2) Not subject to production test, specified by design. 3) Current consumption adders of features defined for SBC Sleep Mode also apply for SBC Stop Mode and vice versa (unless otherwise specified). Data Sheet 18 Rev. 1.1, 2014-09-26 TLE9261QX General Product Characteristics 4) No pull-up or pull-down configuration selected. 5) The specified WKx current consumption adder for wake capability applies regardless how many WK inputs are activated. 6) A typ. 75µA / max 125µA (Tj = 85°C) adder applies for every additionally activated HSx switch in SBC Stop Mode; In SBC Normal Mode every HSx switch consumes the typ. 75µA / max 125µA (Tj = 85°C) without the initial adder because the biasing is already enabled. 7) HS1 used for cyclic sense, Timer 2, 20ms period, 0.1ms on-time, no load on HS1. In general the current consumption adder for cyclic sense in SBC Stop Mode can be calculated with below equation: IStop,CS = 18µA + (525µA *tON/TPer) 8) Also applies to Cyclic Wake Note: There is no additional current consumption contribution due to PWM generators. Data Sheet 19 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5 System Features This chapter describes the system features and behavior of the TLE9261QX: • State machine • SBC mode control • Device configuration • State of supply and peripherals • System functions such as cyclic sense or cyclic wake • Supervision and diagnosis functions The System Basis Chip (SBC) offers six operating modes: • SBC Init Mode: Power-up of the device and after a soft reset, • SBC Normal Mode: The main operating mode of the device, • SBC Stop Mode: The first-level power saving mode with the main voltage regulator VCC1 enabled, • SBC Sleep Mode: The second-level power saving mode with VCC1 disabled, • SBC Restart Mode: An intermediate mode after a wake event from SBC Sleep or Fail-Safe Mode or after a failure (e.g. WD failure, VCC1 under voltage reset) to bring the microcontroller into a defined state via a reset. Once the failure condition is not present anymore the device will automatically change to SBC Normal Mode after a delay time (tRD1). • SBC Fail-Safe Mode: A safe-state mode after critical failures (e.g. WD failure, VCC1 under voltage reset) to bring the system into a safe state and to ensure a proper restart of the system. VCC1 is disabled. It is a permanent state until either a wake event (via CAN or WKx) occurs or the over temperature condition is not present anymore. A special mode, called SBC Development Mode, is available during software development or debugging of the system. All above mentioned operating modes can be accessed in this mode. However, the watchdog counter is stopped and does not need to be triggered. This mode can be accessed by setting the TEST pin to GND during SBC Init Mode. The device can be configured via hardware (external component) to determine the device behavior after a watchdog trigger failure. See Chapter 5.1.1 for further information. The System Basis Chip is controlled via a 16-bit SPI interface. A detailed description can be found in Chapter 15.The configuration as well as the diagnosis is handled via the SPI. The SPI mapping of the TLE9261QX is compatible to other devices of the TLE926x and TLE927x families. Data Sheet 20 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1 Block Description of State Machine The different SBC Modes are selected via SPI by setting the respective SBC MODE bits in the register M_S_CTRL. The SBC MODE bits are cleared when going through SBC Restart Mode and thus always show the current SBC mode. First battery connection SBC Soft Reset SBC Init Mode * Config.: settings can be changed in this SBC mode ; (Long open window) Fixed: settings stay as defined in SBC Normal Mode VCC1 ON VCC2 OFF FOx inact. CAN(3) OFF WD Cyc. Sense OFF Config. VCC3 OFF * The SBC Development Mode is a super set of state machine where the WD timer is stopped and CAN behavior differs in SBC Init Mode . Otherwise, there are no differences in behavior . Any SPI command Cyc. Wake HSx OFF OFF SBC Normal Mode VCC1 ON VCC2 config. FOx act/inact Automatic Reset is released WD starts with long open window WD Cyc. Sense config. config. VCC3 config. (3) CAN config. SPI cmd HSx Cyc. Wake config. config. SPI cmd SPI cmd SBC Stop Mode SBC Sleep Mode VCC1 over voltage Config 1/3 (if VCC_OV_RST set) Watchdog Failure: Config 1/3 & 1st WD failure in Config4 VCC2 fixed FOx fixed CAN VCC3 Fixed / OFF Wake capable /off WD Cyc. Sense OFF. fixed VCC1 ON VCC2 fixed HSx Cyc. Wake fixed OFF FOx fixed CAN fixed VCC3 fixed WD fixed Cyc. Sense HSx fixed Cyc. Wake fixed fixed Wake up event SBC Restart Mode (RO pin is asserted) VCC1 ON/ ramping FOx(5) VCC1 Undervoltage VCC1 OFF (2) WD trigger active/ fixed VCC2 OFF CAN VCC3 (2) fixed/ ramping (4) woken / OFF WD OFF Cyc. Sense HSx OFF Cyc. Wake After 4 consecutive VCC 1 under voltage events (if VS > VS_UV) VCC1 over voltage Config 2/4 (if VCC_OV_RST set) OFF OFF SBC Fail-Safe Mode (1) After Fail-Safe Mode entry, the device will stay for at least typ . 1s in this mode (with RO low) after a TSD2 event and min. typ. 100ms after other Fail- Safe Events. Only then the device can leave the mode via a wake-up event. Wake events are stored during this time. VCC1 OFF CAN, WKx wake-up event OR Release of over temperature TSD2 after tTSD2 (5) FOx active VCC2 OFF CAN Wake capable VCC3 OFF (1) TSD2 event, WD OFF Cyc. Sense HSx OFF Cyc. Wake OFF OFF 1st Watchdog Failure Config 2, 2nd Watchdog Failure, Config 4 VCC1 Short to GND (2) according to VCC3 configuration (3) For SBC Development Mode CAN/VCC2 are ON in SBC Init Mode and stay ON when going from there to SBC Normal Mode (4) See chapter CAN for detailed behavior in SBC Restart Mode (5) See Chapter 5.1.5 and 13.1 for detailed FOx behavior Figure 3 Data Sheet State Diagram showing the SBC Operating Modes 21 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.1 Device Configuration and SBC Init Mode The SBC starts up in SBC Init Mode after crossing the power-on reset VPOR,r threshold (see also Chapter 14.3) and the watchdog will start with a long open window (tLW). During this power-on phase following configurations are stored in the device: • The device behavior regarding a watchdog trigger failure and a VCC1 over voltage condition is determined by the external circuitry on the INT pin (see below) • The selection of the normal device operation or the SBC Software Development Mode (watchdog disabled for debugging purposes) will be set depending on the voltage level of the FO3/TEST pin (see also Chapter 5.1.7). 5.1.1.1 Device Configuration The configuration selection is intended to select the SBC behavior regarding a watchdog trigger failure. Depending on the requirements of the application, the VCC1 output shall be switched OFF and the device shall go to SBC Fail-Safe Mode in case of a watchdog failure (1 or 2 fails). To set this configuration (Config 2/4), the INT pin does not need an external pull-up resistor. In case VCC1 should not be switched OFF (Config 1/3), the INT pin needs to have an external pull-up resistor connected to VCC1 (see application diagram in Chapter 16.1). Figure 5 shows the timing diagram of the hardware configuration selection. The hardware configuration is defined during SBC Init Mode. The INT pin is internally pulled LOW with a weak pull-down resistor during the reset delay time tRD1, i.e.after VCC1 crosses the reset threshold VRT1 and before the RO pin goes HIGH. The INT pin is monitored during this time (with a continuos filter time of tCFG_F) and the configuration (depending on the voltage level at INT) is stored at the rising edge of RO. Note: If the POR bit is not cleared then the internal pull-down resistor will be reactivated every time RO is pulled LOW the configuration will be updated at the rising edge of RO. Therefore it is recommended to clear the POR bit right after initialization. In case there is no stable signal at INT, then the default value ‘0’ will taken as the config select value = SBC Fail-Safe Mode. VS VPOR,r t VCC1 VRT1,r t RO Continuous Filtering with t CFG_F tRD1 t Configuration selection monitoring period Figure 4 Data Sheet Hardware Configuration Selection Timing Diagram 22 Rev. 1.1, 2014-09-26 TLE9261QX System Features There are four different device configurations (Table 5) available defining the watchdog failure and the VCC1 over voltage behavior. The configurations can be selected via the external connection on the INT pin and the SPI bit CFG in the HW_CTRL register (see also Chapter 15.4): • • CFGP = ‘1’: Config 1 and Config 3: – A watchdog trigger failure leads to SBC Restart Mode and depending on CFG the Fail Outputs (FOx) are activated after the 1st (Config 1) or 2nd (Config 3) watchdog trigger failure; – A VCC1 over voltage detection will lead to SBC Restart Mode if VCC1_OV_RST is set. VCC1_ OV will be set and the Fail Outputs are activated; CFGP = ‘0’: Config 2 and Config 4: – A watchdog trigger failure leads to SBC Fail-Safe Mode and depending on CFG the Fail Outputs (FOx) are activated after the 1st (Config 2) or 2nd (Config 4) watchdog trigger failure. The first watchdog trigger failure in Config 4 will lead to SBC Restart Mode; – A VCC1 over voltage detection will lead to SBC Fail-Safe Mode if VCC1_OV_RST is set. VCC1_ OV will be set and the Fail Outputs are activated; The respective device configuration can be identified by reading the SPI bit CFG in the HW_CTRL register and the CFGP bit in the WK_LVL_STAT register. Table 5 shows the configurations and the device behavior in case of a watchdog trigger failure: Table 5 Watchdog Trigger Failure Configuration Config INT Pin (CFGP) SPI Bit CFG Event FOx Activation SBC Mode Entry 1 External pull-up 1 1 x Watchdog Failure after 1st WD Failure SBC Restart Mode 2 No ext. pull-up 1 1 x Watchdog Failure after 1st WD Failure SBC Fail-Safe Mode 3 External pull-up 0 2 x Watchdog Failure after 2nd WD Failure SBC Restart Mode 4 No ext. pull-up 0 2 x Watchdog Failure after 2nd WD Failure SBC Fail-Safe Mode Table 6 shows the configurations and the device behavior in case of a VCC1 over voltage detection when VCC1_OV_RST is set: Table 6 Device Behavior in Case of VCC1 Over Voltage Detection Config INT Pin (CFGP) CFG Bit VCC1_O Event V_RST VCC1 _ OV FOx Activation SBC Mode Entry 1-4 any value x 0 1 x VCC1 OV 1 no FOx activation unchanged 1 External pull-up 1 1 1 x VCC1 OV 1 after 1st VCC1 OV SBC Restart Mode 2 No ext. pull-up 1 1 1 x VCC1 OV 1 after 1st VCC1 OV SBC Fail-Safe Mode 3 External pull-up 0 1 1 x VCC1 OV 1 after 1st VCC1 OV SBC Restart Mode 4 No ext. pull-up 1 1 x VCC1 OV 1 after 1st VCC1 OV SBC Fail-Safe Mode 0 The respective configuration will be stored for all conditions and can only be changed by powering down the device (VS < VPOR,f). Data Sheet 23 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.1.2 SBC Init Mode In SBC Init Mode, the device waits for the microcontroller to finish its startup and initialization sequence. In the SBC Init Mode any valid SPI command will bring the SBC to SBC Normal Mode. During the long open window the watchdog has to be triggered. Thereby the watchdog will be automatically configured. A missing watchdog trigger during the long open window will cause a watchdog failure and the device will enter SBC Restart Mode. Wake events are ignored during SBC Init Mode and will therefore be lost. Note: Any SPI command will bring the SBC to SBC Normal Mode even if it is a illegal SPI command (see Chapter 15.2). Note: For a safe start-up, it is recommended to use the first SPI command to trigger and to configure the watchdog (see Chapter 14.2). Note: At power up no VCC1_UV will be issued nor will FOx be triggered as long as VCC1 is below the VRT,x threshold and if VS is below the VCC1 short circuit detection threshold VS,UV. The RO pin will be kept low as long as VCC1 is below the selected VRT,x threshold. Data Sheet 24 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.2 SBC Normal Mode The SBC Normal Mode is the standard operating mode for the SBC. All configurations have to be done in SBC Normal Mode before entering a low-power mode (see also Chapter 5.1.6 for the device configuration defining the Fail-Safe Mode behavior). A wake-up event on CAN and WKx will create an interrupt on pin INT - however, no change of the SBC mode will occur. The configuration options are listed below: • VCC1 is active • VCC2 can be switched ON or OFF (default = OFF) • VCC3 is configurable (OFF coming from SBC Init Mode; as previously programmed coming from SBC Restart Mode) • CAN is configurable (OFF coming from SBC Init Mode; OFF or wake capable coming from SBC Restart Mode, see also Chapter 5.1.5) • HS Outputs can be switched ON or OFF (default = OFF) or can be controlled by PWM; HS Outputs are OFF coming from SBC Restart Mode • Wake pins show the input level and can be selected to be wake capable (interrupt) • Cyclic sense can be configured with HS1...4 and Timer1 or Timer 2 • Cyclic wake can be configured with Timer1 or Timer2 • Watchdog is configurable • All FOx outputs are OFF by default. Coming from SBC Restart Mode FOx can be active (due to a failure event, e.g. watchdog trigger failure, VCC1 short circuit, etc.) or inactive (no failure occurred) In SBC Normal Mode, there is the possibility of testing the FO outputs, i.e. to verify if setting the FO pin to low will create the intended behavior within the system. The FO output can be enabled and then disabled again by the microcontroller by setting the FO_ON SPI bit. This feature is only intended for testing purposes. Data Sheet 25 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.3 SBC Stop Mode The SBC Stop Mode is the first level technique to reduce the overall current consumption by setting the voltage regulators VCC1, VCC2 and VCC3 into a low-power mode. In this mode VCC1 is still active and supplying the microcontroller, which can enter a power down mode. The VCC2 supply, CAN mode as well as the HSx outputs can be configured to stay enabled. All kind of settings have to be done before entering SBC Stop Mode. In SBC Stop Mode any kind of SPI WRITE commands are ignored and the SPI_FAIL bit is set, except for changing to SBC Normal Mode, triggering a SBC Soft Reset, refreshing the watchdog as well as for reading and clearing the SPI status registers. A wake-up event on CAN and WKx will create an interrupt on pin INT - however, no change of the SBC mode will occur. The configuration options are listed below: • VCC1 is ON • VCC2 is fixed as configured in SBC Normal Mode • VCC3 is fixed as configured in SBC Normal Mode • CAN mode is fixed as configured in SBC Normal Mode • WK pins are fixed as configured in SBC Normal Mode • HS Outputs are fixed as configured in SBC Normal Mode • Cyclic sense is fixed as configured in SBC Normal Mode • Cyclic wake is fixed as configured in SBC Normal Mode • Watchdog is fixed as configured in SBC Normal Mode • SBC Soft Reset can be triggered • FOx outputs are fixed, i.e. the state from SBC Normal Mode is maintained An interrupt is triggered on the pin INT when SBC Stop Mode is entered and not all wake source signalization flags from WK_STAT_1 and WK_STAT_2 were cleared. Note: If switches are enabled during SBC Stop Mode, e.g. HSx on with or without PWM, then the SBC current consumption will increase (see Chapter 4.4). Note: It is not possible to switch directly from SBC Stop Mode to SBC Sleep Mode. Doing so will also set the SPI_FAIL flag and will bring the SBC into Restart Mode. Note: When WK1 and WK2 are configured for the alternate measurement function (WK_MEAS = 1) then the wake inputs cannot be selected as wake input sources. Data Sheet 26 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.4 SBC Sleep Mode The SBC Sleep Mode is the second level technique to reduce the overall current consumption to a minimum needed to react on wake-up events or for the SBC to perform autonomous actions (e.g. cyclic sense). In this mode, VCC1 is OFF and not supplying the microcontroller anymore.The VCC2 supply as well as the HSx outputs can be configured to stay enabled. The settings have to be done before entering SBC Sleep Mode. A wake-up event on CAN or WKx will bring the device via SBC Restart Mode into SBC Normal Mode again and signal the wake source. The configuration options are listed below: • VCC1 is OFF • VCC2 is fixed as configured in SBC Normal Mode • VCC3 is fixed or OFF as configured in SBC Normal Mode • CAN mode changes automatically from ON or Receive Only Mode to wake capable mode or can be selected to be OFF • WK pins are fixed as configured in SBC Normal Mode • HS Outputs are fixed as configured in SBC Normal Mode • Cyclic sense is fixed as configured in SBC Normal Mode • Cyclic wake is not available • Watchdog is OFF • FOx outputs are fixed, i.e. the state from SBC Normal Mode is maintained • As VCC1 is OFF during SBC Sleep Mode, no SPI communication is possible; • The Sleep Mode entry is signalled in the SPI register DEV_STAT with the bit DEV_STAT It is not possible to switch all wake sources off in SBC Sleep Mode. Doing so will set the SPI_FAIL flag and will bring the SBC into SBC Restart Mode. In order to enter SBC Sleep Mode successfully, all wake source signalization flags from WK_STAT_1 and WK_STAT_2 need to be cleared. A failure to do so will result in an immediate wake-up from SBC Sleep Mode by going via SBC Restart to Normal Mode. All settings must be done before entering SBC Sleep Mode. Note: If switches are enabled during SBC Sleep mode, e.g. HSx on with or without PWM, then the SBC current consumption will increase (see Chapter 4.4). Note: Cyclic Sense function will not work properly anymore in case of an overcurrent, over temperature, under- or overvoltage (in case function is selected) event because the respective HS switch will be disabled. Note: When WK1 and WK2 are configured for the alternate measurement function (WK_MEAS = 1) then the wake inputs cannot be selected as wake input sources. Data Sheet 27 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.1.5 SBC Restart Mode There are multiple reasons to enter the SBC Restart Mode. The purpose of the SBC Restart Mode is to reset the microcontroller: • in case of under voltage on VCC1 in SBC Normal and in SBC Stop Mode, • in case of over voltage on VCC1 if the bit VCC1_OV_RST is set and if CFGP = ‘1’, • due to 1st incorrect Watchdog triggering (only if Config1, Config3 or Config 4 is selected, otherwise SBC FailSafe Mode is immediately entered), • In case of a wake event from SBC Sleep or SBC Fail-Safe Mode or a release of over temperature shutdown (TSD2) out of SBC Fail-Safe Mode this transition is used to ramp up VCC1 after a wake in a defined way. From SBC Restart Mode, the SBC goes automatically to SBC Normal Mode, i.e the mode is left automatically by the SBC without any microcontroller influence. The SBC MODE bits are cleared. As shown in Figure 42 the Reset Output (RO) is pulled low when entering Restart Mode and is released at the transition to Normal Mode after the reset delay time (tRD1). The watchdog timer will start with a long open window starting from the moment of the rising edge of RO and the watchdog period setting in the register WD_CTRL will be changed to the respective default value ‘100’. Leaving the SBC Restart Mode will not result in changing / deactivating the Fail outputs. The behavior of the blocks is listed below: • All FOx outputs are activated in case of a 1st watchdog trigger failure (if Config1 or Config2 is selected) or in case of VCC1 over voltage detection (if VCC1_OV_RST is set) • VCC1 is ON or ramping up • VCC2 will be disabled if it was activated before • VCC3 is fixed or ramping as configured in SBC Normal Mode • CAN is “woken” due to a wake event or OFF depending on previous SBC and transceiver mode (see also Chapter 10). It is wake capable when it was in CAN Normal-, Receive Only or wake capable mode before SBC Restart Mode • HS Outputs will be disabled if they were activated before • RO is pulled low during SBC Restart Mode • SPI communication is ignored by the SBC, i.e. it is not interpreted • The Restart Mode entry is signalled in the SPI register DEV_STAT with the bits DEV_STAT Table 7 Reasons for Restart - State of SPI Status Bits after Return to Normal Mode Prev. SBC Mode Event DEV_STAT WD_FAIL VCC1_UV VCC1_OV VCC1_SC Normal 1x Watchdog Failure 01 01 x x x Normal 2x Watchdog Failure 01 10 x x x Normal VCC1 under voltage reset 01 xx 1 x x Normal VCC1 over voltage reset 01 xx x 1 x Stop 1x Watchdog Failure 01 01 x x x Stop 2x Watchdog Failure 01 10 x x x Stop VCC1 under voltage reset 01 xx 1 x x Stop VCC1 over voltage reset 01 xx x 1 x Sleep Wake-up event 10 xx x x x Fail-Safe Wake-up event 01 see “Reasons for Fail Safe, Table 8” Note: An over voltage event on VCC1 will only lead to SBC Restart Mode if the bit VCC1_OV_RST is set and if CFGP = ‘1’ (Config 1/3). Data Sheet 28 Rev. 1.1, 2014-09-26 TLE9261QX System Features Note: The content of the WD_FAIL bits will depend on the device configuration, e.g. 1 or 2 watchdog failures. 5.1.6 SBC Fail-Safe Mode The purpose of this mode is to bring the system in a safe status after a failure condition by turning off the VCC1 supply and powering off the microcontroller. After a wake event the system is then able to restart again. The Fail-Safe Mode is automatically reached for following events: • after an SBC thermal shutdown (TSD2) (see also Chapter 14.9.3), • in case of over voltage on VCC1 if the bit VCC1_OV_RST is set and if CFGP = ‘0’, • after a 1st incorrect watchdog trigger in Config2 (CFG = 1) and after a 2nd incorrect watchdog trigger in Config4 (CFG = 0) (see also Chapter 5.1.1), • if VCC1 is shorted to GND (see also Chapter 14.7), • After 4 consecutive VCC1 under voltage events (only if VS > VS,UV, see Chapter 14.6). In this case, the default wake sources (CAN, WK1...3, see also registers WK_CTRL_2, BUS_CTRL_1) are activated, the wake events are cleared in the register WK_STAT_1, and all output drivers and all voltage regulators are switched off. When WK1 and WK2 are configured for the alternate measurement function (WK_MEAS = 1) then WK1 and WK2 will stay configured for the measurement function when SBC Fail-Safe Mode is entered, i.e. they will not be activated as wake sources. The SBC Fail-Safe Mode will be maintained until a wake event on the default wake sources occurs. To avoid any fast toggling behavior a filter time of typ. 100ms (tFS,min) is implemented. Wake events during this time will be stored and will automatically lead to entering SBC Restart Mode after the filter time. In case of an VCC1 over temperature shutdown (TSD2) the SBC Restart Mode will be reached automatically after a filter time of typ. 1s (tTSD2) without the need of a wake event. Leaving the SBC Fail-Safe Mode will not result in deactivation of the Fail Output pins. The following functions are influenced during SBC Fail-Safe Mode: • All FOx outputs are activated (see also Chapter 13) • VCC1 is OFF • VCC2 is OFF • VCC3 is OFF • CAN is wake capable • HS Outputs are OFF • WK pins are wake capable through static sense (with default 16µs filter time) • Cyclic sense and Cyclic wake is disabled • SPI communication is disabled because VCC1 is OFF • The Fail-Safe Mode activation is signalled in the SPI register DEV_STAT with the bits FAILURE and DEV_STAT Data Sheet 29 Rev. 1.1, 2014-09-26 TLE9261QX System Features Table 8 Reasons for Fail-Safe - State of SPI Status Bits after Return to Normal Mode Prev. SBC Failure Event Mode DEV_ STAT TSD2 WD_ FAIL VCC1_ UV VCC1_ UV_FS VCC1_ OV VCC1_ SC Normal 1 x Watchdog Failure 01 x 01 x x x x Normal 2 x Watchdog Failure 01 x 10 x x x x Normal TSD2 01 1 xx x x x x Normal VCC1 short to GND 01 x xx 1 x x 1 Normal 4x VCC1 UV 01 x xx 1 1 x x Normal VCC1 over voltage 01 x xx x x 1 x Stop 1 x Watchdog Failure 01 x 01 x x x x Stop 2 x Watchdog Failure 01 x 10 x x x x Stop TSD2 01 1 xx x x x x Stop VCC1 short to GND 01 x xx 1 x x 1 Stop 4x VCC1 UV 01 x xx 1 1 x x Stop VCC1 over voltage 01 x xx x x 1 x Note: An over voltage event on VCC1 will only lead to SBC Fail-Safe Mode if the bit VCC1_OV_RST is set and if CFGP = ‘0’ (Config 2/4). Note: The content of the WD_FAIL bits will depend on the device configuration, e.g. 1 or 2 watchdog failures. Note: See Chapter 14.6.1 for detailed description of the 4x VCC1 under voltage behavior. 5.1.7 SBC Development Mode The SBC Development Mode is used during the development phase of the module. It is especially useful for software development. Compared to the default SBC user mode operation, this mode is a super set of the state machine. The device will start also in SBC Init Mode and it is possible to use all the SBC Modes and functions with following differences: • Watchdog is stopped and does not need to be triggered. Therefore no reset is triggered due to watchdog failure • SBC Fail-Safe and SBC Restart Mode are not reached due to watchdog failure but the other reasons to enter these modes are still valid • CAN and VCC2 default value in SBC INIT MODE and entering SBC Normal Mode from SBC Init Mode is ON instead of OFF The SBC Software Development Mode is reached automatically if the FO3/TEST pin is set and kept LOW during SBC Init Mode. The voltage level monitoring is started as soon as VS > VPOR,f. The Software Development Mode is configured and maintained if SBC Init Mode is left by sending any SPI command while FO3/TEST is LOW. In case the FO3/TEST level will be HIGH for longer than tTEST during the monitoring period then the SBC Development Mode is not reached . The SBC will remain in this mode for all conditions and can only be left by powering down the device (VS < VPOR,f). Data Sheet 30 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.2 Wake Features Following wake sources are implemented in the device: • Static Sense: WK inputs are permanently active (see Chapter 11) • Cyclic Sense: WK inputs only active during on-time of cyclic sense period (see below) • Cyclic Wake: internal wake source controlled via internal timer (see below) • CAN wake: Wake-up via CAN message (see Chapter 10) 5.2.1 Cyclic Sense The cyclic sense feature is intended to reduce the quiescent current of the device and the application. In the cyclic sense configuration, one or more high-side drivers are switched on periodically controlled by TIMER1_CTRL and TIMER2_CTRL. The respective high-side drivers supply external circuitries e.g. switches and/or resistor arrays, which are connected to one or more wake inputs (see Figure 5). Any edge change of the WKx input signal during the on-time of the cyclic sense period causes a wake. Depending on the SBC mode, either the INT is pulled low (SBC Normal Mode and Stop Mode) or the SBC is woken enabling the VCC1 (after SBC Sleep and SBC Fail-Safe Mode). HS x High Side 1-4 HS_CTRL Signals GND Switching Circuitry TIMER_CTRL Period / On-Time INT SBC STATE MACHINE to uC WK x Figure 5 Data Sheet WK 1-3 WK_FLT_CTRL Cyclic Sense Working Principle 31 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.2.1.1 Configuration and Operation of Cyclic Sense The correct sequence to configure the cyclic sense is shown in Figure 6. All the configurations have to be performed before the on-time is set in the TIMERx_CTRL registers. The settings “OFF / LOW” and “OFF / HIGH” define the voltage level of the respective HS driver before the start of the cyclic sense. The intention of this selection is to avoid an unintentional wake due to a voltage level change at the start of the cyclic sense. Cyclic Sense (=TimerX) will start as soon as the respective on-time has been selected independently from the assignment of the HS and filter configuration. The selection of the respective timer (Config C/D see Chapter 11.2.1) must therefore be done before starting the timer. The correct configuration sequence is as follows: • Configure the initial level • Mapping of a Timer to the respective HSx outputs • Configuring the respective filter timing and WK pins • Configuring the timer period and on-time Cyclic Sense Configuration Assign TIMERx_ON to OFF/Low or OFF/High in TIMERx_CTRL Timer1, Timer2 Assign Timer to selected HS switch in HS_CTRL_X Timer1, Timer2 Enable WKx as wake source with configured Timer in WK_FLT_CTRL WK1, WK2, WK3 with above selected timer Select WKx pull-up / pull-down configuration in WK_PUPD_CTRL No pull-up/-down, pull-down or pull-up selected, automatic switching Select Timer Period and desired On-Time in TIMERx_CTRL Period : 10, 20, 50, 100, 200ms, 1s, 2s On-Time: 0.1, 0.3, 1.0, 10, 20ms Changing the settings can be done on the fly, changes become effective at the next on-time or period Cyclic Sense starts / ends by setting / clearing On-time Figure 6 Cyclic Sense: Configuration and Sequence Note: All configurations of period and on-time can be selected. However, recommended on-times for cyclic sense are 0.1ms, 0.3ms and 1ms. The SPI_FAIL will be set if the on-time is longer than the period. Data Sheet 32 Rev. 1.1, 2014-09-26 TLE9261QX System Features The first sample of the WK input value (HIGH or LOW) is taken as the reference for the next cycle. A change of the WK input value between the first and second cycle recognized during the on-time of the second cycle will cause a wake from SBC Sleep Mode or an interrupt during SBC Normal or SBC Stop Mode. A filter time of 16µs is implemented to avoid a parasitic wake-up due to transients or EMC disturbances. The filter time tFWK1 is triggered right at the end of the selected on-time and a wake signal is recognized if: • the input level will not cross the switching threshold level of typ. 3V during the selected filter time (i.e. if the signal will keep the HIGH or LOW level) and • there was an input level change between the current and previous cycle Data Sheet 33 Rev. 1.1, 2014-09-26 TLE9261QX System Features A wake event due to cyclic sense in SBC Mode will set the respective bit WK1_WU, WK2_WU, or WK3_WU. During Cyclic Sense, WK_LVL_STAT is updated only with the sampled voltage levels of the WKx pins in SBC Normal or SBC Stop Mode. The functionality of the sampling and different scenarios are depicted in Figure 7 to Figure 9. The behavior in SBC Stop and SBC Sleep Mode is identical except that in Stop Mode INT will be triggered to signal a change of WK input levels and in SBC Sleep Mode, VCC1 will power-up instead. HS on Cyclic Sense Periode HS switch Filter time tFWK1 Filter time tFWK1 On Time t 1st sample taken as reference Figure 7 Wake detection possible on 2nd sample Wake Input Timing HS Filter time High Low Switch open closed WK High Low INT n-1 n Learning Cycle WKn-1= High WKn= Low WKn ≠WKn-1 wake event n+1 WKn+1 = Low WKn = WKn+1 no wake n+2 WKn+2 = High WKn+2 ≠WK n+1 wake event High Low Figure 8 Data Sheet INT & WK Bit Set Cyclic Sense Example in SBC Stop Mode, HSx starts “OFF”/LOW, GND based WKx input 34 Rev. 1.1, 2014-09-26 TLE9261QX System Features HS Filter time High Low Switch Spike open closed WK High Low n-1 VCC1 n Learning Cycle WKn-1 = Low High n+1 WKn= Low WKn = WK n-1 no wake event WKn = WKn+1 = Low (but ignored because change during filter time ) WKn = WKn+1 no wake event Transition to: SBC Normal Mode SBC Sleep Mode Low INT & WK Bit Set Start of Cyclic Sense Figure 9 n+2 WKn+2= High WKn+2 ≠WK n+1 wake event Cyclic Sense Example in SBC Sleep Mode, HSx starts “OFF”/HIGH, GND based WKx input The cyclic sense function will not work properly anymore in case of following conditions: • in case SBC Fail-Safe Mode is entered: The respective HS Switch will be disabled and the respective wake pin will be changed to static sensing • In SBC Normal, Stop, or Sleep Mode in case of an overcurrent, overtemperature, under- or overvoltage (in case function is selected) event: the respective HS switch will be disabled Note: The internal timers for cyclic sense are not disabled automatically in case the HS switch is turned off due to above mentioned failures.This must be considered to avoid loss of wake events. 5.2.1.2 Cyclic Sense in Low Power Mode If cyclic sense is intended for SBC Stop or SBC Sleep Mode mode, it is necessary to activate the cyclic sense in SBC Normal Mode before going to the low power mode. A wake event due to cyclic sense will set the respective bit WK1_WU, WK2_WU or WK3_WU. In Stop Mode the wake event will trigger an interrupt, in Sleep Mode the wake event will send the device via Restart Mode to Normal Mode. Before returning to SBC Sleep Mode, the wake status register WK_STAT_1 and WK_STAT_2 needs to be cleared. Trying to go to SBC Sleep mode with uncleared wake flags, such as WKx_WU the SBC will directly wake-up from Sleep Mode by going via Restart Mode to Normal Mode, a reset is issued. The WKx_WU bit is seen as source for the wake. This is implemented in order not to loose an wake event during the transition. Data Sheet 35 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.2.2 Cyclic Wake The cyclic wake feature is intended to reduce the quiescent current of the device and application. For the cyclic wake feature one or both timers are configured as internal wake-up source and will periodically trigger an interrupt in SBC Normal and SBC Stop Mode. The correct sequence to configure the cyclic wake is shown in Figure 10. The sequence is as follows: • First, disable the timers to ensure that there is not unintentional interrupt when activating cyclic wake, • Enable Timer1 and/or Timer2 as a wake-up source in the register WK_CTRL_1, • Configure the respective period Timer1 and/or Timer2. Also an on-time (any value) must be selected to start the cyclic wake even if the value is ignored. Cyclic Wake Configuration Disable Timer1 and/or Timer2 as a wake source in WK_CTRL_1 To avoid unintentional interrupts Select Timer Period and any On-Time in TIMERX_CTRL Periods : 10, 20, 50, 100, 200 ms, 1s, 2s On-times: any (OFF/LOW & OFF/HIGH are not allowed ) Select Timer1 and/or Timer2 as a wake source in WK_CTRL_1 No interrupt will be generated , if the timer is not enabled as a wake source Cyclic Wake starts / ends by setting / clearing On-time INT is pulled low at every rising edge of On-time except first one Figure 10 Cyclic Wake: Configuration and Sequence As in cyclic sense, the cyclic wake function will start as soon as the on-time is configured. An interrupt is generated for every start of the on time except for the very first time when the timer is started Data Sheet 36 Rev. 1.1, 2014-09-26 TLE9261QX System Features 5.2.3 Internal Timer The integrated Timer1 and Timer2 are typically used to wake up the microcontroller periodically (cyclic wake) or to perform cyclic sense on the wake inputs. Therefore, the timers can be mapped to the dedicated HS switches by SPI (via HS_CTRL1...2). Following periods and on-times can be selected via the register TIMER1_CTRL and TIMER2_CTRL respectively: • Period: 10ms / 20ms / 50ms / 100ms / 200ms / 1s / 2s • On time: 0.1ms / 0.3ms / 1.0ms / 10ms / 20ms / OFF at HIGH or LOW 5.3 Supervision Features The device offers various supervision features to support functional safety requirements. Please see Chapter 14 for more information. Data Sheet 37 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 1 6 Voltage Regulator 1 6.1 Block Description VS V CC1 Vref 1 Overtemperature Shutdown Bandgap Reference State Machine INH GND Figure 11 Module Block Diagram Functional Features • 5V low-drop voltage regulator • Under voltage monitoring with adjustable reset level, VCC1 prewarning and VCC1 short circuit detection (VRT1/2/3/4, VPW,f ). Please refer to Chapter 14.6 and Chapter 14.7 for more information. • Short circuit detection and switch off with under voltage fail threshold, device enters SBC Fail-Safe Mode • ≥470nF ceramic capacitor at voltage output for stability, with ESR < 1Ω @ f = 10 kHz, to achieve the voltage regulator control loop stability based on the safe phase margin (bode diagram). • Output current capability up to IVCC1,lim. Data Sheet 38 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 1 6.2 Functional Description The Voltage Regulator 1 (=VCC1) is “ON” in SBC Normal and SBC Stop Mode and is disabled in SBC Sleep and in SBC Fail-Safe Mode. The regulator can provide an output current up to IVCC1,lim. For low-quiescent current reasons, the output voltage tolerance is decreased in SBC Stop Mode because only a low-power mode regulator with a lower accuracy (VCC1,out41) will be active for small loads. If the load current on VCC1 exceeds the selected threshold (IVCC1,Ipeak1,r or IVCC1,Ipeak2,r) then the high-power mode regulator will be also activated to support an optimum dynamic load behavior. The current consumption will then increase by typ. 2.9mA. If the load current on VCC1 falls below the selected threshold (IVCC1,Ipeak1,f or IVCC1,Ipeak2,f), then the low-quiescent current mode is resumed again by disabling the high-power mode regulator. Both regulators (low-power mode and high-power mode) are active in SBC Normal Mode. Two different active peak thresholds can be selected via SPI: • I_PEAK_TH = ‘0’(default): the lower VCC1 active peak threshold 1 is selected with lowest quiescent current consumption in SBC Stop Mode (IStop_1,25, IStop_1,85); • I_PEAK_TH = ‘1’: the higher VCC1 active peak threshold 2 is selected with an increased quiescent current consumption in SBC Stop Mode (IStop_2,25, IStop_2,85); Data Sheet 39 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 1 6.3 Electrical Characteristics Table 9 Electrical Characteristics VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Output Voltage including line and Load regulation VCC1,out1 4.9 5.0 5.1 V 1) SBC Normal Mode; 10µA < IVCC1 < 250mA 6V < VS < 28V P_6.3.1 Output Voltage including line and Load regulation VCC1,out2 4.9 5.0 5.1 V 1) P_6.3.7 Output Voltage including line and Load regulation VCC1,out3 4.97 – 5.07 V 1)2) SBC Normal Mode; P_6.3.12 20mA < IVCC1 < 90mA 8V < VS < 18V 25°C < Tj < 125°C Output Voltage including line and Load regulation VCC1,out41 4.9 5.05 5.2 V SBC Stop Mode; P_6.3.2 1mA < IVCC1 < IVCC1,Ipeak Output Voltage including line and Load regulation VCC1,out42 4.9 5.05 5.25 V SBC Stop Mode; 10µA < IVCC1 < 1mA P_6.3.20 Output Drop VCC1,d1 – – 500 mV P_6.3.3 Output Drop VCC1,d2 – – 500 mV VCC1 Active Peak Threshold 1 IVCC1,Ipeak1,r – (Transition threshold between low-power and high-power mode regulator) 1.9 3.5 mA IVCC1 = 50mA VS=3V IVCC1 = 150mA VS=5V 2) ICC1 rising; VS = 13.5V -40°C < Tj < 150°C; VCC1 Active Peak Threshold 1 IVCC1,Ipeak1,f 0.5 (Transition threshold between high-power and low-power mode regulator) 1.3 VCC1 Active Peak Threshold 2 IVCC1,Ipeak2,r – (Transition threshold between low-power and high-power mode regulator) 4.3 VCC1 Active Peak Threshold 2 IVCC1,Ipeak2,f 1.7 (Transition threshold between high-power and low-power mode regulator) 3.4 Over Current Limitation IVCC1,lim 250 SBC Normal Mode; 10µA < IVCC1 < 150mA P_6.3.4 P_6.3.13 I_PEAK_TH = ‘0’ – mA 2) ICC1 falling; VS = 13.5V -40°C < Tj < 150°C; P_6.3.17 I_PEAK_TH = ‘0’ 7.0 mA 2) ICC1 rising; VS = 13.5V -40°C < Tj < 150°C; P_6.3.18 I_PEAK_TH = ‘1’ – mA 2) ICC1 falling; VS = 13.5V -40°C < Tj < 150°C; P_6.3.19 I_PEAK_TH = ‘1’ – 1200 2) mA current flowing out of pin, VCC1 = 0V P_6.3.6 1) In SBC Stop Mode, the specified output voltage tolerance applies when IVCC1 has exceeded the selected active peak threshold (IVCC1,Ipeak1,r or IVCC1,Ipeak2,r) but with increased current consumption. 2) Not subject to production test, specified by design. Data Sheet 40 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 1 Figure 12 Data Sheet Typical on-resistance of VCC1 pass device during low drop operation for ICC1 = 100mA 41 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 1 Figure 13 Data Sheet On-resistance range of VCC1 pass device during low drop operation for ICC1 = 150mA 42 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 2 7 Voltage Regulator 2 7.1 Block Description VS V CC2 Vref 1 Overtemperature Shutdown Bandgap Reference State Machine INH GND Figure 14 Module Block Diagram Functional Features • 5 V low-drop voltage regulator • Protected against short to battery voltage, e.g. for off-board sensor supply • Can also be used for CAN supply • VCC2 under voltage monitoring. Please refer to Chapter 14.8 for more information • Can be active in SBC Normal, SBC Stop, and SBC Sleep Mode (not SBC Fail-Safe Mode) • VCC2 switch off after entering SBC Restart Mode. Switch off is latched, LDO must be enabled via SPI after shutdown. • Over temperature protection • ≥ 470nF ceramic capacitor at output voltage for stability, with ESR < 1Ω @ f = 10 kHz, to achieve the voltage regulator control loop stability based on the safe phase margin (bode diagram). • Output current capability up to IVCC2,lim. Data Sheet 43 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 2 7.2 Functional Description In SBC Normal Mode VCC2 can be switched on or off via SPI. For SBC Stop- or Sleep Mode, the VCC2 has to be switched on or off before entering the respective SBC mode. The regulator can provide an output current up to IVCC2,lim. For low-quiescent current reasons, the output voltage tolerance is decreased in SBC Stop Mode because only a low-power mode regulator with a lower accuracy (VCC2,out5) will be active for small loads. If the load current on VCC2 exceeds IVCC2 > IVCC2,Ipeak,r then the high-power mode regulator will also be enabled to support an optimum dynamic load behavior. The current consumption will then increase by typ. 2.9mA. If the load current on VCC2 falls below the threshold (IVCC2 < IVCC2,Ipeak,f), then the low-quiescent current mode is resumed again by disabling the high-power mode regulator. Both regulators are active in SBC Normal Mode. Note: If the VCC2 output voltage is supplying external off-board loads, the application must consider the series resonance circuit built by cable inductance and decoupling capacitor at the load. Sufficient damping must be provided. 7.2.1 Short to Battery Protection The output stage is protected for short to VBAT. Data Sheet 44 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 2 7.3 Electrical Characteristics Table 10 Electrical Characteristics VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Output Voltage including line and Load regulation (SBC Normal Mode) VCC2,out1 4.9 5.0 5.1 V 1) SBC Normal Mode; 10µA < IVCC2 < 100mA 6.5V < VS < 28V P_7.3.1 Output Voltage including line and Load regulation (SBC Normal Mode) VCC2,out2 4.9 5.0 5.1 V 1) SBC Normal Mode; 10µA < IVCC2 < 80mA 6V < VS < 28V P_7.3.16 Output Voltage including line and Load regulation (SBC Normal Mode) VCC2,out3 4.9 5.0 5.1 V 1) SBC Normal Mode; 10µA < IVCC2 < 40mA P_7.3.2 Output Voltage including line and Load regulation (SBC Normal Mode) VCC2,out4 4.97 – 5.07 V 2) P_7.3.14 Output Voltage including line and Load regulation (SBC Stop/Sleep Mode) VCC2,out5 4.9 5.05 5.2 V Stop, Sleep Mode; P_7.3.3 1mA < IVCC2 < IVCC2,Ipeak Output Voltage including line and Load regulation (SBC Stop/Sleep Mode) VCC2,out6 4.9 5.05 5.25 V Stop, Sleep Mode; 10µA < IVCC2 < 1mA P_7.3.18 Output Drop VCC2,d1 – – 500 mV P_7.3.4 VCC2 Active Peak Threshold (Transition threshold between low-power and high-power mode regulator) IVCC2,Ipeak,r – 1.9 3.5 mA IVCC2 = 30mA VS = 5V 2) ICC2 rising; VS = 13.5V -40°C < Tj < 150°C P_7.3.15 VCC2 Active Peak Threshold (Transition threshold between high-power and low-power mode regulator) IVCC2,Ipeak,f 0.5 1.3 – mA 2) ICC2 falling; VS = 13.5V -40°C < Tj < 150°C P_7.3.17 Over Current limitation IVCC2,lim – 7502) mA current flowing out of pin, VCC2 = 0V P_7.3.5 100 SBC Normal Mode; 10µA < IVCC2 < 5mA 8V < VS < 18V 25°C < Tj < 125°C 1) In SBC Stop Mode, the specified output voltage tolerance applies when IVCC2 has exceeded the selected active peak threshold (IVCC2,Ipeak,r) but with increased current consumption. 2) Not subject to production test, specified by design. Data Sheet 45 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 2 Figure 15 Data Sheet Typical on-resistance of VCC2 pass device during low drop operation for ICC2 = 30mA 46 Rev. 1.1, 2014-09-26 TLE9261QX Voltage Regulator 2 Figure 16 Data Sheet On-resistance range of VCC2 pass device during low drop operation for ICC2 = 50mA 47 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 8 External Voltage Regulator 3 8.1 Block Description VS VCC3SH VCC3B VCC3REF R BE ICC3base VS - VCC3shunt > Vshunt_threshold + - VREF State Machine Figure 17 Functional Block Diagram Functional Features • 5V / 3.3V low-drop voltage regulator with external PNP transistor (up to 350mA with 470mΩ shunt resistor) • Four high-voltage pins are used: VS, VCC3B, VCC3SH, VCC3REF • Configurable as stand-alone regulator (5V or 3.3V output voltage selectable via SPI) or in load-sharing mode with VCC1 (5V output voltage) • ≥ 4.7µF ceramic capacitor at output voltage for stability, with ESR < 150mΩ @ f = 10 kHz to achieve the voltage regulator control loop stability based on the safe phase margin (bode diagram). • Overcurrent limitation with external shunt in stand-alone configuration • Adjustable load current sharing ratio between VCC1 and VCC3 for load-sharing configuration • Under voltage shutdown in stand-alone configuration only Table 11 1) External Voltage Regulator Configurations depending on VCC1 output voltage VCC1 configuration VCC3 voltage for VCC3_ V_CFG = 0 VCC3 voltage for VCC3_ V_CFG = 1 VCC1 = 5.0V VCC3 = 3.3V VCC3 = 5.0V 1) This settings are valid only for the VCC3 stand-alone configuration. The bit VCC3_ V_CFG is ignored for VCC3 load sharing configuration Data Sheet 48 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 8.2 Functional Description The external voltage regulator can be used as an independent voltage regulator or in load-sharing mode with VCC1. Setting VCC3_ON in the M_S_CTRL register in SBC Normal Mode sets the stand-alone configuration of VCC3 as an independent voltage regulator. The load sharing configuration is set via the SPI bit VCC3_LS in the HW_CTRL register. VCC3 load sharing? No Default value of VCC3_LS = ‘0' Yes 5.0V VCC3 output voltage in stand-alone configuration 3.3V Set bit VCC3_LS = 1 VCC3_V_CFG is automatically set to 0 VCC3_LS, VCC3_ON and VCC3_V_CFG cannot be changed anymore Set bit VCC3_V_CFG = 0 Set bit VCC3_V_CFG = 1 Set bit VCC3_ON = 0 or 1 Set bit VCC3_ON = 0 or 1 VCC3_LS and VCC3_V_CFG cannot be changed anymore (once VCC3_ON is set for the first time ) VCC3 load sharing VCC3 = VCC1 Figure 18 stand-alone configuration VCC3 = 5V stand-alone configuration VCC3 = 3.3V Selecting the Configuration of the VCC3 Regulator Depending on the configuration the regulator will act in the respective SBC Mode as described in Table 12. After the VCC3 configuration has been selected, it cannot be changed anymore. In stand-alone configuration the maximum current ICC3max is defined by the current limitation determined by the used shunt. In load sharing configuration, the shunt is used to determine the current ratio between VCC1 and VCC3. Since the junction temperature of the external PNP transistor cannot be sensed by the SBC, it cannot be protected against over temperature by the SBC. Therefore the thermal behavior has to be analyzed by the application. For low-quiescent current reasons, the output voltage tolerance is decreased in SBC Stop Mode because a lowpower mode regulator with a lower accuracy will be active for small loads. If the base current on VCC3 exceeds IVCC3base > IVCC3base,Ipeak,r then the high-power mode regulator is enabled additionally to support an optimum dynamic load behavior. If the base current on VCC3 falls below the threshold (IVCC3base < IVCC3base,Ipeak,f), then the low-quiescent current consumption is resumed again by disabling the high-power mode regulator. Only the high-power mode regulator is active in SBC Normal Mode. The status of VCC3 is reported in the SUP_STAT_2 SPI register. The regulator will switch OFF in case of VS dropping below VS_UV regardless of the VCC3 configuration and will be automatically enabled again when exceeding this threshold voltage unless the control bit VCC3_VS_ UV_OFF is set. VCC3 will also stay active in SBC Stop Mode when the bit VCC3_LS_ STP_ON is set and when load sharing is configured (for detailed protection features see Chapter 14.7 and Chapter 15.3). Data Sheet 49 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 Table 12 External Voltage Regulator State by SBC Mode SBC Mode Load Sharing Mode1) Independent Voltage Regulator INIT Mode OFF OFF Normal Mode Configurable Configurable 2) Stop Mode OFF/Fixed Sleep Mode OFF Fixed Restart Mode ON or ramping Fixed Fail-Safe Mode OFF OFF Fixed 1) Behaves as VCC1 and has to be configured in SBC Normal Mode 2) Load Sharing operation in SBC Stop Mode is by default disabled for power saving reasons but VCC3_LS bit will stay set. However, it can be also configured via the SPI bit VCC3_LS_ STP_ON to stay enabled in SBC Stop Mode. Note: The configuration of the VCC3 voltage regulator behavior must be done immediately after power-up of the device and cannot be changed afterwards as long as the device is supplied. Note: As soon as the bit VCC3_ON or VCC3_LS is set for the first time, the configuration for VCC3 cannot be changed anymore. This configuration is valid - also after a SBC Soft Reset - as long as the SBC is powered. Note: If the VCC3 output voltage is supplying external off-board loads, the application must consider the series resonance circuit built by cable inductance and decoupling capacitor at the load. Sufficient damping must be provided (e.g. a 100Ohm resistor between the PNP collector and VCC3REF with 10uF capacitor on collector - see also Figure 19). 8.2.1 External Voltage Regulator as Independent Voltage Regulator Configured as an independent voltage regulator the SBC offers with VCC3 a third supply which could be used as off-board supply e.g. for sensors due to the integrated HV pins VCC3B, VCC3SH, VCC3REF. This configuration is set and locked by enabling VCC3_ON while keeping VCC3_LS = 0. VCC3 can be switched ON or OFF but the configuration cannot be changed anymore. However, the SPI_FAIL is not set while trying to change the configuration. An over current limitation function is realized with the external shunt (see Chapter 8.4 for calculating the desired shunt value) and the output current shunt voltage threshold (Vshunt_threshold). If this threshold is reached, then ICC3 is limited and only the current limitation bit VCC3_OC is set (no other reaction) and can be cleared via SPI once the over current condition is not present anymore. If the over current limitation feature is not needed, then connect the pins VCC3SH and VS together. In this configuration VCC3 has the under voltage signalization enabled and an under voltage event is signaled with the bit VCC3_UV in the SUP_STAT_2 SPI register. Note: To avoid undesired current consumption increase of the device it must be ensured that VCC3 is not connected to VCC1 in this configuration. Data Sheet 50 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 VS RSHUNT VCC3 T1 ICC3 C1 RLim C2 100 Ω VS VCC3SH VCC3B VCC3REF R BE ICC3base VS - VCC3shunt > Vshunt_threshold + - VREF State Machine Figure 19 Protecting the VCC3 against inductive short circuits when configured as an independent voltage regulator for off-board supply 8.2.2 External Voltage Regulator in Load Sharing Mode The purpose of the load sharing mode is to increase the total current capability of VCC1 without increase of the power dissipation within the SBC. The load current is shared between the VCC1 internal regulator and the external PNP transistor of VCC3. Figure 20 shows the setup for Load Sharing. Load Sharing is active in SBC Normal Mode. It can also be configured via SPI to stay active in SBC Stop Mode. An input voltage up to VSx,MAX is regulated to VCC3,nom = 5.0 V with a precision of ±2% when used in the load sharing configuration in SBC Normal Mode. This configuration is set and locked by enabling VCC3_LS for the first time while VCC3_ON has no function, i.e. keep VCC3_ON = 0. Trying to change the VCC3 configuration after VCC3_LS has been set will result in the SPI_FAIL bit being set and keeping the VCC3 configurations unchanged. Load sharing will be automatically disabled (only if VCC3_LS_ STP_ON = 0) during SBC Stop Mode due to power saving reasons but the bit will remain set to automatically switch back on after returning to SBC Normal Mode. It must be ensured that the same VCC3 output voltage level is selected as for VCC1. In this configuration VCC3 has no undervoltage signalization. VCC3 shuts down if Fail-Safe Mode is reached, e.g. due to undervoltage shutdown (VS,UV monitoring). VCC3 has no over current limitation in this configuration and the shunt resistor is defining the load sharing ratio between the VCC1 and VCC3 load currents (see Equation (2) in Chapter 8.4). Thus, no over current condition VCC3_OC will be signaled in this configuration. Data Sheet 51 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 VS RSHUNT V CC13 T1 I CC3 C1 C2 VS VCC3SH VCC3B VCC3REF Vcc3 Vcc1 I CC1 Figure 20 VCC3 in Load Sharing Configuration 8.3 External Components Characterization is performed with the BCP52-16 from Infineon (ICC3 < 200 mA) and with MJD253. Other PNP transistors can be used. However, the functionality must be checked in the application. Figure 20 shows one hardware set up used. Table 13 Bill of Materials for the VCC3 Function with and without load sharing configuration Device Vendor Reference / Value C2 Murata 10 µF/10 V GCM31CR71A106K64L RSHUNT - 1 Ω (with / without LS) T1 Infineon BCP52-16 Note: The SBC is not able to ensure a thermal protection of the external PNP transistor. The power handling capabilities for the application must therefore be chosen according to the selected PNP device, the PCB layout and properties of the application to prevent thermal damage, e.g. via the shunt current limitation in stand alone configuration or by selecting the proper ICC1/ICC3 ratio in load-sharing configuration. Note: To ensure an optimum EMC behavior of the VCC3 regulator when the VCC3 output is leaving the PCB, it is necessary to optimize the PCB layout to have the PNP very close to the SBC. If this is not sufficient or possible, an external capacitance should be placed to the off-board connector (see also Chapter 16.1). Data Sheet 52 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 8.4 Calculation of RSHUNT As a independent regulator, the maximum current ICC3max where the limit starts and the bit ICC3 > ICC3max is set is determined by the shunt resistor RSHUNT and the Output Current Shunt Voltage Threshold Vshunt_threshold. The resistor can be calculated as following: RSHUNT = U shunt _ threshold (1) I CC 3 max If VCC3 is configured for load sharing, then the shunt resistor determines the load sharing ratio between VCC1 and VCC3. The ratio can be calculated as following: I CC I CC 1 I CC 3 3 = 110 Ω 105 − 15 mV R SHUNT = I CC 1 ⋅ 110 Ω 105 R SHUNT I CC 1 (a ) − 15 mV (2) (b ) Example: A shunt resistor with 470mΩ and a load current of 100mA out of VCC1 would result in ICC3 = 191mA. 8.5 Unused Pins In case the VCC3 is not used in the application, it is recommended to connect the unused pins of VCC3 as followed: • Connect VCC3SH to VS or leave open; • Leave VCC3B open; • Leave VCC3REF open • Do not enable the VCC3 via SPI as this leads to increased current consumption Data Sheet 53 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 8.6 Electrical Characteristics VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all outputs open; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified. Table 14 Electrical Characteristics Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Parameters independent from Test Set-up External Regulator Control Drive Current Capability IVCC3base 40 60 80 mA VVCC3base = 13.5 V P_8.6.1 Input Current VCC3ref IVCC3ref 0 3 10 µA VVCC3ref = 5 V P_8.6.2 Input Current VCC3 Shunt Pin IVCC3shunt 0 3 10 µA VVCC3shunt = VS P_8.6.3 Output Current Shunt Voltage Threshold Vshunt_threshold 180 245 310 mV 1) P_8.6.6 Current increase regulation reaction time trIinc – – 5 µs 4) Current decrease regulation reaction time trIdec – – 5 µs 4) Leakage current of VCC3base when VCC3 disabled IVCC3base_lk – – 5 µA VCC3base = VS; Tj = 25°C P_8.6.9 Leakage current of VCC3shunt when VCC3 disabled IVCC3shunt_lk – – 5 µA VCC3shunt = VS; Tj = 25°C P_8.6.11 Base to emitter resistor RBE 120 150 185 kΩ VCC3 = OFF; P_8.6.12 Active Peak Threshold VCC3 IVCC3base,Ipeak,r – (Transition threshold between low-power and highpower mode regulator) 50 65 µA 4) Drive current IVCC3base; IVCC3base rising VS =13.5V; -40°C < Tj < 150°C P_8.6.33 Active Peak Threshold VCC3 IVCC3base,Ipeak,f 15 (Transition threshold between high-power and lowpower mode regulator) 30 – µA 4) P_8.6.34 VCC3 = 6 V to 0 V; P_8.6.7 ICC3base = 20 mA Figure 21 VCC3 = 0 V to 6 V; P_8.6.8 ICC3base = 20 mA Figure 21 Drive current IVCC3base; IVCC3base falling VS =13.5V; -40°C < Tj < 150°C Parameters dependent on the Test Set-up (with external PNP device MJD-253) 2) External Regulator Output Voltage (VCC3 = 5.0V) VCC3.out1 4.9 5 5.1 V P_8.6.13 SBC Normal Mode; load sharing configuration with 470 mΩ shunt resistor; 10 µA < IVCC1 + IVCC3 < 300 mA; External Regulator Output Voltage (VCC3 = 5.0V) VCC3,out2 4.9 5 5.1 V 2) Data Sheet 54 SBC Normal Mode; stand-alone configuration 10 mA < IVCC3 < 300 mA; P_8.6.14 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 Table 14 Electrical Characteristics (cont’d) Parameter Symbol Values Unit Note / Test Condition Min. Typ. Max. Number External Regulator Output Voltage (VCC3 = 5.0V) VCC3,out3 4.8 5 5.2 V 2) External Regulator Output Voltage (VCC3 = 3.3V) VCC3,out4 3.23 3.3V 3.37 V 2) External Regulator Output Voltage (VCC3 = 3.3V) VCC3,out5 3.15 3.3V 3.45 V 2) Load Sharing Ratio ICC1 : ICC3 RatioLS_1,VCC3 1 : 1: 1.9 1: 2.45 – 4)5) 6.0V < VS < 28V; SBC Normal Mode; LS ratio for a 470 mΩ shunt resistor and total load current of 300mA P_8.6.16 Load Sharing Ratio ICC1 : ICC3 RatioLS_2,VCC3 1 : 1: 0.95 1: 1.23 – 4)5) 6.0V < VS < 28V; SBC Normal Mode; LS ratio for a 1 Ω shunt resistor and total load current of 300mA P_8.6.20 Load Sharing Ratio ICC1 : ICC3 RatioLS_3,VCC3 1 : 1: 1.95 1: 2.40 – 4)5) Tj = 150°C; 8.0V < VS < 18V; SBC Normal Mode; LS ratio for a 470 mΩ shunt resistor and total load current of 300mA P_8.6.27 Load Sharing Ratio ICC1 : ICC3 RatioLS_4,VCC3 1 : 1: 0.98 1: 1.21 – 4)5) P_8.6.28 1.35 0.67 1.50 0.75 SBC Stop-, Sleep Mode; P_8.6.15 Stand-alone configuration 10µA < IVCC3 < IVCC3_peak,r3) SBC Normal Mode; stand-alone configuration 10 mA < IVCC3 < 300 mA; P_8.6.22 SBC Stop-, Sleep Mode; P_8.6.23 Stand-alone configuration 10µA < IVCC3 < IVCC3_peak,r3) Tj = 150°C; 8.0V < VS < 18V; SBC Normal Mode; LS ratio for a 1 Ω shunt resistor and total load current of 300mA 1) Threshold at which the current limitation starts to operate. This threshold is only active when VCC3 is configured for standalone configuration. 2) Tolerance includes load regulation and line regulation. 3) IVCC3_peak refers to the load current out of the collector of the external PNP device. This value can be calculated by multiplying the VCC3base active peak threshold (IVCC3base,Ipeak) with the current gain of the PNP 4) Not subject to production test, specified by design. 5) a) Ratio will change depending on the chosen shunt resistor which value is correlating to the maximum power dissipation of the PNP pass device. See Chapter 8.4 for the ratio calculation. The ratio will also change at low-drop operation. For supply voltages of 5.5V < VS < 6V the accuracy applies only for a total load current of 250mA. The load sharing ratio in SBC Stop Mode has +/-10% wider limits than specified. b) The output voltage precision in load sharing in SBC Stop Mode is according to VCC1 +/-4% or better for loads up to 20mA and +/-2% with loads greater than 20mA. In SBC Normal the +/-2% precision for 5V/3.3V tolerance is valid regardless of the applied load. Data Sheet 55 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 Note: At Tj > 125°C, the power transistor leakage could be increased, which has to be added to the quiescent current of the application independently if the regulator is turned on/off. To prevent an over-voltage condition at no load due to this increased leakage, an internal clamping structure will automatically turn on at typ. 200mV above the upper limit of the programmed output voltage. Note: There is no thermal protection available for the external PNP transistor. Therefore, the application must be designed to avoid overheating of the PNP via the shunt current limitation in stand alone configuration and by selecting the proper ICC1/ICC3 ratio in load-sharing configuration. Note: In SBC Stop Mode, the same output voltage tolerance applies as in SBC Normal Mode when IVCC3 has exceeded the selected active peak threshold (IVCC3base,Ipeak) but with increased current consumption. Data Sheet 56 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 Timing diagram for regulator reaction time “current increase regulation reaction time” and “current decrease regulation reaction time” VCC3 t ICCbase ICC3base, 50% trlinc Figure 21 Data Sheet trldec t Regulator Reaction Time 57 Rev. 1.1, 2014-09-26 TLE9261QX External Voltage Regulator 3 Typical Load Sharing Characteristics using the BCP52-16 PNP transistor and a 1 Ω shunt resistor 0,35 Tj = 27°C Total Current - Icc1 + Icc3 (mA) (A) 0,30 Tj = 150°C 0,25 Tj = -40°C 0,20 0,15 0,10 0,05 0 Figure 22 0 0,2 0,4 0,6 0,8 Load Sharing Ratio - Icc3 Icc1vs. vs.Icc1 Icc3 1,0 1,2 1,4 Load Sharing Ratio ICC1 : ICC3 vs. the total load current 0,35 Tj = 27°C Total Current - Icc1 + Icc3 (mA) (A) 0,30 Tj = 150°C 0,25 Tj = -40°C 0,20 0,15 0,10 0,05 0 Figure 23 Data Sheet 0 0,02 0,04 0,06 0,08 Load Current - Icc1 0,10 0,12 0,14 0,16 Load Sharing Behavior of ICC1 vs. the total load current 58 Rev. 1.1, 2014-09-26 TLE9261QX High-Side Switch 9 High-Side Switch 9.1 Block Description HSx VSHS HS Gate Control Overcurrent Detection Open Load (On) Figure 24 High-Side Module Block Diagram Features • Dedicated supply pin VSHS for high-side outputs • Over voltage and under voltage switch off - configurable via SPI • Overcurrent detection and switch off • Open load detection in ON-state • PWM capability with internal timer configurable via SPI • Switch recovery after removal of OV or UV condition configurable via SPI 9.2 Functional Description The High-Side switches can be used for control of LEDs, as supply for the wake inputs and for other loads. The High-Side outputs can be controlled either directly via SPI by (HS_CTRL1, HS_CTRL2), by the integrated timers or by the integrated PWM generators. The high-side outputs are supplied by a dedicated supply pin VSHS (different to VS). The topology supports improved cranking condition behavior. The configuration of the High-Side (Permanent On, PWM, cyclic sense, etc.) drivers must be done in SBC Normal Mode. The configuration is taken over in SBC Stop- or SBC Sleep Mode and cannot be modified. When entering SBC Restart Mode or SBC Fail-Safe Mode the HSx outputs are disabled. Data Sheet 59 Rev. 1.1, 2014-09-26 TLE9261QX High-Side Switch 9.2.1 Over and Under Voltage Switch Off All HS drivers in on-state are switched off in case of over voltage on VSHS (VSHS,OVD). If the voltage drops below the over voltage threshold the HS drivers are activated again. The feature can be disabled by setting the SPI bit HS_OV_SD_EN. The HS drivers are switched off in case of under voltage on VSHS (VSHS,UVD). If the voltage rises above the under voltage threshold the HS drivers are activated again. The feature can be disabled by setting the SPI bit HS_UV_SD_EN. So after release of under voltage or over voltage condition the HS switch goes back to programmed state in which it was configured via SPI. This behavior is only valid if the bit HS_OV_UV_REC is set to ‘1’. Otherwise the switches will stay off and the respective SPI control bits are cleared are cleared. The over voltage and under voltage is signaled in the bits VSHS_OV and VSHS_UV, no other error bits are set. 9.2.2 Over Current Detection and Switch Off If the load current exceeds the over current shutdown threshold for a time longer then the over current shutdown filter time the output is switched off. The over current condition and the switch off is signaled with the respective HSx_OC_OT bit in the register HS_OC_OT_STAT. The HSx configuration is then reset to 000 by the SBC. To activate the High-Side again the HSx configuration has to be set to ON (001) or be programmed to a timer function. It is recommended to clear the over current bit before activation the High-Side switch, as the bits are not cleared automatically by the SBC. 9.2.3 Open Load Detection Open load detection on the High-Side outputs is done during on state of the output. If the current in the activated output falls below then Open Load Detection current, the open load is detected and signaled via the respective bit HS1_OL, HS2_OL, HS3_OL, or HS4_OL in the register HS_OL_STAT. The High-Side output stays activated. If the open load condition disappears the Open Load bit in the SPI can be cleared. The bits are not cleared automatically by the SBC. 9.2.4 HSx Operation in Different SBC Modes • During SBC Stop and SBC Sleep Mode the HSx outputs can be used for the cyclic sense feature. The openload detection, over current shut down as well as over voltage and under voltage shutdown are available. The over current shutdown protection feature may influence the wake-up behavior1). • the HSx output can also be enabled for SBC Stop and SBC Sleep Mode as well as controlled by the PWMx generator. The HSx outputs must be configured in SBC Normal Mode before entering a low-power mode. • The HSx outputs are switched off during SBC Restart or SBC Fail-Safe Mode. They can be enabled via SPI if the failure condition is removed. 1) For the wake feature, the forced over current shut down case must be considered in the user software for all SBC Modes, i.e. due to disabled HSx switches a level change might not be detected anymore at WKx pins. Data Sheet 60 Rev. 1.1, 2014-09-26 TLE9261QX High-Side Switch 9.2.5 PWM and Timer Function Two 8-bit PWM generators are dedicated to generate a PWM signal on the HS outputs, e.g. for brightness adjustment or compensation of supply voltage fluctuation. The PWM generators are mapped to the dedicated HS outputs, and the duty cycle can be independently configured with a 8bit resolution via SPI (PWM1_CTRL, PWM2_CTRL). Two different frequencies (200Hz, 400Hz) can be selected independently for every PWM generator in the register PWM_FREQ_CTRL. PWM Assignment and Configuration: • Configure duty cycle and frequency for respective PWM generator in PWM1_CTRL/PWM2_CTRL and PWM_FREQ_CTRL • Assign PWM generator to respective HS switch(es) in HSx_CTRL • The PWM generation will start right after the HSx is assigned to the PWM generator (HS_CTRL1, HS_CTRL2) Assignment options of HS1... HS4 • Timer 1 • Timer 2 • PWM 1 • PWM 2 Note: The min. On-time during PWM is limited by the actual Ton and Toff time of the respective HS switch, e.g. the PWM setting ‘0000 0001’ could not be realized. In addition, the minimum PWM setting for reliable detection of over-current and open-load measurement is 4 digits for a period of 400Hz and 2 digits for a period of 200Hz Data Sheet 61 Rev. 1.1, 2014-09-26 TLE9261QX High-Side Switch 9.3 Electrical Characteristics Table 15 Target Specifications VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Ids = 60mA, Tj < 25°C Ids = 60mA, Tj < 150°C P_9.3.1 Output HS1, HS2, HS3, HS4 Static Drain-Source ON Resistance HS1...HS4 RON,HS25 – 7 – Ω Static Drain-Source ON Resistance HS1...HS4 RON,HS150 – 11.5 16 Ω Leakage Current HSx / per channel Ileak,HS – – 2 µA 1) 0 V < VHSx < VSHS; Tj < 85°C P_9.3.11 Output Slew Rate (rising) SRraise,HS 0.8 – 2.5 V/µs 1) P_9.3.3 SRfall,HS -2.5 Switch-on time HSx tON,HS 3 – 30 µs CSN = HIGH to 0.8*VSHS; RL = 220Ω; VSHS = 6 to 18V P_9.3.5 Switch-off time HSx tOFF,HS 3 – 30 µs CSN = HIGH to 0.2*VSHS; RL = 220Ω; VSHS = 6 to 18V P_9.3.6 Short Circuit Shutdown Current ISD,HS 150 245 300 mA VSHS = 6 to 20V, hysteresis included P_9.3.7 µs 2) 3) P_9.3.8 Output Slew Rate (falling) 20 to 80% VSHS = 6 to 18V RL = 220Ω – -0.8 V/µs 1) 80 to 20% P_9.3.4 VSHS = 6 to 18V RL = 220Ω Short Circuit Shutdown Filter tSD,HS Time Open Load Detection Current IOL,HS P_9.3.2 16 , 0.4 – 3 mA hysteresis included P_9.3.9 Open Load Detection hysteresis IOL,HS,hys – 0.45 – mA 1) P_9.3.14 Open Load Detection Filter Time tOL,HS – 64 – µs 2) 3) P_9.3.10 , 1) Not subject to production test, specified by design. 2) Not subject to production test, tolerance defined by internal oscillator tolerance. 3) The minimum PWM setting for reliable detection of over current and open load measurement is 5 digits for a period of 200Hz and 3 digits for a period of 150Hz. Data Sheet 62 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver 10 High Speed CAN Transceiver 10.1 Block Description VCAN SPI Mode Control CANH CANL VCC1 RTXD Driver Output Stage Temp.Protection TXDCAN + timeout To SPI diagnostic VCAN VBIAS = 2.5V VCC 1 MUX RXDCAN Receiver Vs Wake Receiver Figure 25 Functional Block Diagram 10.2 Functional Description The Controller Area Network (CAN) transceiver part of the SBC provides high-speed (HS) differential mode data transmission (up to 2 Mbaud) and reception in automotive and industrial applications. It works as an interface between the CAN protocol controller and the physical bus lines compatible to ISO/DIS 11898-2, 11898-5 and SAE J2284. The CAN transceiver offers low power modes to reduce current consumption. This supports networks with partially powered down nodes. To support software diagnostic functions, a CAN Receive-only Mode is implemented. It is designed to provide excellent passive behavior when the transceiver is switched off (mixed networks, clamp15/30 applications). A wake-up from the CAN wake capable mode is possible via a message on the bus. Thus, the microcontroller can be powered down or idled and will be woken up by the CAN bus activities. The CAN transceiver is designed to withstand the severe conditions of automotive applications and to support 12 V applications. The different transceiver modes can be controlled via the SPI CAN bits. Data Sheet 63 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Figure 26 shows the possible transceiver mode transitions when changing the SBC mode. SBC Mode CAN Transceiver Mode SBC Stop Mode Receive Only Wake Capable Normal Mode OFF SBC Normal Mode Receive Only Wake Capable Normal Mode OFF SBC Sleep Mode Wake Capable OFF SBC Restart Mode Woken1 OFF SBC Fail-Safe Mode Wake Capable 1 after a wake event on CAN Bus Behavior after SBC Restart Mode - not coming from SBC Sleep Mode due to a wake up of the respective transceiver: If the transceivers had been configured to Normal Mode, or Receive Only Mode, then the mode will be changed to Wake Capable. If it was Wake Capable, then it will remain Wake Capable. If it had been OFF before SBC Restart Mode, then it will remain OFF. Behavior in SBC Development Mode: CAN default value in SBC INIT MODE and entering SBC Normal Mode from SBC Init Mode is ON instead of OFF. Figure 26 CAN Mode Control Diagram CAN FD Support CAN FD stands for ‘CAN with Flexible Data Rate’. It is based on the well established CAN protocol as specified in ISO 11898-1. CAN FD still uses the CAN bus arbitration method. The benefit is that the bit rate can be increased by switching to a shorter bit time at the end of the arbitration process and then to return to the longer bit time at the CRC delimiter, before the receivers transmit their acknowledge bits. See also Figure 27. In addition, the effective data rate is increased by allowing longer data fields. CAN FD allows the transmission of up to 64 data bytes compared to the 8 data bytes from the standard CAN. Figure 27 Standard CAN message CAN Header CAN FD with reduced bit time CAN Header Data phase (Byte 0 – Byte 7) Data phase (Byte 0 – Byte 7) CAN Footer CAN Footer Example: - 11bit identifier + 8Byte data - Arbitration Phase 500kbps - Data Phase 2Mbps average bit rate 1.14Mbps Bite Rate Increase with CAN FD vs. Standard CAN Not only the physical layer must support CAN FD but also the CAN controller. In case the CAN controller is not able to support CAN FD then the respective CAN node must at least tolerate CAN FD communication. This CAN FD tolerant mode is realized in the physical layer in combination with CAN Partial Networking. The TLE926x-3QX variants of this family also support the CAN FD tolerant mode. Data Sheet 64 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver 10.2.1 CAN OFF Mode The CAN OFF Mode is the default mode after power-up of the SBC. It is available in all SBC Modes and is intended to completely stop CAN activities or when CAN communication is not needed. The CANH/L bus interface acts as a high impedance input with a very small leakage current. In CAN OFF Mode, a wake-up event on the bus will be ignored. 10.2.2 CAN Normal Mode The CAN Transceiver is enabled via SPI in SBC Normal Mode. CAN Normal Mode is designed for normal data transmission/reception within the HS-CAN network. The Mode is available in SBC Normal Mode and in SBC Stop Mode. The bus biasing is set to VCAN/2. Transmission The signal from the microcontroller is applied to the TXDCAN input of the SBC. The bus driver switches the CANH/L output stages to transfer this input signal to the CAN bus lines. Enabling sequence The CAN transceiver requires an enabling time tCAN,EN before a message can be sent on the bus. This means that the TXDCAN signal can only be pulled LOW after the enabling time. If this is not ensured, then the TXDCAN needs to be set back to HIGH (=recessive) until the enabling time is completed. Only the next dominant bit will be transmitted on the bus. Figure 28 shows different scenarios and explanations for CAN enabling. VTXDCAN CAN Mode t CAN,EN t CAN ,EN t t CAN,EN CAN NORMAL CAN OFF t VCANDIFF Dominant Recessive Correct sequence , Bus is enabled after tCAN, EN Figure 28 tCAN, EN not ensured , no transmission on bus recessive TXD level required bevor start of transmission t tCAN, EN not ensured , no transmission on bus recessive TXD level required CAN Transceiver Enabling Sequence Reduced Electromagnetic Emission To reduce electromagnetic emissions (EME), the bus driver controls CANH/L slopes symmetrically. Reception Analog CAN bus signals are converted into digital signals at RXD via the differential input receiver. Data Sheet 65 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver 10.2.3 CAN Receive Only Mode In CAN Receive Only Mode (RXD only), the driver stage is de-activated but reception is still operational. This mode is accessible by an SPI command in Normal Mode and in Stop Mode. The bus biasing is set to VCAN/2. 10.2.4 CAN Wake Capable Mode This mode can be used in SBC Stop, Sleep, Restart and Normal Mode and it is used to monitor bus activities. It is automatically accessed in SBC Fail-Safe Mode. Both bus pins CANH/L are connected to GND via the input resistors. A wake-up signal on the bus results in a change of behavior of the SBC, as described in Table 16. The pins CANH/L are terminated to typ. 2.5V through the input resistors. As a wake-up signalization to the microcontroller, the RXD_CAN pin is set LOW and will stay LOW until the CAN transceiver is changed to any other mode. After a wake-up event, the transceiver can be switched to CAN Normal Mode for communication via SPI. As shown in Figure 29, a wake-up pattern is signaled on the bus by two consecutive dominant bus levels for at least tWake1 (filter time t > tWake1), each separated by a recessive bus level of less than tWake2. Entering low -power mode , when selective wake-up function is disabled or not supported Ini Bus recessive > t WAKE1 Bias off Wait Bias off Bus dominant > tWAKE1 optional: tWAKE2 expired 1 Bias off Bus recessive > tWAKE1 optional: tWAKE2 expired 2 Bias off Bus dominant > tWAKE1 Entering CAN Normal or CAN Recive Only 3 tSilence expired AND Device in low-power mode Bias on Bus dominant > t WAKE1 Bus recessive > t WAKE1 4 tSilence expired AND device in low-power mode Bias on Figure 29 Data Sheet WUP detection following the definition in ISO 11898-5 66 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Rearming the Transceiver for Wake Capability After a BUS wake-up event, the transceiver is woken. However, the CAN transceiver mode bits will still show wake capable (=‘01’) so that the RXD signal will be pulled low. There are two possibilities how the CAN transceiver’s wake capable mode is enabled again after a wake event: • The CAN transceiver mode must be toggled, i.e. switched from Wake Capable Mode to CAN Normal Mode, CAN Receive Only Mode or CAN Off, before switching to CAN Wake Capable Mode again. • Rearming is done automatically when the SBC is changed to SBC Stop, SBC Sleep, or SBC Fail-Safe Mode to ensure wake-up capability. Note: It is not necessary to clear the CAN wake-up bit CAN_WU to become wake capable again. It is sufficient to toggle the CAN mode. Note: The CAN module is supplied by an internal voltage when in CAN Wake Capable Mode, i.e. the module must not be supplied through the VCAN pin during this time. Before changing the CAN Mode to Normal Mode, the supply of VCAN has to be activated first. Wake-Up in SBC Stop and Normal Mode In SBC Stop Mode, if a wake-up is detected, it is always signaled by the INT output and in the WK_STAT_1 SPI register. It is also signaled by RXDCAN pulled to low. The same applies for the SBC Normal Mode. The microcontroller should set the device from SBC Stop Mode to SBC Normal Mode, there is no automatic transition to Normal Mode. For functional safety reasons, the watchdog will be automatically enabled in SBC Stop Mode after a Bus wake event in case it was disabled before (if bit WD_EN_ WK_BUS was configured to HIGH before). Wake-Up in SBC Sleep Mode Wake-up is possible via a CAN message (filter time t > tWake1). The wake-up automatically transfers the SBC into the SBC Restart Mode and from there to Normal Mode the corresponding RXD pin in set to LOW. The microcontroller is able to detect the low signal on RXD and to read the wake source out of the WK_STAT_1 register via SPI. No interrupt is generated when coming out of Sleep Mode. The microcontroller can now for example switch the CAN transceiver into CAN Normal Mode via SPI to start communication. Table 16 Action due to CAN Bus Wake-Up SBC Mode SBC Mode after Wake VCC1 INT RXD Normal Mode Normal Mode ON LOW LOW Stop Mode Stop Mode ON LOW LOW Sleep Mode Restart Mode Ramping Up HIGH LOW Restart Mode Restart Mode ON HIGH LOW Fail-Safe Mode Restart Mode Ramping up HIGH LOW Data Sheet 67 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver 10.2.5 TXD Time-out Feature If the TXD signal is dominant for a time t > tTXD_CAN_TO, in CAN Normal Mode, the TXD time-out function deactivates the transmission of the signal at the bus. This is implemented to prevent the bus from being blocked permanently due to an error. The transmitter is disabled and the transceiver is switched to Receive Only Mode. The failure is stored in the SPI flag CAN_FAIL. The CAN transmitter stage is activated again after the dominant time-out condition is removed and the transceiver is automatically switched back to CAN Normal Mode.The transceiver configuration stays unchanged. 10.2.6 Bus Dominant Clamping If the HS CAN bus signal is dominant for a time t > tBUS_CAN_TO, regardless of the CAN transceiver mode a bus dominant clamping is detected and the SPI bit CAN_FAIL is set. The transceiver configuration stays unchanged. 10.2.7 Under Voltage Detection The voltage at the CAN supply pin is monitored in CAN Normal Mode only. In case of VCAN under voltage a signalization via SPI bit VCAN_UV is triggered and the SBC disables the transmitter stage. If the CAN supply reaches a higher level than the under voltage detection threshold (VCAN > VCAN_UV), the transceiver is automatically switched back to CAN Normal Mode. The transceiver configuration stays unchanged. Data Sheet 68 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver 10.3 Electrical Characteristics Table 17 Electrical Characteristics VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; 4.75 V < VCAN < 5.25 V; RL = 60Ω; CAN Normal Mode; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. – 0.80 0.90 Unit Note / Test Condition Number V P_10.3.2 Vdiff = VCANH VCANL ; -12V ≤ VCM(CAN) CAN Bus Receiver Differential Receiver Threshold Voltage, recessive to dominant edge Vdiff,rd_N ≤ +12 V; CAN Normal Mode Differential Receiver Threshold Voltage, dominant to recessive edge Vdiff,dr_N 0.50 0.60 – V P_10.3.3 Vdiff = VCANH VCANL; -12V ≤ VCM(CAN) ≤ +12 V; CAN Normal Mode Common Mode Range CMR -12 – 12 V 1) P_10.3.4 CANH, CANL Input Resistance Rin 20 40 50 kΩ CAN Normal / Wake capable Mode; Recessive state P_10.3.6 Differential Input Resistance Rdiff 40 80 100 kΩ CAN Normal / Wake capable Mode; Recessive state P_10.3.7 Input Resistance Deviation between CANH and CANL ∆R i -3 – 3 % 1) Input Capacitance CANH, CANL versus GND Cin – 20 40 pF 1) P_10.3.39 – 10 20 pF 1) P_10.3.40 Differential Input Capacitance Cdiff Recessive state P_10.3.38 VTXD = 5V VTXD = 5V Wake-up Receiver Threshold Voltage, recessive to dominant edge Vdiff, rd_W – 0.8 1.15 V -12V ≤ VCM(CAN) P_10.3.8 ≤ +12 V; CAN Wake Capable Mode Wake-up Receiver Threshold Voltage, dominant to recessive edge Vdiff, dr_W 0.4 0.7 – V -12V ≤ VCM(CAN) P_10.3.9 ≤ +12 V; CAN Wake Capable Mode Data Sheet 69 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Table 17 Electrical Characteristics (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; 4.75 V < VCAN < 5.25 V; RL = 60Ω; CAN Normal Mode; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number CAN Bus Transmitter CANH/CANL Recessive Output Voltage (CAN Normal Mode) VCANL/H_NM 2.0 – 3.0 V CAN Normal Mode; VTXD = VCC1; no load P_10.3.11 CANH/CANL Recessive Output Voltage (CAN Wake Capable Mode) VCANL/H_LP -0.1 – 0.1 V CAN Wake Capable Mode; VTXD = VCC1; no load P_10.3.43 CANH, CANL Recessive Output Voltage Difference Vdiff_r_N -500 – 50 mV CAN Normal Mode VTXD = VCC1; no load P_10.3.12 Vdiff_r_W -500 – 50 mV CAN Wake Capable Mode; VTXD = VCC1; no load P_10.3.41 CANL Dominant Output Voltage VCANL 0.5 – 2.25 V CAN Normal Mode; VTXD = 0 V; VCAN = 5 V; 50Ω ≤ RL ≤ 65Ω P_10.3.13 CANH Dominant Output Voltage VCANH 2.75 – 4.5 V CAN Normal Mode; VTXD = 0 V; VCAN = 5 V; 50Ω ≤ RL ≤ 65Ω P_10.3.14 CANH, CANL Dominant Output Voltage Difference Vdiff = VCANH - VCANL Vdiff_d_N 1.5 – 3.0 V CAN Normal Mode; VTXD = 0 V; VCAN = 5 V; 50Ω ≤ RL ≤ 65Ω P_10.3.16 Driver Symmetry VSYM = VCANH + VCANL VSYM 4.5 – 5.5 V 2) CAN Normal Mode; VTXD = 0 V / 5 V; VCAN = 5 V; CSPLIT = 4.7nF; 50Ω ≤ RL ≤ 60Ω P_10.3.42 CANH Short Circuit Current ICANHsc -100 -80 -50 mA CAN Normal Mode; VCANHshort = 0 V P_10.3.17 Vdiff = VCANH - VCANL (CAN Normal Mode) CANH, CANL Recessive Output Voltage Difference Vdiff = VCANH - VCANL (CAN Wake Capable Mode) Data Sheet 70 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Table 17 Electrical Characteristics (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; 4.75 V < VCAN < 5.25 V; RL = 60Ω; CAN Normal Mode; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. CANL Short Circuit Current ICANLsc 50 80 100 mA CAN Normal Mode VCANLshort = 18 V P_10.3.18 Leakage Current (unpowered device) ICANH,lk ICANL,lk – 5 7.5 µA VS = VCAN = 0V; P_10.3.19 0V < VCANH,L ≤ 5V; 3) Rtest = 0 / 47 kΩ VRXD,H 0.8 × – – V CAN Normal P_10.3.21 Mode IRXD(CAN) = -2 mA; VRXD,L – – 0.2 × V CAN Normal Mode IRXD(CAN) = 2 mA; P_10.3.22 HIGH Level Input Voltage Threshold VTXD,H – V CAN Normal Mode recessive state P_10.3.23 LOW Level Input Voltage Threshold VTXD,L 0.3 × TXD Input Hysteresis VTXD,hys – RTXD tCAN,EN 20 – Receiver Output RXD HIGH level Output Voltage LOW Level Output Voltage VCC1 VCC1 Transmission Input TXD TXD Pull-up Resistance CAN Transceiver Enabling Time – 0.7 × VCC1 – – V CAN Normal Mode dominant state P_10.3.24 0.12 × – mV 1) P_10.3.25 40 80 kΩ – P_10.3.26 10 – µs 4) VCC1 VCC1 CSN = HIGH to P_10.3.27 first valid transmitted TXD dominant Dynamic CAN-Transceiver Characteristics Min. Dominant Time for Bus Wake-up tWake1 0.50 – 3 µs -12V ≤ VCM(CAN) P_10.3.28 ≤ +12 V; CAN Wake capable Mode Wake-up Time-out, Recessive Bus tWake2 0.5 – 10 ms 4) WUP Wake-up Reaction Time tWU_WUP – – 100 µs 4)5)6) Data Sheet 71 CAN Wake capable Mode P_10.3.29 P_10.3.44 Wake-up reaction time after a valid WUP on CAN bus; Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Table 17 Electrical Characteristics (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; 4.75 V < VCAN < 5.25 V; RL = 60Ω; CAN Normal Mode; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Unit Note / Test Condition Number Min. Typ. Max. Propagation Delay TXD-to-RXD LOW (recessive to dominant) td(L),TR – 150 255 ns 2) CAN Normal Mode CL = 100 pF; RL = 60 Ω; VCAN = 5 V; CRXD = 15 pF P_10.3.30 Propagation Delay TXD-to-RXD HIGH (dominant to recessive) td(H),TR – 150 255 ns 2) CAN Normal Mode CL = 100 pF; RL = 60 Ω; VCAN = 5 V; CRXD = 15 pF P_10.3.31 Propagation Delay TXD LOW to bus dominant td(L),T – 50 – ns CAN Normal Mode CL = 100pF; RL = 60 Ω; VCAN = 5 V; P_10.3.32 Propagation Delay TXD HIGH to bus recessive td(H),T – 50 – ns CAN Normal Mode CL = 100 pF; RL = 60 Ω; VCAN = 5 V; P_10.3.33 Propagation Delay bus dominant to RXD LOW td(L),R – 100 – ns CAN Normal Mode CL = 100pF; RL = 60 Ω; VCAN = 5 V; CRXD = 15 pF P_10.3.34 Propagation Delay bus recessive to RXD HIGH td(H),R – 100 – ns CAN Normal Mode CL = 100pF; RL = 60 Ω VCAN = 5 V; CRXD = 15 pF P_10.3.35 400 – 550 ns CAN Normal Mode CL = 100pF; RL = 60 Ω; VCAN = 5 V; CRXD = 15 pF; tbit(TXD) = 500ns; Refer to Figure 31 P_10.3.46 Recessive Bit Width on RXD tbit(RXD) (CAN FD up to 2Mbps) Data Sheet Values 72 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Table 17 Electrical Characteristics (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; 4.75 V < VCAN < 5.25 V; RL = 60Ω; CAN Normal Mode; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Min. Typ. Max. TXD Permanent Dominant Time-out tTxD_CAN_TO – 2 BUS Permanent Dominant Time-out tBUS_CAN_TO – 2 1) 2) 3) 4) 5) 6) Values Unit Note / Test Condition Number – ms 4) CAN Normal Mode P_10.3.36 – ms 4) P_10.3.37 CAN Normal Mode Not subject to production test, specified by design. fTXD = 250 kHz rectangular signal, duty cycle = 50%; Rtest between supply (VS / VCAN) and 0V (GND); Not subject to production test, tolerance defined by internal oscillator tolerance; Wake-up is signalized via INT pin activation in SBC Stop Mode and via VCC1 ramping up with wake from SBC Sleep Mode; Time starts with end of last dominant phase of WUP; V TXD V CC 1 GND V DIFF t d(L ),T V diff, rd_N V diff, dr_N t d(L),R V RXD V CC 1 t t d(H),T t t d(H),R t d(L),TR td (H),TR 0.8 x VCC 1 GND 0.2 x V CC1 t CA N dynamic characteristics.vsd Figure 30 Data Sheet Timing Diagrams for Dynamic Characteristics 73 Rev. 1.1, 2014-09-26 TLE9261QX High Speed CAN Transceiver Figure 31 Data Sheet Timing Diagrams for RXD recessive bit width definition tbit(RXD) 74 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 11 Wake and Voltage Monitoring Inputs 11.1 Block Description Internal Supply I PU_WK + WKx I PD_WK t WK VRef Logic MONx_Input_Circuit_ext.vsd Figure 32 Wake Input Block Diagram Features • Three High-Voltage inputs with a 3V (typ.) threshold voltage • Alternate Measurement function for high-voltage sensing via WK1 and WK2 • Wake-up capability for power saving modes • Edge sensitive wake feature LOW to HIGH and HIGH to LOW • Pull-up and Pull-down current sources, configurable via SPI • Selectable configuration for static sense or cyclic sense working with TIMER1, TIMER2 • In SBC Normal and SBC Stop Mode the level of the WK pin can be read via SPI even if the respective WK is not enabled as a wake source. Data Sheet 75 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 11.2 Functional Description The wake input pins are edge-sensitive inputs with a switching threshold of typically 3V. This means that both transitions, HIGH to LOW and LOW to HIGH, result in a signalization by the SBC. The signalization occurs either in triggering the interrupt in SBC Normal Mode and SBC Stop Mode or by a wake up of the device in SBC Sleep and SBC Fail-Safe Mode. Two different wake detection modes can be selected via SPI: • Static sense: WK inputs are always active • Cyclic sense: WK inputs are only active for a certain time period (see Chapter 5.2.1) Two different filter times of 16µs or 64µs can be selected to avoid a parasitic wake-up due to transients or EMC disturbances in static sense configuration. The filter time (tFWK1, tFWK2) is triggered by a level change crossing the switching threshold and a wake signal is recognized if the input level will not cross again the threshold during the selected filter time. Figure 33 shows a typical wake-up timing and parasitic filter. VWK VWK,th VWK,th t VINT tWK,f tWK,f t INT t No Wake Event Figure 33 Wake Event Wake-up Filter Timing for Static Sense The wake-up capability for each WK pin can be enabled or disabled via SPI command in the WK_CTRL_2 register. The wake source for a wake via a WKx pin can always be read in the register WK_STAT_1 at the bits WK1_WU, WK2_WU, and WK3_WU. The actual voltage level of the WK pin (LOW or HIGH) can always be read in SBC Normal and SBC Stop Mode in the register WK_LVL_STAT. During Cyclic Sense, the register show the sampled levels of the respective WK pin. If FO2...3 are configured as WK inputs in its alternative function (16µs static filter time), then the wake events will be signalled in the register WK_STAT_2. Data Sheet 76 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 11.2.1 Wake Input Configuration To ensure a defined and stable voltage levels at the internal comparator input it is possible to configure integrated current sources via the SPI register WK_PUPD_CTRL. In addition, the wake detection modes (including the filter time) can be configured via the SPI register WK_FLT_CTRL. An example illustration for the automatic switching configuration is shown in Figure 34. Table 18 WKx_PUPD _1 Pull-Up / Pull-Down Resistor WKx_PUPD _0 Current Sources Note 0 0 no current source WKx input is floating if left open (default setting) 0 1 pull-down WKx input internally pulled to GND 1 0 pull-up WKx input internally pulled to internal 5V supply 1 1 Automatic switching If a high level is detected at the WKx input the pull-up source is activated, if low level is detected the pull down is activated. Note: If there is no pull-up or pull-down configured on the WK input, then the respective input should be tied to GND or VS on board to avoid unintended floating of the pin and subsequent wake events. IWKth_min I WK I WKth_max VWKth Figure 34 Illustration for Pull-Up / Down Current Sources with Automatic Switching Configuration Table 19 Wake Detection Configuration and Filter Time WKx_FLT_1 WKx_FLT_0 Filter Time Description 0 0 Config A static sense, 16µs filter time 0 1 Config B static sense, 64µs filter time 1 0 Config C Cyclic sense, Timer 1, 16µs filter time. Period, On-time configurable in register TIMER1_CTRL 1 1 Config D Cyclic sense, Timer 2, 16µs filter time. Period, On-time configurable in register TIMER2_CTRL Config A and B are intended for static sense with two different filter times. Config C or D are intended for cyclic sense configuration. With the filter settings, the respective timer needs to be assigned to one or more HS output, which supplies an external circuit connected to the WKx pin, e.g. HS1 controlled by Timer 2 (HS1 = 010) and connected to WK3 via an switch circuitry - see also Chapter 5.2. Data Sheet 77 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 11.2.2 Alternate Measurement Function with WK1 and WK2 11.2.2.1 Block Description This function provides the possibility to measure a voltage, e.g. the unbuffered battery voltage, with the protected WK1 HV-input. The measured voltage is routed out at WK2. It allows for example a voltage compensation for LED lighting by changing the duty cycle of the High-Side outputs. A simple voltage divider needs to be placed externally to provide the correct voltage level to the microcontroller A/D converter input. The function is available in SBC Normal Mode and it is disabled in all other modes to allow a low-quiescent current operation.The measurement function can be used instead of the WK1 and WK2 wake and level signalling capability. The benefits of the function is that the signal is measured by a HV-input pin and that there is no current flowing through the resistor divider during low-power modes. The functionality is shown in a simplified application diagram in Figure 55. 11.2.2.2 Functional Description This measurement function is by default disabled. In this case, WK1 and WK2 have the regular wake and voltage level signalization functionality. The switch S1 is open for this configuration (see Figure 55). The measurement function can be enabled via the SPI bit WK_MEAS. If WK_MEAS is set to ‘1’, then the measurement function is enabled and switch S1 is closed in SBC Normal Mode. S1 is open in all other SBC modes. If this function the pull-up and down currents of WK1 and WK2 are disabled, and the internal WK1 and WK2 signals are gated. In addition, the settings for WK1 and WK2 in the registers WK_PUPD_CTRL, WK_FLT_CTRL and WK_CTRL_2 are ignored but changing these setting is not prevented. The registers WK_STAT_1 and WK_LVL_STAT are not updated with respect to the inputs WK1 and WK2. However, if only WK1 or WK2 are set as wake sources and a SBC Sleep Mode command is set, then the SPI_FAIL flag will be set and the SBC will be changed into SBC Restart Mode (see Chapter 5.1 also for wake capability of WK1 and WK2). Table 20 Differences between Normal WK Function and Measurement Function Affected Settings/Modules for WK1 and WK2 Inputs WK_MEAS = 0 WK_MEAS = 1 S1 configuration ‘open’ ‘closed’ in SBC Normal Mode, ‘open’ in all other SBC Modes Internal WK1 & WK2 signal processing Default wake and level signaling function, WK_STAT_1, WK_STAT_2 are updated accordingly ‘WK1...2 inputs are gated internally, WK_STAT_1, WK_STAT_2 are not updated WK1_EN, WK2_EN Wake-up via WK1 and WK2 possible if setting the bits is ignored and not bits are set prevented. If only WK1_EN, WK2_EN are set while trying to go to SBC Sleep Mode, then the SPI_FAIL flag will be set and the SBC will be changed into SBC Restart Mode. WK_PUPD_CTRL normal configuration is possible no pull-up or pull-down enabled WK_FLT_CTRL normal configuration is possible setting the bits is ignored and not prevented Note: There is a diode in series to the switch S1 (not shown in the Figure 55), which will influence the temperature behavior of the switch. Data Sheet 78 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 11.3 Electrical Characteristics Table 21 Electrical Characteristics VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Min. Unit Note / Test Condition Number Typ. Max. 3 4 V without external serial resistor RS (with RS: ∆V = IPD/PU * RS); hysteresis included P_12.3.1 - 0.7 V without external serial resistor RS (with RS: ∆V = IPD/PU * RS); P_12.3.2 VWK_IN = 4V VWK_IN = 2V P_12.3.3 P_12.3.5 WK1...WK3 Input Pin Characteristics Wake-up/monitoring threshold voltage VWKth Threshold hysteresis VWKNth,hys 0.1 WK pin Pull-up Current IPU_WK 2 -20 -10 -3 µA WK pin Pull-down Current IPD_WK 3 10 20 µA Input leakage current ILK,l -2 2 µA 0 V < VWK_IN < 40V – 1000 – mV 1) Drop Voltage P_12.3.13 between WK1 and WK2 when enabled for voltage measurement; IWK1 = 500µA; Tj = 25°C Refer to Figure 35 - 16 - µs 2) P_12.3.6 µs 2) P_12.3.7 Drop Voltage across S1 VDrop,S1 switch P_12.3.4 Timing Wake-up filter time 1 Wake-up filter time 2 tFWK1 tFWK2 - 64 - SPI Setting SPI Setting 1) Not subject to production test; specified by design 2) Not subject to production test, tolerance defined by internal oscillator tolerance Data Sheet 79 Rev. 1.1, 2014-09-26 TLE9261QX Wake and Voltage Monitoring Inputs 1100 VS = 13.5V VS1,VOLTA AGEDROPOFSWITCHS1(mV) 1000 500 μA 900 800 250 μA 700 100 μA 600 50 μA 500 50 0 50 100 150 Tj JUNCTIONTEMPERATURE(°C) Figure 35 Data Sheet Typical Drop Voltage Characteristics of S1 (between WK1 & WK2) 80 Rev. 1.1, 2014-09-26 TLE9261QX Interrupt Function 12 Interrupt Function 12.1 Block and Functional Description Vcc1 Time out Interrupt logic Figure 36 INT Interrupt Block Diagram The interrupt is used to signalize special events in real time to the microcontroller. The interrupt block is designed as a push/pull output stage as shown in Figure 36. An interrupt is triggered and the INT pin is pulled low (active low) for tINT in SBC Normal and Stop Mode and it is released again once tINT is expired. The minimum HIGH-time of INT between two consecutive interrupts is tINTD. An interrupt does not cause a SBC mode change. Two different interrupt classes could be selected via the SPI bit INT_ GLOBAL: • Class 1 (wake interrupt - INT_ GLOBAL=0): all wake-up events stored in the wake status SPI register (WK_STAT_1 and WK_STAT_2) cause an interrupt (default setting). An interrupt is only triggered if the respective function is also enabled as a wake source (including GPIOx if configured as a wake input). • Class 2 (global interrupt - INT_ GLOBAL=1): in addition to the wake-up events, all signalled failures stored in the other status registers cause an interrupt (the register WK_LVL_STAT is not generating interrupts) Note: The errors which will cause SBC Restart or SBC Fail-Safe Mode (Vcc1_UV, WD_FAIL, VCC1_SC, TSD2, FAILURE) are the exceptions of an INT generation on status bits. Also POR and DEV_STAT_x and will not generate interrupts. In addition to this behavior, an INT will be triggered when the SBC is sent to SBC Stop Mode and not all bits were cleared in the WK_STAT_1 and WK_STAT_2register. The SPI status registers are updated at every falling edge of the INT pulse. All interrupt events are stored in the respective register (except the register WK_LVL_STAT) until the register is read and cleared via SPI command. A second SPI read after reading out the respective status register is optional but recommended to verify that the interrupt event is not present anymore. The interrupt behavior is shown in Figure 37 for class 1 interrupts. The behavior for class 2 is identical. The INT pin is also used during SBC Init Mode to select the hardware configuration of the device. See Chapter 5.1.1 for further information. Data Sheet 81 Rev. 1.1, 2014-09-26 TLE9261QX Interrupt Function WK1 WK2 INT tINTD tINT Scenario 2 Scenario 1 Update of WK_STAT register Update of WK_STAT register optional SPI Read & Clear WK_STAT contents SPI Read & Clear WK1 no WK WK2 no WK WK1 + WK2 no WK No SPI Read & Clear Command sent WK_STAT contents Interrupt_Behavior .vsd Figure 37 Data Sheet Interrupt Signalization Behavior 82 Rev. 1.1, 2014-09-26 TLE9261QX Interrupt Function 12.2 Electrical Characteristics Table 22 Interrupt Output VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified. Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. VINT,H 0.8 × – – V 1) IINT = -1 mA; INT = OFF P_13.2.1 VINT,L – – 0.2 × V 1) IINT = 1 mA; INT = ON P_13.2.2 µs 2) P_13.2.3 Interrupt Output; Pin INT INT High Output Voltage INT Low Output Voltage tINT INT Pulse Minimum Delay tINTD INT Pulse Width VCC1 VCC1 – 100 – – 100 – µs 2) between consecutive pulses P_13.2.4 Time Configuration Select; Pin INT Config Pull-down Resistance RCFG – 250 – kΩ VINT = 5 V P_13.2.5 Config Select Filter Time tCFG_F – 7 – µs 2) P_13.2.6 1) Output Voltage Value also determines device configuration during SBC Init Mode 2) Not subject to production test, tolerance defined by internal oscillator tolerance. Data Sheet 83 Rev. 1.1, 2014-09-26 TLE9261QX Fail Outputs 13 Fail Outputs 13.1 Block and Functional Description 5V_int SBC Init Mode T test R TEST FO1/2 Failure logic FO3/TEST T FO_PL Failure Logic Figure 38 Simplified Fail Output Block Diagram for FO1/2 and for FO3/TEST The fail outputs consist of a failure logic block and three open-drain outputs (FO1, FO2, FO3) with active-low signalization. The fail outputs are activated due to following failure conditions: • Watchdog trigger failure (For config 3&4 only after the 2nd watchdog trigger failure and for config 1&2 after 1st watchdog trigger failure) • Thermal shutdown TSD2 • VCC1 short to GND • VCC1 over voltage (only if the SPI bit VCC1_OV_RST is set) • After 4 consecutive VCC1 under voltage event (see Chapter 14.6 for details) At the same time SBC Fail-Safe Mode is entered (exceptions are watchdog trigger failures depending on selected configurations - see Chapter 5.1.1). The fail output activation is signalled in the SPI bit FAILURE of the register DEV_STAT. For testing purposes only the Fail Outputs can also be activated via SPI by setting the bit FO_ON. This bit is independent of the FO failure bits. In case that there is no failure condition, the FO outputs can also be turned off again via SPI, i.e. no successful watchdog trigger is needed. The entry of SBC Fail-Safe Mode due to a watchdog failure can be configured as described in Chapter 5.1.1. In order to deactivate the fail outputs in SBC Normal Mode the failure conditions must not be present anymore (e.g. TSD2, VCC1 short circuit, etc) and the bit FAILURE needs to be cleared via SPI command. In case of a FAILURE bit setting due to a watchdog fail, a successful WD trigger is needed in addition, i.e. WD_FAIL must be cleared. WD_FAIL will also be cleared when going to SBC Sleep or SBC Fail-Safe Mode due to another failure (not a WD failure) or if the watchdog is disabled in SBC Stop Mode. Note: The Fail output pin is triggered for any of the above described failures. No FAILURE is caused for the 1st watchdog failure if selected for Config2. The three fail outputs are activated simultaneously with following output functionalities: • FO1: Static fail output • FO2: 1.25Hz, 50% (typ.) duty cycle, e.g. to generate an indicator signal Data Sheet 84 Rev. 1.1, 2014-09-26 TLE9261QX Fail Outputs • FO3: 100Hz PWM, 20% (typ.) duty cycle, e.g. to generate a dimmed rear light from a break light. Note: The duty cycle for FO3 can be configured via SPI option to 20%, 10%, 5% or 2.5%. Default value is 20%. See the register FO_DC for configuration. 13.1.1 General Purpose I/O Functionality of FO2 and FO3 as Alternate Function In case that FO2 and FO3 are not used in the application, those pins can also be configured with an alternate function as high-voltage (VSHS related) General Purpose I/O pins. VSHS Config & Control Logic Figure 39 FOx/ GPIOx Simplified General Purpose I/O block diagram for FO2 and FO3/TEST The pins are by default configured as FO pins. The configuration is done via the SPI register GPIO_CTRL. The alternate function can be: • Wake Inputs: The detection threshold VGPIOI,th is similar as for the WK inputs. The wake-up detection behavior is the same as for WKx pins. Wake events are stored and reported in WK_STAT_2. • Low-Side Switches: The switch is able to drive currents of up to 10mA (see also VGPIOL,L1). It is self-protected with regards to current limitation. No other diagnosis is implemented. • High-Side Switches: The switch is able to drive currents up to 10mA (see also VGPIOH,H1). It is self-protected with regards to current limitation. No other diagnosis is implemented. • If configured as GPIO then the respective level at the pin will be shown in WK_LVL_STAT in SBC Normal and Stop Mode. This is also the case if configured as LS/HS and can serve as a feedback about the respective state. GPIO2 is shared with the TEST level bit. Figure 40 describes the behavior of the FO/GPIO pins in their different configurations and SBC modes. Function FOx WK HS LS Figure 40 Normal Mode configurable Stop Mode keeps the state wake capable as configured in Normal Mode as configured in Normal Mode Sleep Mode keeps the state wake capable OFF OFF Fail-Safe Mode active OFF OFF OFF FO / GPIO behavior for the respective SBC modes Note: In order to avoid unintentional entry of SBC Development Mode care must be taken that the level of FO3/TEST is HIGH during device power up and SBC Init Mode. Note: The FOx drivers are supplied via VS. However, the GPIO HS switches (FO2, FO3/TEST) are supplied by VSHS Data Sheet 85 Rev. 1.1, 2014-09-26 TLE9261QX Fail Outputs 13.2 Electrical Characteristics Table 23 Interrupt Output VSHS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified.1) Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number Pin FO1 FO1 low output voltage (active) VFO,L1 – – 1.0 V IFO = 4mA P_14.2.1 FO1 high output current (inactive) IFO,H 0 – 2 µA VFO = 28V P_14.2.2 FO2 side indicator frequency fFO2SI 1.00 1.25 1.50 Hz 3) P_14.2.3 FO2 side indicator duty cycle dFO2SI – 50 – % 3) P_14.2.4 Pull-up Resistance at pin FO3/TEST RTEST 2.5 5 10 kΩ VTEST =0V; SBC Init Mode P_14.2.5 TEST Input Filter Time tTEST fFO3PL – 64 – µs 3) P_14.2.6 80 100 120 Hz 3) P_14.2.7 dFO3PL – 20 – % 3)4) Pin FO2 Pin FO3/TEST2) FO3 pulsed light frequency FO3 pulsed light duty cycle default setting P_14.2.8 Alternate FO2...3 Electrical Characteristics: GPIO GPIO low-side output voltage (active) VGPIOL,L1 – – 1 V IGPIO = 10mA P_14.2.9 GPIO low-side output voltage (active) VGPIOL,L2 – – 5 mV 5) IGPIO = 50µA P_14.2.17 GPIO high-side output voltage (active) VGPIOH,H1 VSHS-1 – – V IGPO = -10mA P_14.2.10 GPIO high-side output voltage (active) VGPIOH,H2 VSHS-5 – – mV 5) P_14.2.18 GPIO input threshold voltage VGPIOI,th 1.5 2.5 3.5 V 6) hysteresis included P_14.2.11 GPIO input threshold hysteresis VGPIOI,hys 100 400 700 mV 5) P_14.2.12 GPIO low-side current limitation IGPIOL,max 10 – 30 mA VGPIO = 28V P_14.2.13 GPIO high-side current limitation IGPIOH,max -45 – -10 mA VGPIO = 0V P_14.2.14 IGPO = -50µA 1) The FOx drivers are supplied via VS. However, the GPIO HS switches (FO2, FO3/TEST) are supplied by VSHS Data Sheet 86 Rev. 1.1, 2014-09-26 TLE9261QX Fail Outputs 2) The external capacitance on this pin must be limited to less than 10nF to ensure proper detection of SBC Development Mode and SBC User Mode operation. 3) Not subject to production test, tolerance defined by internal oscillator tolerance. 4) The duty cyclic is adjustable via the SPI bits FO_DC. 5) Not subject to production test, specified by design. 6) Applies also for TEST voltage input level Data Sheet 87 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14 Supervision Functions 14.1 Reset Function VCC1 RO Reset logic Incl. filter & delay Figure 41 Reset Block Diagram 14.1.1 Reset Output Description The reset output pin RO provides a reset information to the microcontroller, for example, in the event that the output voltage has fallen below the under voltage threshold VRT1/2/3/4. In case of a reset event, the reset output RO is pulled to low after the filter time tRF and stays low as long as the reset event is present plus a reset delay time tRD1. When connecting the SBC to battery voltage, the reset signal remains LOW initially. When the output voltage Vcc1 has reached the reset default threshold VRT1,r, the reset output RO is released to HIGH after the reset delay time tRD1. A reset can also occur due to a watchdog trigger failure. The reset threshold can be adjusted via SPI, the default reset threshold is VRT1,f. The RO pin has an integrated pull-up resistor. In case reset is triggered, it will be pulled low for Vcc1 ≥ 1V and for VS ≥ VPOR,f (see also Chapter 14.3). The timings for the RO triggering regarding VCC1 under voltage and watchdog trigger is shown in Figure 42. Data Sheet 88 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions VCC VRT1 t < tRF The reset threshold can be configured via SPI in SBC Normal Mode , default is VRT1 undervoltage t RD1 t CW tLW tCW SPI SPI Init tOW t tLW tOW WD Trigger t CW t RD1 WD Trigger SPI Init t tRF RO tLW = long open window tCW = closed window tOW= open window t SBC Init Figure 42 Reset Timing Diagram 14.1.2 Soft Reset Description SBC Normal SBC Restart SBC Normal In SBC Normal and SBC Stop Mode, it is also possible to trigger a device internal reset via a SPI command in order to bring the SBC into a defined state in case of failures. In this case the microcontroller must send a SPI command and set the MODE bits to ‘11’ in the M_S_CTRL register. As soon as this command becomes valid, the SBC is set back to SBC INIT Mode and all SPI registers are set to their default values (see SPI Chapter 15.5 and Chapter 15.6). Two different soft reset configurations are possible via the SPI bit SOFT_ RESET_RO: • The reset output (RO) is triggered when the soft reset is executed (default setting, the same reset delay time tRD1 applies) • The reset output (RO) is not triggered when the soft reset is executed Note: The device must be in SBC Normal Mode or SBC Stop Mode when sending this command. Otherwise, the command will be ignored. Data Sheet 89 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.2 Watchdog Function The watchdog is used to monitor the software execution of the microcontroller and to trigger a reset if the microcontroller stops serving the watchdog due to a lock up in the software. Two different types of watchdog functions are implemented and can be selected via the bit WD_WIN: • Time-Out Watchdog (default value) • Window Watchdog The respective watchdog functions can be selected and programmed in SBC Normal Mode. The configuration stays unchanged in SBC Stop Mode. Please refer to Table 24 to match the SBC Modes with the respective watchdog modes. Table 24 Watchdog Functionality by SBC Modes SBC Mode Watchdog Mode Remarks INIT Mode Starts with Long Open Window Watchdog starts with Long Open Window after RO is released Normal Mode WD Programmable Stop Mode Watchdog is fixed or OFF Sleep Mode OFF SBC will start with Long Open Window when entering SBC Normal Mode. Restart Mode OFF SBC will start with Long Open Window when entering SBC Normal Mode. Window Watchdog, Time-Out watchdog or switched OFF for SBC Stop Mode The watchdog timing is programmed via SPI command. As soon as the watchdog is programmed, the timer starts with the new setting and the watchdog must be served. The watchdog is triggered by sending a valid SPI-write command to the watchdog configuration register. The trigger SPI command is executed when the Chip Select input (CSN) becomes HIGH. When coming from SBC Init, SBC Restart Mode or in certain cases from SBC Stop Mode, the watchdog timer is always started with a long open window. The long open window (tLW = 200ms) allows the microcontroller to run its initialization sequences and then to trigger the watchdog via SPI. The watchdog timer period can be selected via the watchdog timing bit field (WD_TIMER) and is in the range of 10 ms to 1000 ms. This setting is valid for both watchdog types. The following watchdog timer periods are available: • WD Setting 1: 10ms • WD Setting 2: 20ms • WD Setting 3: 50ms • WD Setting 4: 100ms • WD Setting 5: 200ms • WD Setting 6: 500ms • WD Setting 7: 1000ms In case of a watchdog reset, SBC Restart or SBC Fail-Safe Mode is entered according to the configuration and the SPI bits WD_FAIL are set. Once the RO goes HIGH again the watchdog immediately starts with a long open window the SBC enters automatically SBC Normal Mode. In SBC Software Development Mode the watchdog is OFF and therefore no reset and interrupt are generated due to a watchdog failure. Data Sheet 90 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions Depending on the configuration, the WD_FAIL bits will be set after a watchdog trigger failure as follows: • In case an incorrect WD trigger is received (triggering in the closed watchdog window or when the watchdog counter expires without a valid trigger) then the WD_FAIL bits will be increased (showing the number of incorrect WD triggers) • For config 2: the bits can have the maximum value of ‘01’ • For config 1, 3 and 4: the bits can have the maximum value of ‘10’ The WD_FAIL bits are cleared automatically when following conditions apply: • After a successful watchdog trigger • When the watchdog is OFF: in SBC Stop Mode after successfully disabling it, in SBC Sleep Mode, or in SBC Fail-Safe Mode (except for a watchdog failure) 14.2.1 Time-Out Watchdog The time-out watchdog is an easier and less secure watchdog than a window watchdog as the watchdog trigger can be done at any time within the configured watchdog timer period. A correct watchdog service immediately results in starting a new watchdog timer period. Taking the tolerances of the internal oscillator into account leads to the safe trigger area as defined in Figure 43. If the time-out watchdog period elapses, a watchdog reset is created by setting the reset output RO low and the SBC switches to SBC Restart or SBC Fail-Safe Mode. Typical timout watchdog trigger period t WD x 1.50 open window uncertainty Watchdog Timer Period (WD_TIMER) tWD x 1.20 t WD x 1.80 t / [tWD_TIMER] safe trigger area Wd1_TimeOut_per.vsd Figure 43 Data Sheet Time-out Watchdog Definitions 91 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.2.2 Window Watchdog Compared to the time-out watchdog the characteristic of the window watchdog is that the watchdog timer period is divided between an closed and an open window. The watchdog must be triggered within the open window. A correct watchdog trigger results in starting the window watchdog period by a closed window followed by an open window. The watchdog timer period is at the same time the typical trigger time and defines the middle of the open window. Taking the oscillator tolerances into account leads to a safe trigger area of: tWD x 0.72 < safe trigger area < tWD x 1.20. The typical closed window is defined to a width of 60% of the selected window watchdog timer period. Taking the tolerances of the internal oscillator into account leads to the timings as defined in Figure 44. A correct watchdog service immediately results in starting the next closed window. Should the trigger signal meet the closed window or should the watchdog timer period elapse, then a watchdog reset is created by setting the reset output RO low and the SBC switches to SBC Restart or SBC Fail-Safe Mode. tWD x 0.6 tWD x 0.9 Typ. closed window Typ. open window tWD x 0.48 closed window tWD x 0.72 uncertainty tWD x 1.0 tWD x 1.20 open window tWD x 1.80 uncertainty Watchdog Timer Period (WD_TIMER) t / [tWD _TIMER ] safe trigger area Figure 44 Window Watchdog Definitions 14.2.3 Watchdog Setting Check Sum A check sum bit is part of the SPI commend to trigger the watchdog and to set the watchdog setting. The sum of the 8 data bits in the register WWD_CTRL needs to have even parity (see Equation (3)). This is realized by either setting the bit CHECKSUM to 0 or 1. If the check sum is wrong, then the SPI command is ignored, i.e. the watchdog is not triggered or the settings are not changed and the bit SPI_FAIL is set. The checksum is calculated by taking all 8 data bits into account. The written value of the reserved bit 3 of the WWD_CTRL register is considered (even if read as ‘0’ in the SPI output) for checksum calculation, i.e. if a 1 is written on the reserved bit position, then a 1 will be used in the checksum calculation. (3) CHKSUM = Bit15 ⊕ … ⊕ Bit8 Data Sheet 92 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.2.4 Watchdog during SBC Stop Mode The watchdog can be disabled for SBC Stop Mode in SBC Normal Mode. For safety reasons, there is a special sequence to be followed in order to disable the watchdog as described in Figure 45. Two different SPI bits (WD_STM_ EN_0, WD_STM_ EN_1) in the registers WK_CTRL_1 and WD_CTRL need to be set. Correct WD disabling sequence Sequence Errors • Missing to set bit WD_STM_EN_0 with the next watchdog trigger after having set WD_STM_EN_1 • Staying in Normal Mode instead of going to Stop Mode with the next trigger Set bit WD_STM_EN_1 = 1 with next WD Trigger Set bit WD_STM_EN_0 = 1 Before subsequent WD Trigger Will enable the WD : Change to SBC Stop Mode • Switching back to SBC Normal Mode • Triggering the watchdog WD is switched off Figure 45 Watchdog disabling sequence in SBC Stop Mode If a sequence error occurs, then the bit WD_STM_ EN_1 will be cleared and the sequence has to be started again. The watchdog can be enabled by triggering the watchdog in SBC Stop Mode or by switching back to SBC Normal Mode via SPI command. In both cases the watchdog will start with a long open window and the bits WD_STM_EN_1 and WD_STM_ EN_0 are cleared. After the long open window the watchdog has to be served as configured in the WD_CTRL register. Note: The bit WD_STM_ EN_0 will be cleared automatically when the sequence is started and it was 1 before. 14.2.5 Watchdog Start in SBC Stop Mode due to Bus Wake In SBC Stop Mode the Watchdog can be disabled. In addition a feature is available which will start the watchdog with any BUS wake (CAN) during SBC Stop Mode. The feature is enabled by setting the bit WD_EN_ WK_BUS = 1 (= default value after POR). The bit can only be changed in SBC Normal Mode and needs to be programmed before starting the watchdog disable sequence. A wake on CAN will generate an interrupt and the RXD pin for CAN is pulled to low. By these signals the microcontroller is informed that the watchdog is startedwith a long open window. After the long open window the watchdog has to be served as configured in the WD_CTRL register. To disable the watchdog again, the SBC needs to be switched to Normal Mode and the sequence needs to be sent again. Data Sheet 93 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.3 VS Power On Reset At power up of the device, the VS Power on Reset is detected when VS > VPOR,r and the SPI bit POR is set to indicate that all SPI registers are set to POR default settings. VCC1 is starting up and the reset output will be kept LOW and will only be released once VCC1 has crossed VRT1,r and after tRD1 has elapsed. In case VS < VPOR,f, an device internal reset will be generated and the SBC is switched OFF and will restart in INIT mode at the next VS rising. This is shown in Figure 46. VS VPOR,r VPOR,f t VCC1 VRT1,r The reset threshold can be configured via SPI in SBC Normal Mode , default is VRT1 VRTx,f t RO SBC Restart Mode is entered whenever the Reset is triggered t SBC Mode SBC OFF tRD1 SBC INIT MODE Any SBC MODE Restart SBC OFF t SPI Command Figure 46 Data Sheet Ramp up / down example of Supply Voltage 94 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.4 Under Voltage VS and VSHS If the supply voltage VS reaches the under voltage threshold VS,UV then the SBC does the following measures: • SPI bit VS_UV is set. No other error bits are set. The bit can be cleared once the condition is not present anymore, • VCC3 is disabled (see Chapter 8.2) unless the control bit VCC3_VS_ UV_OFF is set • The VCC1 short circuit protection becomes inactive (see Chapter 14.7). However, the thermal protection of the device remains active. If the under voltage threshold is exceeded (VS rising) then functions will be automatically enabled again. If the supply voltage VSHS passes below the under voltage threshold (VSHS,UVD) the SBC does the following measures: • HS1...4 are acting accordingly to the SPI setting (see Chapter 9) • SPI bit VSHS_UV is set. No other error bits are set. The bit can be cleared once the condition is not present anymore, • VCC1, VCC2, WKx and CAN are not affected by VSHS under voltage 14.5 Over Voltage VSHS If the supply voltage VSHS reaches the over voltage threshold (VSHS,OVD) the SBC triggers the following measures: • HS1...4 are acting accordingly to the SPI setting (see Chapter 9) • SPI bit VSHS_OV is set. No other error bits are set. The bit can be cleared once the condition is not present anymore, • VCC1, VCC2, VCC3, WKx and CAN are not affected by VS over voltage 14.6 VCC1 Over-/ Under Voltage and Under Voltage Prewarning 14.6.1 VCC1 Under Voltage and Under Voltage Prewarning A first-level voltage detection threshold is implemented as a prewarning for the microcontroller. The prewarning event is signaled with the bit VCC1_ WARN. No other actions are taken. As described in Chapter 14.1 and Figure 47, a reset will be triggered (RO pulled ‘low’) when the VCC1 output voltage falls below the selected under voltage threshold (VRTx). The bit VCC1_UV is set and the SBC will enter SBC Restart Mode. Note: The VCC1_ WARN or VCC1_UV bits are not set in Sleep Mode as VCC1 = 0V in this case Data Sheet 95 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions VCC1 VRTx tRF t tRD1 RO t SBC Normal Figure 47 SBC Restart SBC Normal VCC1 Under Voltage Timing Diagram An additional safety mechanism is implemented to avoid repetitive VCC1 under voltage resets due to high dynamic loads on VCC1: • A counter is increased for every consecutive VCC1 under voltage event (regardless on the selected reset threshold), • The counter is active in SBC Init-, Normal-, and Stop Mode, • For VS < VS,UV the counter will be stopped in SBC Normal Mode (i.e. the VS UV comparator is always enabled in SBC Normal Mode), • A 4th consecutive VCC1 under voltage event will lead to SBC Fail-Safe Mode entry and to setting the bit VCC1_UV _FS • This counter is cleared: – when SBC Fail-Safe Mode is entered, – when the bit VCC1_UV is cleared, – when a Soft Reset is triggered. Note: It is recommended to clear the VCC1_UV bit once it was set and detected. 14.6.2 VCC1 Over Voltage For fail-safe reasons a configurable VCC1 over voltage detection feature is implemented. It is active in SBC Init-, Normal-, and Stop Mode. In case the VCC1,OV,r threshold is crossed, the SBC triggers following measures depending on the configuration: • The bit VCC1_ OV is always set; • If the bit VCC1_OV_RST is set and CFGP = ‘1’, then SBC Restart Mode is entered. The FOx outputs are activated. After the reset delay time (tRD1), the SBC Restart Mode is left and SBC Normal Mode is resumed even if the VCC1 over voltage event is still present (see also Figure 48). The VCC1_OV_RST bit is cleared automatically; • If the bit VCC1_OV_RST is set and CFGP = ‘0’, then SBC Fail-Safe Mode is entered and FOx outputs are activated. Note: In case the VCC1 output current in SBC STOP Mode is below the active peak threshold (IVCC1,Ipeak) it should be considered to clear the bit VCC1_OV_RST before entering SBC Stop Mode to avoid unintentional SBC Restart or Fail-Safe Mode entry and to ignore the VCC1_ OV bit due to external noise. Data Sheet 96 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions VCC1 VCC1,OV t tOV_filt RO tRD1 t SBC Normal SBC Restart Figure 48 VCC1 Over Voltage Timing Diagram 14.7 VCC1 Short Circuit and VCC3 Diagnostics SBC Normal The short circuit protection feature for VCC1 is implemented as follows (VS needs to be higher than VS,UV): • If VCC1 is not above the VRTx within tVCC1,SC after device power up or after waking from SBC Sleep Mode then the SPI bit VCC1_SC bit is set, VCC1 is turned OFF, the FOx pins are enabled, FAILURE is set and SBC FailSafe Mode is entered. The SBC can be activated again via wake on CAN, WKx. • The same behavior applies, if VCC1 falls below VRTx for more than tVCC1,SC. VCC3 diagnosis features are implemented as follows: • Load Sharing: The external PNP is disabled when VS < VS,UV if VCC3_VS_ UV_OFF = 0 or when in SBC Stop Mode if VCC3_LS_ STP_ON = ‘0’. All other diagnostic features are disabled because they are provided via VCC1. • Stand-alone configuration: The external PNP is disabled when VCC3 < VS,UV if VCC3_VS_ UV_OFF = 0. The overcurrent limitation is signalled via the bit VCC3_OC according to the selected shunt resistor, VCC3 undervoltage is signalled via the bit VCC3_UV and the regulator is disabled due to VS undervoltage when VS,UV is reached. Note: Neither VCC1_SC nor VCC3_UV flags are set during power up of VCC1 or turn on of VCC3 respectively. 14.8 VCC2 Undervoltage and VCAN Undervoltage An undervoltage warning is implemented for VCC2 and VCAN as follows: • VCC2 undervoltage Detection: In case VCC2 will drop below the VCC2,UV,f threshold, then the SPI bit VCC2_UV is set and can be only cleared via SPI. • VCAN undvervoltage Detection: In case the voltage on VCAN will drop below the VCAN_UV threshold, then the SPI bit VCAN_UV is set and can be only cleared via SPI. Note: The VCC2_UV flag is not set during turn-on or turn-off of VCC2. Data Sheet 97 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.9 Thermal Protection Three independent and different thermal protection features are implemented in the SBC according to the system impact: • Individual thermal shutdown of specific blocks • Temperature prewarning of main microcontroller supply VCC1 • SBC thermal shutdown due to VCC1 over temperature 14.9.1 Individual Thermal Shutdown As a first-level protection measure the output stages VCC2, CAN, and HSx are independently switched OFF if the respective block reaches the temperature threshold TjTSD1. Then the TSD1 bit is set. This bit can only be cleared via SPI once the overtemperature is not present anymore. Independent of the SBC Mode the thermal shutdown protection is only active if the respective block is ON. The respective modules behave as follows: • VCC2: Is switched to OFF and the control bits VCC2_ON are cleared. The status bit VCC2_OT is set. Once the over temperature condition is not present anymore, then VCC2 has to be configured again by SPI. • VCC3 as a stand-alone regulator: Is switched to OFF and the control bits VCC3_ON are cleared. The status bit VCC3_OT is set. Once the over temperature condition is not present anymore VCC3 has to be configured again by SPI. It is recommended to clear the VCC3_OT bit before enabling the regulator again. • VCC3 in load sharing configuration: in case of over temperature at VCC3 the bit VCC3_OT is set and VCC3 is switched off. The regulator will be switched on again automatically once the overtemperature event is not present anymore. Also in this case it is recommended to clear the VCC3_OT bit right away. • CAN: The transmitter is disabled and stays in CAN Normal Mode acting like CAN Receive only mode. The status bits CAN_FAIL = ‘01’ are set. Once the over temperature condition is not present anymore, then the CAN transmitter is automatically switched on. • HSx: If one or more HSx switches reach the TSD1 threshold, then all HSx switches are turned OFF and the control bits for HSx are cleared (see registers HS_CTRL1 and HS_CTRL2). The status bits HSx_OC_OT are set (see register HS_OC_OT_STAT). Once the over temperature condition is not present anymore, then HSx has to be configured again by SPI. Note: The diagnosis bits are not cleared automatically and have to be cleared via SPI once the overtemperature condition is not present anymore. Data Sheet 98 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.9.2 Temperature Prewarning As a next level of thermal protection a temperature prewarning is implemented if the main supply VCC1 reaches the thermal prewarning temperature threshold TjPW. Then the status bit TPW is set. This bit can only be cleared via SPI once the overtemperature is not present anymore. Independent of the SBC Mode the thermal prewarning is only active if the VCC1 is ON. 14.9.3 SBC Thermal Shutdown As a highest level of thermal protection a temperature shutdown of the SBC is implemented if the main supply VCC1 reaches the thermal shutdown temperature threshold TjTSD2. Once a TSD2 event is detected SBC Fail-Safe Mode is entered for tTSD2 to allow the device to cool down. After this time has expired, the SBC will automatically change via SBC Restart Mode to SBC Normal Mode (see also Chapter 5.1.6). When a TSD2 event is detected, then the status bit TSD2 is set. This bit can only be cleared via SPI in SBC Normal Mode once the overtemperature is not present anymore. Independent of the SBC Mode the thermal shutdown is only active if VCC1 is ON. Data Sheet 99 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions 14.10 Electrical Characteristics Table 25 Electrical Specification VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified. Parameter Symbol Values Min. Typ. Max. Unit Note / Test Condition Number VCC1 Monitoring; VCC1 = 5.0V Version Undervoltage Prewarning Threshold Voltage PW,f VPW,f 4.6 4.7 4.85 V VCC1 falling, SPI bit is set P_15.10.1 Reset Threshold Voltage RT1,f VRT1,f 4.5 4.6 4.75 V default setting; VCC1 falling P_15.10.3 Reset Threshold Voltage RT1,r VRT1,r 4.6 4.7 4.85 V default setting; VCC1 rising P_15.10.4 Reset Threshold Voltage RT2,f VRT2,f 3.75 3.9 4.05 V VCC1 falling P_15.10.5 Reset Threshold Voltage RT2,r VRT2,r 3.85 4.0 4.15 V VCC1 rising P_15.10.6 Reset Threshold Voltage RT3,f VRT3,f 3.15 3.3 3.45 V VS ≥ 4V; VCC1 falling P_15.10.7 Reset Threshold Voltage RT3,r VRT3,r 3.25 3.4 3.55 V VS ≥ 4V; VCC1 rising P_15.10.8 Reset Threshold Voltage RT4,f VRT4,f 2.4 2.65 2.8 V VS ≥ 4V; VCC1 falling P_15.10.9 Reset Threshold Voltage RT4,r VRT4,r 2.5 2.75 2.9 V VS ≥ 4V; VCC1 rising P_15.10.10 Reset Threshold Hysteresis VRT,hys VCC1,OV,r 50 100 200 mV – P_15.10.11 5.2 – 5.5 V 1)5) tVCC1,SC – 4 – ms 3) P_15.10.12 Reset Low Output Voltage VRO,L – 0.2 0.4 V P_15.10.14 Reset High Output Voltage VRO,H 0.8 x – VCC1 + V IRO = 1 mA for VCC1 ≥ 1 V & VS ≥ VPOR,f IRO = -20 µA VCC1 Over Voltage Detection Threshold Voltage VCC1 Short to GND Filter Time rising VCC1 P_15.10.50 Reset Generator; Pin RO Reset Pull-up Resistor Reset Filter Time RRO tRF VCC1 P_15.10.15 0.3 V 10 20 40 kΩ 4 10 26 µs VRO = 0 V 3) VCC1 < VRT1x P_15.10.16 P_15.10.17 to RO = L see also Chapter 14.3 Reset Delay Time tRD1 1.5 2 2.5 ms 2) 3) P_15.10.18 VCC2,UV,f 4.5 – 4.75 V VCC2 falling P_15.10.19 VCC2 Monitoring VCC2 Undervoltage Threshold Voltage (falling) Data Sheet 100 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions Table 25 Electrical Specification (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified. Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. 4.6 – 4.9 V VCC2 rising P_15.10.77 20 100 250 mV – P_15.10.20 VCC3 Undervoltage Detection VCC3,UV VCC3 Undervoltage Detection VCC3,UV 4.0 4.25 4.5 V hysteresis included P_15.10.21 2.65 2.85 3.00 V 3.3V option or P_15.10.47 VCC3_ V_CFG=1 hysteresis included VCC3 Undervoltage detection VCC3,UV, hys 20 100 250 mV – P_15.10.22 VCAN_UV 4.45 – 4.85 V CAN Normal Mode, hysteresis included; P_15.10.23 tLW fCLKSBC – 200 – ms 3) P_15.10.24 0.8 1.0 1.2 MHz – P_15.10.25 – ms 3)4) P_15.10.75 VCC2 Undervoltage Threshold Voltage (rising) VCC2,UV,r VCC2 Undervoltage detection VCC2,UV, hys hysteresis VCC3 Monitoring hysteresis VCAN Monitoring CAN Supply under voltage detection threshold Watchdog Generator Long Open Window Internal Oscillator Minimum Waiting time during SBC Fail-Safe Mode Min. waiting time Fail-Safe tFS,min – 100 Power-on Reset, Over / Under Voltage Protection VPOR,r VPOR,f VS,UV – 4.5 V VS increasing P_15.10.26 – 3 V VS decreasing P_15.10.27 6.0 V P_15.10.13 Supply UV supervision for VCC3 and VCC1 SC detection; hysteresis included VSHS Over Voltage Detection Threshold VSHS,OVD 20 22 V P_15.10.28 Supply OV supervision for HSx; hysteresis included VSHS Over Voltage Detection hysteresis VSHS,OVD,hys – – mV 5) VSHS Under Voltage Detection Threshold VSHS,UVD 5.5 V P_15.10.30 Supply UV supervision for HSx, and HS of GPIOx; hysteresis included VS Power on reset rising VS Power on reset falling VS Under Voltage Detection Threshold Data Sheet 5.3 – 500 4.8 101 P_15.10.29 Rev. 1.1, 2014-09-26 TLE9261QX Supervision Functions Table 25 Electrical Specification (cont’d) VS = 5.5 V to 28 V; Tj = -40 °C to +150 °C; SBC Normal Mode; all voltages with respect to ground; positive current defined flowing into pin; unless otherwise specified. Parameter Symbol Values Min. VSHS Under Voltage Detection hysteresis VSHS,UVD,hys – Unit Note / Test Condition Number 5) P_15.10.31 Typ. Max. 200 – mV Over Temperature Shutdown5) Thermal Prewarning Temperature TjPW 125 145 165 °C P_15.10.32 Thermal Shutdown TSD1 TjTSD1 TjTSD2 TjTSD,hys 165 185 200 °C P_15.10.33 165 185 200 °C P_15.10.34 – 25 – °C P_15.10.68 tTSD2 – 1 – s Thermal Shutdown TSD2 Thermal Shutdown hysteresis Deactivation time after thermal shutdown TSD2 3) P_15.10.35 1) It is ensured that the threshold VCC1,OV,r is always higher than the highest regulated VCC1 output voltage VCC1,out42. 2) 3) 4) 5) The reset delay time will start when VCC1 crosses above the selected Vrtx threshold Not subject to production test, tolerance defined by internal oscillator tolerance. This time applies for all failure entries except a device thermal shutdown (TSD2 has a typ. 1s waiting time tTSD2) Not subject to production test, specified by design. Data Sheet 102 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15 Serial Peripheral Interface 15.1 SPI Block Description The 16-bit wide Control Input Word is read via the data input SDI, which is synchronized with the clock input CLK provided by the microcontroller. The output word appears synchronously at the data output SDO (see Figure 49). The transmission cycle begins when the chip is selected by the input CSN (Chip Select Not), LOW active. After the CSN input returns from LOW to HIGH, the word that has been read is interpreted according to the content. The SDO output switches to tristate status (high impedance) at this point, thereby releasing the SDO bus for other use.The state of SDI is shifted into the input register with every falling edge on CLK. The state of SDO is shifted out of the output register after every rising edge on CLK. The SPI of the SBC is not daisy chain capable. CSN high to low: SDO is enabled. Status information transferred to output shift register CSN time CSN low to high: data from shift register is transferred to output functions CLK time Actual data SDI 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 SDI: will accept data on the falling edge of CLK signal Actual status SDO ERR 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 - New data 0 1 + + time New status ERR 0 + 1 + time SDO: will change state on the rising edge of CLK signal Figure 49 Data Sheet SPI Data Transfer Timing (note the reversed order of LSB and MSB shown in this figure compared to the register description) 103 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.2 Failure Signalization in the SPI Data Output When the microcontroller sends a wrong SPI command to the SBC, the SBC ignores the information. Wrong SPI commands are either invalid SBC mode commands or commands which are prohibited by the state machine to avoid undesired device or system states (see below). In this case the diagnosis bit ‘SPI_FAIL’ is set and the SPI Write command is ignored (mostly no partial interpretation). This bit can be only reset by actively clearing it via a SPI command. Invalid SPI Commands leading to SPI_FAIL are listed below: • Illegal state transitions: Going from SBC Stop to SBC Sleep Mode. In this case the SBC enters in addition the SBC Restart Mode; Trying to go to SBC Stop or SBC Sleep mode from SBC Init Mode. In this case SBC Normal Mode is entered; • Uneven parity in the data bit of the WD_CTRL register. In this case the watchdog trigger is ignored or the new watchdog settings are ignored respectively; • In SBC Stop Mode: attempting to change any SPI settings, e.g. changing the watchdog configuration, PWM settings and HS configuration settings during SBC Stop Mode, etc.; the SPI command is ignored in this case; only WD trigger, returning to Normal Mode, triggering a SBC Soft Reset, and Read & Clear status registers commands are valid SPI commands in SBC Stop Mode; • When entering SBC Stop Mode and WK_STAT_1 and WK_STAT_2 are not cleared; SPI_FAIL will not be set but the INT pin will be triggered; • Changing from SBC Stop to Normal Mode and changing the other bits of the M_S_CTRL register. The other modifications will be ignored; • SBC Sleep Mode: attempt to go to Sleep Mode when all bits in the BUS_CTRL_1 and WK_CTRL_2 registers are cleared. In this case the SPI_FAIL bit is set and the SBC enters Restart Mode. Even though the Sleep Mode command is not entered in this case, the rest of the command (e.g modifying VCC2 or VCC3) is executed and the values stay unchanged during SBC Restart Mode; Note: At least one wake source must be activated in order to avoid a deadlock situation in SBC Sleep Mode, i.e. the SBC would not be able to wake up anymore. If the only wake source is a timer and the timer is OFF then the SBC will wake immediately from Sleep Mode and enter Restart Mode; No failure handling is done for the attempt to go to SBC STOP Mode when all bits in the registers BUS_CTRL_1 and WK_CTRL_2 are cleared because the microcontroller can leave this mode via SPI; • If VCC3 load sharing VCC3_LS is enabled and the microcontroller tries to clear the bit, then the rest of the command executed but VCC3_LS will remain set; • Attempt to enter SBC Sleep Mode if WK_MEAS is set to ‘1’ and only WK1_EN or WK2_EN are set as wake sources. Also in this case the SPI_FAIL bit is set and the SBC enters Restart Mode; • Setting a longer or equal on-time than the timer period of the respective timer; • SDI stuck at HIGH or LOW, e.g. SDI received all ‘0’ or all ‘1’; Note: There is no SPI fail information for unused addresses. Signalization of the ERR Flag (high active) in the SPI Data Output (see Figure 49): The ERR flag presents an additional diagnosis possibility for the SPI communication. The ERR flag is being set for following conditions: • in case the number of received SPI clocks is not 0 or 16, • in case RO is LOW and SPI frames are being sent at the same time. Note: In order to read the SPI ERR flag properly, CLK must be low when CSN is triggered, i.e. the ERR bit is not valid if the CLK is high on a falling edge of CSN Data Sheet 104 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface The number of received SPI clocks is not 0 or 16: The number of received input clocks is supervised to be 0- or 16 clock cycles and the input word is discarded in case of a mismatch (0 clock cycle to enable ERR signalization). The error logic also recognizes if CLK was high during CSN edges. Both errors - 0 bit and 16 bit CLK mismatch or CLK high during CSN edges - are flagged in the following SPI output by a “HIGH” at the data output (SDO pin, bit ERR) before the first rising edge of the clock is received. The complete SPI command is ignored in this case. RO is LOW and SPI frames are being sent at the same time: The ERR flag will be set when the RO pin is triggered (during SBC Restart) and SPI frames are being sent to the SBC at the same time. The behavior of the ERR flag will be signalized at the next SPI command for below conditions: • if the command begins when RO is HIGH and it ends when RO is LOW, • if a SPI command will be sent while RO is LOW, • If a SPI command begins when RO is LOW and it ends when RO is HIGH. and the SDO output will behave as follows: • always when RO is LOW then SDO will be HIGH, • when a SPI command begins with RO is LOW and ends when RO is HIGH, then the SDO should be ignored because wrong data will be sent. Note: It is possible to quickly check for the ERR flag without sending any data bits. i.e. only the CSN is pulled low and SDO is observed - no SPI Clocks are sent in this case Note: The ERR flag could also be set after the SBC has entered SBC Fail-Safe Mode because the SPI communication is stopped immediately. Data Sheet 105 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.3 SPI Programming For the TLE9261QX, 7 bits are used or the address selection (BIT6...0). Bit 7 is used to decide between Read Only and Read & Clear for the status bits, and between Write and Read Only for configuration bits. For the actual configuration and status information, 8 data bits (BIT15...8) are used. Writing, clearing and reading is done byte wise. The SPI status bits are not cleared automatically and must be cleared by the microcontroller, e.g. if the TSD2 was set due to over temperature. The configuration bits will be partially automatically cleared by the SBC - please refer to the individual registers description for detailed information. During SBC Restart Mode the SPI communication is ignored by the SBC, i.e. it is not interpreted. There are two types of SPI registers: • Control registers: Those are the registers to configure the SBC, e.g. SBC mode, watchdog trigger, etc • Status registers: Those are the registers where the status of the SBC is signalled, e.g. wake events, warnings, failures, etc. For the status registers, the requested information is given in the same SPI command in DO. For the control registers, also the status of the respective byte is shown in the same SPI command. However, if the setting is changed this is only shown with the next SPI command (it is only valid after CSN high) of the same register. The SBC status information from the SPI status registers, is transmitted in a compressed way with each SPI response on SDO in the so called Status Information Field register (see also Figure 50). The purpose of this register is to quickly signal the information to the microcontroller if there was a change in one of the SPI status registers. In this way, the microcontroller does not need to read constantly all the SPI status registers but only those registers, which were changed. Each bit in the Status Information Field represents a SPI status register (see Table 26). As soon as one bit is set in one of the status registers, then the respective bit in the Status Information Field register will be set. The register WK_LVL_STAT is not included in the status Information field. This is listed in Table 26. For Example if bit 0 in the Status Information Field is set to 1, one or more bits of the register 100 0001 (SUP_STAT_1) is set to 1. Then this register needs to be read in a second SPI command. The bit in the Status Information Field will be set to 0 when all bits in the register 100 0001 are set back to 0. Table 26 Status Information Field Bit in Status Information Field Corresponding Address Bit Status Register Description 0 100 0001 SUP_STAT_1: Supply Status -VSHS fail, VCCx fail, POR 1 100 0010 THERM_STAT: Thermal Protection Status 2 100 0011 DEV_STAT: Device Status - Mode before Wake, WD Fail, SPI Fail, Failure 3 100 0100 BUS_STAT: Bus Failure Status: CAN; 4 100 0110 WK_STAT_1, WK_STAT_2: Wake Source Status; Status bit is set as combinational OR of both registers 5 100 0000 SUP_STAT_2: VCC1_WARN/OV, VCC3 Status 6 101 0100 HS_OC_OT_STAT: High-Side Over Load Status 7 101 0101 HS_OL_STAT: High-Side Open Load Status Data Sheet 106 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface LSB DI 0 MSB 1 2 3 4 5 6 Address Bits 7 8 9 10 11 12 13 14 15 Data Bits R/W x x x x x x x x Register content of selected address DO 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 Status Information Field Data Bits x x x x x x x x time LSB is sent first in SPI message Figure 50 Data Sheet SPI Operation Mode 107 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.4 SPI Bit Mapping The following figures show the mapping of the registers and the SPI bits of the respective registers. The Control Registers ‘000 0000’ to ‘001 1110’ are Read/Write Register. Depending on bit 7 the bits are only read (setting bit 7 to ‘0’) or also written (setting bit 7 to ‘1’). The new setting of the bit after write can be seen with a new read / write command. The registers ‘100 0000’ to ‘111 1110’ are Status Registers and can be read or read with clearing the bit (if possible) depending on bit 7. To clear a Data Byte of one of the Status Registers bit 7 must be set to 1. The registers WK_LVL_STAT, and FAM_PROD_STAT are an exception as they show the actual voltage level at the respective WK pin (LOW/HIGH), or a fixed family/ product ID respectively and can thus not be cleared. It is recommended for proper diagnosis to clear respective status bits for wake events or failure. However, in general it is possible to enable drivers without clearing the respective failure flags. When changing to a different SBC Mode, certain configurations bits will be cleared automatically or modified: • The SBC Mode bits are updated to the actual status, e.g. when returning to Normal Mode • When changing to a low-power mode (Stop/Sleep), the diagnosis bits of the switches and transceivers are not cleared. FOx will stay activated if it was triggered before. • When changing to SBC Stop Mode, the CAN control bits will not be modified. • When changing to SBC Sleep Mode, the CAN control bits will be modified if they were not OFF or wake capable before. • HSx, VCC2 and VCC3 will stay on when going to Sleep-/Stop Mode (configuration can only be done in Normal Mode). Diagnosis is active (OC, OL, OT). In case of a failure the switch is turned off and no wake-up is issued • The configuration bits for HSx and VCC2 in stand-alone configuration are cleared in SBC Restart Mode. FOx will stay activated if it was triggered before. Depending on the respective configuration, CAN transceivers will be either OFF, woken or still wake capable. Note: The detailed behavior of the respective SPI bits and control functions is described in Chapter 15.5, Chapter 15.6.and in the respective module chapter. The bit type be marked as ‘rwh’ in case the SBC will modify respective control bits. Data Sheet 108 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface MSB LSB 9 Status Registers Control Registers 8 Data Bits [bits 8... 15] Figure 51 Data Sheet for Configuration & Status Information M_S_CTRL HW_CTRL WD_CTRL BUS_CTRL_1 BUS_CTRL_2 WK_CTRL_1 WK_CTRL_2 WK_PUPD_CTRL WK_FLT_CTRL TIMER1_CTRL TIMER2_CTRL SW_SD_CTRL HS_CTRL_1 HS_CTRL_2 GPIO_CTRL PWM1_CTRL PWM2_CTRL PWM_FREQ_CTRL SYS_STAT_CTRL SUP_STAT_2 SUP_STAT_1 THERM_STAT DEV_STAT BUS_STAT_1 WK_STAT_1 WK_STAT_2 WK_LVL_STAT HS_OC_OT_STAT HS_OL_STAT FAM_PROD_STAT 8 7 Reg. Type rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw rw rc rc rc rc rc rc rc r rc rc r 6 5 4 3 2 1 0 7 Address Bits [bits 0...6] for Register Selection 0 0 0 0 0 0 1 0 0 0 0 0 1 0 0 0 0 0 0 1 1 0 0 0 0 1 0 0 0 0 0 0 1 0 1 0 0 0 0 1 1 0 0 0 0 0 1 1 1 0 0 0 1 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 0 0 0 0 0 1 1 0 1 0 0 1 0 0 0 0 0 0 1 0 1 0 0 0 0 1 0 1 0 1 0 0 1 0 1 1 1 0 0 1 1 0 0 0 0 0 1 1 0 0 1 0 0 1 1 1 0 0 0 0 1 1 1 1 0 1 0 0 0 0 0 0 1 0 0 0 0 0 1 1 0 0 0 0 1 0 1 0 0 0 0 1 1 1 0 0 0 1 0 0 1 0 0 0 1 1 0 1 0 0 0 1 1 1 1 0 0 1 0 0 0 1 0 1 0 1 0 0 1 0 1 0 1 0 1 1 1 1 1 1 1 0 5 0 1 2 3 4 4 6 7 Status Information Field Bit 15 14 13 12 11 10 SPI Register Mapping 109 Rev. 1.1, 2014-09-26 Figure 52 Data Sheet 110 D6 14 D5 13 reserved POR reserved DEV_STAT_1 reserved reserved reserved SBC_DEV_LVL reserved reserved FAM_3 FAM_PROD_STAT FAM_2 VS_UV VSHS_UV reserved DEV_STAT_0 reserved reserved reserved CFGP reserved reserved VCC3_OC VCC2_OT reserved reserved reserved TIMER_WU GPIO1_WU GPIO1_LVL reserved VCC3_UV VCC2_UV reserved WD_FAIL_1 reserved reserved reserved reserved HS4_OC_OT HS4_OL STATUS REGISTERS VCC2_ON_0 VCC3_LS reserved reserved reserved reserved reserved WK2_PUPD_1 WK2_FLT_1 reserved reserved reserved reserved reserved GPIO2_0 PWM1_DC_3 PWM2_DC_3 reserved SYS_STAT_3 D1 9 D0 8 VCC3_OT VCC1_SC TSD2 WD_FAIL_0 CAN_FAIL_1 WK3_WU reserved WK3_LVL HS3_OC_OT HS3_OL PROD_1 VCC1_OV VCC1_UV_FS TSD1 SPI_FAIL CAN_FAIL_0 WK2_WU reserved WK2_LVL HS2_OC_OT HS2_OL PROD_0 VCC1_WARN VCC1_UV TPW FAILURE VCAN_UV WK1_WU reserved WK1_LVL HS1_OC_OT HS1_OL VCC1_OV_RST VCC1_RT_1 VCC1_RT_0 reserved VCC3_LS_STP_ON CFG WD_TIMER_2 WD_TIMER_1 WD_TIMER_0 reserved CAN_1 CAN_0 reserved reserved reserved WD_STM_EN_1 reserved reserved WK3_EN WK2_EN WK1_EN WK2_PUPD_0 WK1_PUPD_1 WK1_PUPD_0 WK2_FLT_0 WK1_FLT_1 WK1_FLT_0 TIMER1_PER_2 TIMER1_PER_1 TIMER1_PER_0 TIMER2_PER_2 TIMER2_PER_1 TIMER2_PER_0 reserved reserved reserved HS1_2 HS1_1 HS1_0 HS3_2 HS3_1 HS3_0 GPIO1_2 GPIO1_1 GPIO1_0 PWM1_DC_2 PWM1_DC_1 PWM1_DC_0 PWM2_DC_2 PWM2_DC_1 PWM2_DC_0 PWM2_FREQ_0 reserved PWM1_FREQ_0 SYS_STAT_2 SYS_STAT_1 SYS_STAT_0 D2 10 F A M I LY A N D P R O D U C T R E G I S T E R S FAM_1 FAM_0 PROD_3 PROD_2 reserved VSHS_OV reserved reserved reserved CAN_WU GPIO2_WU GPIO2_LVL reserved D3 11 CONTROL REGISTERS 12 Data Bit 15…8 D4 MODE_1 MODE_0 VCC3_ON VCC2_ON_1 VCC3_V_CFG SOFT_RESET_RO FO_ON VCC3_VS_UV_OFF CHECKSUM WD_STM_EN_0 WD_WIN WD_EN_WK_BUS reserved reserved reserved reserved reserved reserved I_PEAK_TH reserved TIMER2_WK_EN TIMER1_WK_EN reserved reserved INT_GLOBAL reserved WK_MEAS reserved reserved reserved WK3_PUPD_1 WK3_PUPD_0 reserved reserved WK3_FLT_1 WK3_FLT_0 reserved TIMER1_ON_2 TIMER1_ON_1 TIMER1_ON_0 reserved TIMER2_ON_2 TIMER2_ON_1 TIMER2_ON_0 reserved HS_OV_SD_EN HS_UV_SD_EN HS_OV_UV_REC reserved HS2_2 HS2_1 HS2_0 reserved HS4_2 HS4_1 HS4_0 FO_DC_1 FO_DC_0 GPIO2_2 GPIO2_1 PWM1_DC_7 PWM1_DC_6 PWM1_DC_5 PWM1_DC_4 PWM2_DC_7 PWM2_DC_6 PWM2_DC_5 PWM2_DC_4 reserved reserved reserved reserved SYS_STAT_7 SYS_STAT_6 SYS_STAT_5 SYS_STAT_4 D7 15 SUP_STAT_2 SUP_STAT_1 THERM_STAT DEV_STAT BUS_STAT_1 WK_STAT_1 WK_STAT_2 WK_LVL_STAT HS_OC_OT_STAT HS_OL_STAT M_S_CTRL HW_CTRL WD_CTRL BUS_CTRL_1 BUS_CTRL_2 WK_CTRL_1 WK_CTRL_2 WK_PUPD_CTRL WK_FLT_CTRL TIMER1_CTRL TIMER2_CTRL SW_SD_CTRL HS_CTRL_1 HS_CTRL_2 GPIO_CTRL PWM1_CTRL PWM2_CTRL PWM_FREQ_CTRL SYS_STAT_CTRL Register Short Name read read/clear read/clear read/clear read/clear read/clear read/clear read/clear read read/clear read/clear read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write read/write 7 Access Mode 1111110 1000000 1000001 1000010 1000011 1000100 1000110 1000111 1001000 1010100 1010101 0000001 0000010 0000011 0000100 0000101 0000110 0000111 0001000 0001001 0001100 0001101 0010000 0010100 0010101 0010111 0011000 0011001 0011100 0011110 6...0 Address A6…A0 TLE9261QX Serial Peripheral Interface TLE9261QX SPI Bit Mapping Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.5 SPI Control Registers READ/WRITE Operation (see also Chapter 15.3): • The ‘POR / Soft Reset Value’ defines the register content after POR or SBC Reset. • The ‘Restart Value’ defines the register content after SBC Restart, where ‘x’ means the bit is unchanged. • One 16-bit SPI command consist of two bytes: - the 7-bit address and one additional bit for the register access mode and - following the data byte The numbering of following bit definitions refers to the data byte and correspond to the bits D0...D7 and to the SPI bits 8...15 (see also figure before). • There are three different bit types: - ‘r’ = READ: read only bits (or reserved bits) - ‘rw’ = READ/WRITE: readable and writable bits - ‘rwh’ = READ/WRITE/Hardware: readable/writable bits, which can also be modified by the SBC hardware • Reserved bits are marked as “Reserved” and always read as “0”. The respective bits shall also be programmed as “0”. • Reading a register is done byte wise by setting the SPI bit 7 to “0” (= Read Only). • Writing to a register is done byte wise by setting the SPI bit 7 to “1”. • SPI control bits are in general not cleared or changed automatically. This must be done by the microcontroller via SPI programming. Exceptions to this behavior are stated at the respective register description and the respective bit type is marked with a ‘h’ meaning that the SBC is able to change the register content. The registers are addressed wordwise. Data Sheet 111 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.5.1 General Control Registers M_S_CTRL Mode- and Supply Control (Address 000 0001B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00x0 00xxB 7 6 5 4 3 MODE_1 MODE_0 VCC3_ON VCC2_ON_1 VCC2_ON_0 rwh rwh rwh rwh rwh 2 1 VCC1_OV_RS VCC1_RT_1 T rwh r 0 VCC1_RT_0 rw rw Field Bits Type Description MODE 7:6 rwh SBC Mode Control 00B , SBC Normal Mode 01B , SBC Sleep Mode 10B , SBC Stop Mode 11B , SBC Reset: Soft Reset is executed (configuration of RO triggering in bit SOFT_ RESET_RO) VCC3_ON 5 rwh VCC3 Mode Control 0B , VCC3 OFF 1B , VCC3 is enabled (as independent voltage regulator) VCC2_ON 4:3 rwh VCC2 Mode Control 00B , VCC2 off 01B , VCC2 on in Normal Mode 10B , VCC2 on in Normal and Stop Mode 11B , VCC2 always on (except in SBC Fail-Safe Mode) VCC1_OV_R 2 ST rwh VCC1 Over Voltage leading to Restart / Fail-Safe Mode enable 0B , VCC1_ OV is set in case of VCC1_OV; no SBC Restart or FailSafe is entered for VCC1_OV 1B , VCC1_ OV is set in case of VCC1_OV; depending on the device configuration SBC Restart or SBC Fail-Safe Mode is entered (see Chapter 5.1.1); VCC1_RT rw VCC1 Reset Threshold Control 00B , Vrt1 selected (highest threshold) 01B , Vrt2 selected 10B , Vrt3 selected 11B , Vrt4 selected 1:0 Notes 1. It is not possible to change from Stop to Sleep Mode via SPI Command. See also the State Machine Chapter 2. After entering SBC Restart Mode, the MODE bits will be automatically set to SBC Normal Mode. The VCC2_ON bits will be automatically set to OFF after entering SBC Restart Mode and after OT. 3. The SPI output will always show the previously written state with a Write Command (what has been programmed before) Data Sheet 112 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface HW_CTRL Mode- and Supply Control (Address 000 0010B) POR / Soft Reset Value: y000 y000B; Restart Value: xx0x x00xB 7 6 5 4 3 2 1 0 VCC3_V_CFG SOFT_RESET _RO FO_ON VCC3_VS_UV _OFF VCC3_LS Reserved VCC3_LS_ST P_ON CFG rw rw rwh rw rw r rw rw r Field Bits Type Description VCC3_ V_CFG 7 rw VCC3 Output Voltage Configuration (if configured as independent voltage regulator) 0B , VCC3 has same output voltage as VCC1 1B , VCC3 is configured to either 3.3V or 1.8V (depending on VCC1 derivative) SOFT_ RESET_RO 6 rw Soft Reset Configuration 0B , RO will be triggered (pulled low) during a Soft Reset 1B , No RO triggering during a Soft Reset FO_ON 5 rwh Failure Output Activation (FO1..3) 0B , FOx not activated by software, FO can be activated by defined failures (see Chapter 13) 1B , FOx activated by software (via SPI) VCC3_VS_ UV_OFF 4 rw VCC3 VS_UV shutdown configuration 0B , VCC3 will be disabled automatically at VS_UV 1B , VCC3 will stay enabled even below VS_UV VCC3_LS 3 rw VCC3 Configuration 0B , VCC3 operating as a stand-alone regulator 1B , VCC3 in load sharing operation with VCC1 Reserved 2 r Reserved, always reads as 0 VCC3_LS_ STP_ON 1 rw VCC3 Load Sharing in SBC Stop Mode configuration 0B , VCC3 in LS configuration during SBC Stop Mode and highpower mode: disabled 1B , VCC3 in LS configuration during SBC Stop Mode and highpower mode: enabled CFG 0 rw Configuration Select (see also Table 5) 0B , Depending on hardware configuration, SBC Restart or FailSafe Mode is reached after the 2. watchdog trigger failure (=default) - Config 3/4 1B , Depending on hardware configuration, SBC Restart or FailSafe Mode is reached after the 1. watchdog trigger failure Config 1/2 Notes 1. Clearing the FO_ON bit will not disable the FOx outputs for the case a failure occurred which triggered the FOx outputs. In this case the FOx outputs have to be disabled by clearing the FAILURE bit. If the FO_ON bit is set by the software then it will be cleared by the SBC after SBC Restart Mode was entered and the FOx outputs will be disabled. See also Chapter 13 for FOx activation and deactivation. Data Sheet 113 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 2. After triggering a SBC Soft Reset the bits VCC3_V_CFG and VCC3_LS are not reset if they were set before, i.e. it stays unchanged, which is stated by the ‘y’ in the POR / Soft Reset Value. POR value: 0000 0000 and Soft Reset value: xx00 x00x 3. VCC3_LS_STP_ON: Is a combination of load sharing and VCC1 active peak in Stop mode Data Sheet 114 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WD_CTRL Watchdog Control (Address 000 0011B) POR / Soft Reset Value: 0001 0100B; Restart Value: x0xx 0100B 7 6 5 4 3 CHECKSUM WD_STM_ EN_0 WD_WIN WD_EN_ WK_BUS Reserved rw rwh rw rw r Field Bits CHECKSUM 7 2 1 0 WD_TIMER_2 WD_TIMER_1 WD_TIMER_0 rwh r rwh rwh Type Description rw Watchdog Setting Check Sum Bit The sum of bits 7:0 needs to have even parity (see Chapter 14.2.3) 0B , Counts as 0 for checksum calculation 1B , Counts as 1 for checksum calculation WD_STM_ EN_0 6 rwh Watchdog Deactivation during Stop Mode, bit 0 (Chapter 14.2.4) 0B , Watchdog is active in Stop Mode 1B , Watchdog is deactivated in Stop Mode WD_WIN 5 rw Watchdog Type Selection 0B , Watchdog works as a Time-Out watchdog 1B , Watchdog works as a Window watchdog WD_EN_ WK_BUS 4 rwh Watchdog Enable after Bus (CAN) Wake in SBC Stop Mode 0B , Watchdog will not start after a CAN wake 1B , Watchdog starts with a long open window after CAN Wake Reserved 3 r Reserved, always reads as 0 WD_TIMER 2:0 rwh Watchdog Timer Period 000B , 10ms 001B , 20ms 010B , 50ms 011B , 100ms 100B , 200ms 101B , 500ms 110B , 1000ms 111B , reserved Notes 1. See also Chapter 14.2.4 for more information on disabling the watchdog in SBC Stop Mode. 2. See Chapter 14.2.5 for more information on the effect of the bit WD_EN_WK_BUS. 3. See Chapter 14.2.3 for calculation of checksum. Data Sheet 115 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface BUS_CTRL_1 Bus Control (Address 000 0100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 00yyB 7 6 5 4 3 2 1 0 Reserved Reserved Reserved Reserved Reserved Reserved CAN_1 CAN_0 r r r r r r rwh rwh Field Bits Type Description Reserved 7:3 r Reserved, always reads as 0 Reserved 2 r Reserved, always reads as 0 CAN 1:0 rwh HS-CAN Module Modes 00B , CAN OFF 01B , CAN is wake capable 10B , CAN Receive Only Mode 11B , CAN Normal Mode r Notes 1. The reset values for the CAN transceivers are marked with ‘y’ because they will vary depending on the cause of change - see below. 2. see Figure 26 for detailed state changes of CAN Transceiver for different SBC modes. 3. Failure Handling Mechanism: When the device enters Fail-Safe Mode due to a failure (TSD2, WD-Failure,...), then the wake registers BUS_CTRL_1, and WK_CTRL_2 are reset to following values (=wake sources) ‘xxx0 1001’, ‘0000 0001’ and ‘x0xx 0111’ in order to ensure that the device can be woken again. Data Sheet 116 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface BUS_CTRL_2 Bus Control (Address 000 0101B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00x0 0000B 7 6 5 4 3 2 1 0 Reserved Reserved I_PEAK_TH Reserved Reserved Reserved Reserved Reserved r r rw r r r r r r Field Bits Type Description Reserved 7:6 r Reserved, always reads as 0 I_PEAK_TH 5 rw VCC1 Active Peak Threshold Selection 0B , low VCC1 active peak threshold selected (ICC1,peak_1) 1B , higher VCC1 active peak threshold selected (ICC1,peak_2) Reserved 4:0 r Reserved, always reads as 0 Notes 1. The bit I_PEAK_TH can be modified in SBC Init and Normal Mode. In SBC Stop Mode this bit is Read only but SPI_FAIL will not be set when trying to modify the bit in SBC STOP Mode and no INT is triggered in case INT_ GLOBAL is set. 2. see Figure 26 for detailed state changes of CAN Transceiver for different SBC modes 3. Failure Handling Mechanism: When the device enters Fail-Safe Mode due to a failure (TSD2, WD-Failure,...), then the wake registers BUS_CTRL_1, BUS_CTRL_2 and WK_CTRL_2 are reset to following values (=wake sources) ‘xxx0 1001’, ‘0000 0001’ and ‘x0xx 0111’ in order to ensure that the device can be woken again. Data Sheet 117 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_CTRL_1 Internal Wake Input Control (Address 000 0110B) POR / Soft Reset Value: 0000 0000B; Restart Value: xx00 0000B 7 6 TIMER2_WK_ TIMER1_WK_ EN EN rw Field 5 4 3 2 1 0 Reserved Reserved Reserved WD_STM_ EN_1 Reserved Reserved r r r rwh r r rw Type Description TIMER2_WK 7 _EN rw Timer2 Wake Source Control (for cyclic wake) 0B , Timer2 wake disabled 1B , Timer2 is enabled as a wake source TIMER1_WK 6 _EN rw Timer1 Wake Source Control (for cyclic wake) 0B , Timer1 wake disabled 1B , Timer1 is enabled as a wake source Reserved 5:3 r Reserved, always reads as 0 WD_STM_ EN_1 2 rwh Watchdog Deactivation during Stop Mode, bit 1 (Chapter 14.2.4) 0B , Watchdog is active in Stop Mode 1B , Watchdog is deactivated in Stop Mode Reserved 1:0 r Reserved, always reads as 0 Data Sheet Bits r 118 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_CTRL_2 External Wake Source Control (Address 000 0111B) POR / Soft Reset Value: 0000 0111B; Restart Value: x0x0 0xxxB 7 6 5 4 3 2 1 0 INT_GLOBAL Reserved WK_MEAS Reserved Reserved WK3_EN WK2_EN WK1_EN r rw r r rw rw rw w rw r Field Bits Type Description INT_ GLOBAL 7 rw Global Interrupt Configuration (see also Chapter 12.1) 0B , Only wake sources trigger INT (default) 1B , All status information register bits will trigger INT (including all wake sources) Reserved 6 r Reserved, always reads as 0 WK_MEAS 5 rw WK / Measurement selection (see also Chapter 11.2.2) 0B , WK functionality enabled for WK1 and WK2 1B , Measurement functionality enabled; WK1 & WK2 are disabled as wake sources, i.e. bits WK1/2_EN bits are ignored Reserved 4:3 r Reserved, always reads as 0 WK3_EN 2 rw WK3 Wake Source Control 0B , WK3 wake disabled 1B , WK3 is enabled as a wake source WK2_EN 1 rw WK2 Wake Source Control 0B , WK2 wake disabled 1B , WK2 is enabled as a wake source WK1_EN 0 rw WK1 Wake Source Control 0B , WK1 wake disabled 1B , WK1 is enabled as a wake source Notes 1. WK_MEAS is by default configured for standard WK functionality (WK1 and WK2). The bits WK1_EN and WK2_EN are ignored in case WK_MEAS is activated. If the bit is set to ‘1’ then the measurement function is enabled during Normal Mode & the bits WK1_EN and WK2_EN are ignored. The bits WK1/”_LVL bits need to be ignored as well. 2. The wake sources CAN are selected in the register BUS_CTRL_1 by setting the respective bits to ‘wake capable’ 3. Failure Handling Mechanism: When the device enters Fail-Safe Mode due to a failure (TSD2, WD-Failure,...), then the wake registers BUS_CTRL_1 and WK_CTRL_2 are reset to following values (=wake sources) ‘xxx0 1001’, ‘0000 0001’ and ‘x0xx 0111’ in order to ensure that the device can be woken again. Data Sheet 119 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_PUPD_CTRL Wake Input Level Control (Address 000 1000B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00xx xxxxB 7 6 Reserved Reserved r r 5 4 3 2 1 WK3_PUPD_1 WK3_PUPD_0 WK2_PUPD_1 WK2_PUPD_0 WK1_PUPD_1 WK1_PUPD_0 rw rw rw rw r rw Field Bits Type Description Reserved 7:6 r Reserved, always reads as 0 WK3_PUPD 5:4 rw WK3 Pull-Up / Pull-Down Configuration 00B , No pull-up / pull-down selected 01B , Pull-down resistor selected 10B , Pull-up resistor selected 11B , Automatic switching to pull-up or pull-down WK2_PUPD 3:2 rw WK2 Pull-Up / Pull-Down Configuration 00B , No pull-up / pull-down selected 01B , Pull-down resistor selected 10B , Pull-up resistor selected 11B , Automatic switching to pull-up or pull-down WK1_PUPD 1:0 rw WK1 Pull-Up / Pull-Down Configuration 00B , No pull-up / pull-down selected 01B , Pull-down resistor selected 10B , Pull-up resistor selected 11B , Automatic switching to pull-up or pull-down Data Sheet 0 120 rw Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_FLT_CTRL Wake Input Filter Time Control (Address 000 1001B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00xx xxxxB 7 6 5 4 3 2 1 0 Reserved Reserved WK3_FLT_1 WK3_FLT_0 WK2_FLT_1 WK2_FLT_0 WK1_FLT_1 WK1_FLT_0 r r rw rw rw rw rw rw r Field Bits Type Description Reserved 7:6 r Reserved, always reads as 0 WK3_FLT 5:4 rw WK3 Filter Time Configuration 00B , Configuration A: Filter with 16µs filter time (static sensing) 01B , Configuration B: Filter with 64µs filter time (static sensing) 10B , Configuration C: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer1 11B , Configuration D: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer2 WK2_FLT 3:2 rw WK2 Filter Time Configuration 00B , Configuration A: Filter with 16µs filter time (static sensing) 01B , Configuration B: Filter with 64µs filter time (static sensing) 10B , Configuration C: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer1 11B , Configuration D: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer2 WK1_FLT 1:0 rw WK1 Filter Time Configuration 00B , Configuration A: Filter with 16µs filter time (static sensing) 01B , Configuration B: Filter with 64µs filter time (static sensing) 10B , Configuration C: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer1 11B , Configuration D: Filtering at the end of the on-time; a filter time of 16µs (cyclic sensing) is selected, Timer2 Note: When selecting a filter time configuration, the user must make sure to also assign the respective timer to at least one HS switch during cyclic sense operation Data Sheet 121 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface TIMER1_CTRL Timer1 Control and Selection (Address 000 1100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0000B 7 6 5 4 3 2 1 0 Reserved TIMER1_ ON_2 TIMER1_ ON_1 TIMER1_ ON_0 Reserved TIMER1_ PER_2 TIMER1_ PER_1 TIMER1_ PER_0 r rwh rwh rwh r rwh rwh rwh r Field Bits Type Description Reserved 7 r Reserved, always reads as 0 TIMER1_ ON 6:4 rwh Timer1 On-Time Configuration 000B , OFF / Low (timer not running, HSx output is low) 001B , 0.1ms on-time 010B , 0.3ms on-time 011B , 1.0ms on-time 100B , 10ms on-time 101B , 20ms on-time 110B , OFF / HIGH (timer not running, HSx output is high) 111B , reserved Reserved 3 r Reserved, always reads as 0 TIMER1_ PER 2:0 rwh Timer1 Period Configuration 000B , 10ms 001B , 20ms 010B , 50ms 011B , 100ms 100B , 200ms 101B , 1s 110B , 2s 111B , reserved Notes 1. A timer must be first assigned and is then automatically activated as soon as the on-time is configured. 2. If cyclic sense is selected and the HS switches are cleared during SBC Restart Mode, then also the timer settings (period and on-time) are cleared to avoid incorrect switch detection. 3. in case the timer are set as wake sources and cyclic sense is running, then both cyclic sense and cyclic wake will be active at the same time. Data Sheet 122 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface TIMER2_CTRL Timer2 Control and selection (Address 000 1101B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0000B 7 6 5 4 3 2 1 0 Reserved TIMER2_ ON_2 TIMER2_ ON_1 TIMER2_ ON_0 Reserved TIMER2_ PER_2 TIMER2_ PER_1 TIMER2_ PER_0 r rwh rwh rwh r rwh rwh rwh r Field Bits Type Description Reserved 7 r Reserved, always reads as 0 TIMER2_ ON 6:4 rwh Timer2 On-Time Configuration 000B , OFF / Low (timer not running, HSx output is low) 001B , 0.1ms on-time 010B , 0.3ms on-time 011B , 1.0ms on-time 100B , 10ms on-time 101B , 20ms on-time 110B , OFF / HIGH (timer not running, HSx output is high) 111B , reserved Reserved 3 r Reserved, always reads as 0 TIMER2_ PER 2:0 rwh Timer2 Period Configuration 000B , 10ms 001B , 20ms 010B , 50ms 011B , 100ms 100B , 200ms 101B , 1s 110B , 2s 111B , reserved Notes 1. A timer must be first assigned and is then automatically activated as soon as the on-time is configured. 2. If cyclic sense is selected and the HS switches are cleared during SBC Restart Mode, then also the timer settings (period and on-time) are cleared to avoid incorrect switch detection. Data Sheet 123 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface SW_SD_CTRL Switch Shutdown Control (Address 001 0000B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0xxx 0000B 7 Reserved 6 5 4 HS_OV_SD_E HS_UV_SD_E HS_OV_UV_R N N EC r rw rw rw 3 2 1 0 Reserved Reserved Reserved Reserved r r r r r Field Bits Type Description Reserved 7 r Reserved, always reads as 0 HS_OV_SD_ 6 EN rw Shutdown Disabling of HS1...4 in case of VSHS OV 0B , shutdown enabled in case of VSHS OV 1B , shutdown disabled in case of VSHS OV HS_UV_SD_ 5 EN rw Shutdown Disabling of HS1...4 in case of VSHS UV 0B , shutdown enabled in case of VSHS UV 1B , shutdown disabled in case of VSHS UV HS_OV_UV_ 4 REC rw Switch Recovery after Removal of VSHS OV/UV for HS1...4 0B , Switch recovery is disabled 1B , Previous state before VSHS OV/UV is enabled after OV/UV condition is removed Reserved r Reserved, always reads as 0 Data Sheet 3:0 124 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface HS_CTRL1 High-Side Switch Control 1 (Address 001 0100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0000B 7 6 5 4 3 2 1 0 Reserved HS2_2 HS2_1 HS2_0 Reserved HS1_2 HS1_1 HS1_0 rw rwh rwh rwh r rwh rwh rwh Field Bits Type Description Reserved 7 r Reserved, always reads as 0 HS2 6:4 rwh HS2 Configuration 000B , Off 001B , On 010B , Controlled by Timer1 011B , Controlled by Timer2 100B , Controlled by PWM1 101B , Controlled by PWM2 110B , Reserved 111B , Reserved Reserved 3 r Reserved, always reads as 0 HS1 2:0 rwh HS1 Configuration 000B , Off 001B , On 010B , Controlled by Timer1 011B , Controlled by Timer2 100B , Controlled by PWM1 101B , Controlled by PWM2 110B , Reserved 111B , Reserved r Note: The bits for the switches are also reset in case of overcurrent and overtemperature. Data Sheet 125 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface HS_CTRL2 High-Side Switch Control 2 (Address 001 0101B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0000B 7 6 5 4 3 2 1 0 Reserved HS4_2 HS4_1 HS4_0 Reserved HS3_2 HS3_1 HS3_0 r rwh rwh rwh r rwh rwh rwh Field Bits Type Description Reserved 7 r Reserved, always reads as 0 HS4 6:4 rwh HS4 Configuration 000B , Off 001B , On 010B , Controlled by Timer1 011B , Controlled by Timer2 100B , Controlled by PWM1 101B , Controlled by PWM2 110B , Reserved 111B , Reserved Reserved 3 r Reserved, always reads as 0 HS3 2:0 rwh HS3 Configuration 000B , Off 001B , On 010B , Controlled by Timer1 011B , Controlled by Timer2 100B , Controlled by PWM1 101B , Controlled by PWM2 110B , Reserved 111B , Reserved r Note: The bits for the switches are also reset in case of overcurrent and overtemperature. Data Sheet 126 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface GPIO_CTRL GPIO Configuration Control (Address 001 0111B) POR / Soft Reset Value: 0000 0000B; Restart Value: xxxx xxxxB 7 6 5 4 3 2 1 0 FO_DC_1 FO_DC_0 GPIO2_2 GPIO2_1 GPIO2_0 GPIO1_2 GPIO1_1 GPIO1_0 rw rw rw rw rw rw rw rw r Field Bits Type Description FO_DC 7:6 rw Duty Cycle Configuration of FO3 (if selected) 00B , 20% 01B , 10% 10B , 5% 11B , 2.5% GPIO2 5:3 rw GPIO2 Configuration 000B , FO3 selected 001B , FO3 selected 010B , FO3 selected 011B , FO3 selected 100B , OFF 101B , Wake input enabled (16µs static filter) 110B , Low-Side Switch ON 111B , High-Side Switch ON GPIO1 2:0 rw GPIO1 Configuration 000B , FO2 selected 001B , FO2 selected 010B , FO2 selected 011B , FO2 selected 100B , OFF 101B , Wake input enabled (16µs static filter) 110B , Low-Side Switch ON 111B , High-Side Switch ON Note: When selecting a filter time configuration, the user must make sure to also assign the respective timer to at least one HS switch during cyclic sense operation Data Sheet 127 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface PWM1_CTRL PWM1 Configuration Control (Address 001 1000B) POR / Soft Reset Value: 0000 0000B; Restart Value: xxxx xxxxB 7 6 5 4 3 2 1 0 PWM1_DC_7 PWM1_DC_6 PWM1_DC_5 PWM1_DC_4 PWM1_DC_3 PWM1_DC_2 PWM1_DC_1 PWM1_DC_0 rw rw rw rw rw rw r Field Bits Type Description PWM1_DC 7:0 rw PWM1 Duty Cycle (bit0=LSB; bit7=MSB) 0000 0000B, 100% OFF xxxx xxxx B, ON with DC fraction of 255 1111 1111B, 100% ON rw rw Note: The min. On-time during PWM is limited by the actual Ton and Toff time of the respective HS switch, e.g. the PWM setting ‘000 0001’ could not be realized. PWM2_CTRL PWM2 Configuration Control (Address 001 1001B) POR / Soft Reset Value: 0000 0000B; Restart Value: xxxx xxxxB 7 6 5 4 3 2 1 0 PWM2_DC_7 PWM2_DC_6 PWM2_DC_5 PWM2_DC_4 PWM2_DC_3 PWM2_DC_2 PWM2_DC_1 PWM2_DC_0 rw rw rw rw rw rw r Field Bits Type Description PWM2_DC 7:0 rw PWM2 Duty Cycle (bit0=LSB; bit7=MSB) 0000 0000B, 100% OFF xxxx xxxxB, ON with DC fraction of 255 1111 1111B, 100% ON rw rw Note: The min. On-time during PWM is limited by the actual Ton and Toff time of the respective HS switch, e.g. the PWM setting ‘000 0001’ could not be realized. Data Sheet 128 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface PWM_FREQ_CTRL PWM Frequency Configuration Control (Address 001 1100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0x0xB 7 6 5 4 3 2 1 0 Reserved Reserved Reserved Reserved Reserved PWM2_FREQ Reserved PWM1_FREQ r r r r r rw r rw Field Bits Type Description Reserved 7:3 r Reserved, always reads as 0 PWM2_ FREQ 2 rw PWM2 Frequency Selection 0B , 200Hz configuration 1B , 400Hz configuration Reserved 1 r Reserved, always reads as 0 PWM1_ FREQ 0 rw PWM1 Frequency Selection 0B , 200Hz configuration 1B , 400Hz configuration r Note: The min. On-time during PWM is limited by the actual Ton and Toff time of the respective HS switch, e.g. the PWM setting ‘000 0001’ could not be realized. SYS_STATUS_CTRL System Status Control (Address 001 1110B) POR Value: 0000 0000B; Restart Value/Soft Reset Value: xxxx xxxxB 7 6 5 4 3 2 1 0 SYS_STAT_7 SYS_STAT_6 SYS_STAT_5 SYS_STAT_4 SYS_STAT_3 SYS_STAT_2 SYS_STAT_1 SYS_STAT_0 rw rw rw rw rw rw r rw Field Bits Type Description SYS_STAT 7:0 rw System Status Control Byte (bit0=LSB; bit7=MSB) Dedicated byte for system configuration, access only by microcontroller. Cleared after power up and Soft Reset rw Notes 1. The SYS_STATUS_CTRL register is an exception for the default values, i.e. it will keep its configured value also after a Soft Reset. 2. This byte is intended for storing system configurations of the ECU by the microcontroller and is only accessible in SBC Normal Mode. The byte is not accessible by the SBC and is also not cleared after Fail-Safe or SBC Restart Mode. It allows the microcontroller to quickly store system configuration without loosing the data. Data Sheet 129 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.6 SPI Status Information Registers READ/CLEAR Operation (see also Chapter 15.3): • One 16-bit SPI command consist of two bytes: - the 7-bit address and one additional bit for the register access mode and - following the data byte The numbering of following bit definitions refers to the data byte and correspond to the bits D0...D7 and to the SPI bits 8...15 (see also figure). • There are two different bit types: - ‘r’ = READ: read only bits (or reserved bits) - ‘rc’ = READ/CLEAR: readable and clearable bits • Reading a register is done byte wise by setting the SPI bit 7 to “0” (= Read Only) • Clearing a register is done byte wise by setting the SPI bit 7 to “1” • SPI status registers are in general not cleared or changed automatically (an exception are the WD_FAIL bits). This must be done by the microcontroller via SPI command The registers are addressed wordwise. Data Sheet 130 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.6.1 General Status Registers SUP_STAT_2 Supply Voltage Fail Status (Address 100 0000B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0x0x xxxxB 7 6 5 4 3 2 1 0 Reserved VS_UV Reserved VCC3_OC VCC3_UV VCC3_OT VCC1_OV VCC1_WARN r rc r rc rc rc rc rc r Field Bits Type Description Reserved 7 r Reserved, always reads as 0 VS_UV 6 rc VS Under-Voltage Detection (VS,UV) 0B , No VS under voltage detected 1B , VS under voltage detected Reserved 5 r Reserved, always reads as 0 VCC3_OC 4 rc VCC3 Over Current Detection 0B , No OC 1B , OC detected VCC3_UV 3 rc VCC3 Under Voltage Detection 0B , No VCC3 UV detection 1B , VCC3 UV Fail detected VCC3_OT 2 rc VCC3 Over Temperature Detection 0B , No over temperature 1B , VCC3 over temperature detected VCC1_ OV 1 rc VCC1 Over Voltage Detection (VCC1,OV,r) 0B , No VCC1 over voltage warning 1B , VCC1 over voltage detected VCC1_ WARN 0 rc VCC1 Undervoltage Prewarning (VPW,f) 0B , No VCC1 undervoltage prewarning 1B , VCC1 undervoltage prewarning detected Notes 1. The VCC1 undervoltage prewarning threshold VPW,f / VPW,r is a fixed threshold and independent of the VCC1 undervoltage reset thresholds. Data Sheet 131 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface SUP_STAT_1 Supply Voltage Fail Status (Address 100 0001B) POR / Soft Reset Value: y000 0000B; Restart Value: xxxx xx0xB 7 6 5 4 3 2 1 0 POR VSHS_UV VSHS_OV VCC2_OT VCC2_UV VCC1_SC VCC1_UV_FS VCC1_UV rc rc rc rc rc rc rc rc r Field Bits Type Description POR 7 rc Power-On Reset Detection 0B , No POR 1B , POR occurred VSHS_UV 6 rc VSHS Under-Voltage Detection (VSHS,UVD) 0B , No VSHS-UV 1B , VSHS-UV detected VSHS_OV 5 rc VSHS Over-Voltage Detection (VSHS,OVD) 0B , No VSHS-OV 1B , VSHS-OV detected VCC2_OT 4 rc VCC2 Over Temperature Detection 0B , No over temperature 1B , VCC2 over temperature detected VCC2_UV 3 rc VCC2 Under Voltage Detection (VCC2,UV,f) 0B , No VCC2 Under voltage 1B , VCC2 under voltage detected VCC1_SC 2 rc VCC1 Short to GND Detection (<Vrtx for t>4ms after switch on) 0B , No short 1B , VCC1 short to GND detected VCC1_UV _FS 1 rc VCC1 UV-Detection (due to Vrtx reset) 0B , No Fail-Safe Mode entry due to 4th consecutive VCC1_UV 1B , Fail-Safe Mode entry due to 4th consecutive VCC1_UV VCC1_UV 0 rc VCC1 UV-Detection (due to Vrtx reset) 0B , No VCC1_UV detection 1B , VCC1 UV-Fail detected Notes 1. The MSB of the POR/Soft Reset value is marked as ‘y’: the default value of the POR bit is set after Power-on reset (POR value = 1000 0000). However it will be cleared after a SBC Soft Reset command (Soft Reset value = 0000 0000). 2. During Sleep Mode, the bits VCC1_SC,VCC1_OV and VCC1_UV will not be set when VCC1 is off 3. The VCC1_UV bit is never updated in SBC Restart Mode, in SBC Init Mode it is only updated after RO was released for the first time, it is always updated in SBC Normal and Stop Mode, and it is always updated in any SBC modes in a VCC1_SC condition (after VCC1_UV = 1 for >4ms). Data Sheet 132 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface THERM_STAT Thermal Protection Status (Address 100 0010B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0xxxB 7 6 5 4 3 2 1 0 Reserved Reserved Reserved Reserved Reserved TSD2 TSD1 TPW r r r r r rc rc rc r Field Bits Type Description Reserved 7:3 r Reserved, always reads as 0 TSD2 2 rc TSD2 Thermal Shut-Down Detection 0B , No TSD2 event 1B , TSD2 OT detected - leading to SBC Fail-Safe Mode TSD1 1 rc TSD1 Thermal Shut-Down Detection 0B , No TSD1 fail 1B , TSD1 OT detected TPW 0 rc Thermal Pre Warning 0B , No Thermal Pre warning 1B , Thermal Pre warning detected Note: TSD1 and TSD2 are not reset automatically, even if the temperature pre warning or TSD1 OT condition is not present anymore. Also TSD2 is not reset. Data Sheet 133 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface DEV_STAT Device Information Status (Address 100 0011B) POR / Soft Reset Value: 0000 0000B; Restart Value: xx00 xxxxB 7 6 DEV_STAT_1 DEV_STAT_0 rc 5 4 3 2 1 0 Reserved Reserved WD_FAIL_1 WD_FAIL_0 SPI_FAIL FAILURE r r rh rh rc rc rc r Field Bits Type Description DEV_STAT 7:6 rc Device Status before Restart Mode 00B , Cleared (Register must be actively cleared) 01B , Restart due to failure (WD fail, TSD2, VCC1_UV); also after a wake from Fail-Safe Mode 10B , Sleep Mode 11B , Reserved Reserved 5:4 r Reserved, always reads as 0 WD_FAIL 3:2 rh Number of WD-Failure Events (1/2 WD failures depending on CFG) 00B , No WD Fail 01B , 1x WD Fail, FOx activation - Config 2 selected 10B , 2x WD Fail, FOx activation - Config 1 / 3 / 4 selected 11B , Reserved (never reached) SPI_FAIL 1 rc SPI Fail Information 0B , No SPI fail 1B , Invalid SPI command detected FAILURE 0 rc Activation of Fail Output FO 0B , No Failure 1B , Failure occurred Notes 1. The bits DEV_STAT show the status of the device before it went through Restart. Either the device came from regular Sleep Mode (‘10’) or a failure (‘01’ - SBC Restart or SBC Fail-Safe Mode: WD fail, TSD2 fail, VCC_UV fail or VCC1_OV if bit VCC1_OV_RST is set) occurred. Failure is also an illegal command from SBC Stop to SBC Sleep Mode or going to SBC Sleep Mode without activation of any wake source. Coming from SBC Sleep Mode (‘10’) will also be shown if there was a trial to enter SBC Sleep Mode without having cleared all wake flags before. 2. The WD_FAIL bits are configured as a counter and are the only status bits, which are cleared automatically by the SBC. They are cleared after a successful watchdog trigger and when the watchdog is stopped (also in SBC Sleep and Fail-Safe Mode unless it was reached due to a watchdog failure). See also Chapter 13.1. 3. The SPI_FAIL bit is cleared only by SPI command 4. In case of Config 2/4 the WD_Fail counter is frozen in case of WD trigger failure until a successful WD trigger. 5. If CFG = ‘0’ then a 1st watchdog failure will not trigger the FO outputs or the FAILURE bit but only force the SBC into SBC Restart Mode. Data Sheet 134 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface BUS_STAT_1 Bus Communication Status (Address 100 0100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 0xxxB 7 6 5 4 3 Reserved Reserved Reserved Reserved Reserved r r r r r 2 1 CAN_FAIL_1 CAN_FAIL_0 Field Bits Type Description Reserved 7 r Reserved, always reads as 0 rc r rc 0 VCAN_UV rc Reserved 6:5 r Reserved, always reads as 0 Reserved 4:3 r Reserved, always reads as 0 CAN_FAIL 2:1 rc CAN Failure Status 00B , No error 01B , CAN TSD 10B , CAN_TXD_DOM: TXD dominant time out for more than 4ms 11B , CAN_BUS_DOM: BUS dominant time out for more than 4ms VCAN_UV 0 rc Under Voltage CAN Bus Supply 0B , Normal operation 1B , CAN Supply under voltage detected. Transmitter disabled Notes 1. The VCAN_UV comparator is enabled if the mode bit CAN_1 = ‘1’, i.e. in CAN Normal or CAN Receive Only Mode. Data Sheet 135 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_STAT_1 Wake-up Source and Information Status (Address 100 0110B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00xx 0xxxB 7 6 5 4 3 2 1 0 Reserved Reserved CAN_WU TIMER_WU Reserved WK3_WU WK2_WU WK1_WU r r rc rc r rc rc rc Field Bits Type Description Reserved 7 r Reserved, always reads as 0 Reserved 6 r Reserved, always reads as 0 CAN_WU 5 rc Wake up via CAN Bus 0B , No Wake up 1B , Wake up TIMER_WU 4 rc Wake up via TimerX 0B , No Wake up 1B , Wake up Reserved 3 r Reserved, always reads as 0 WK3_WU 2 rc Wake up via WK3 0B , No Wake up 1B , Wake up WK2_WU 1 rc Wake up via WK2 0B , No Wake up 1B , Wake up WK1_WU 0 rc Wake up via WK1 0B , No Wake up 1B , Wake up r Note: The respective wake source bit will also be set when the device is woken from SBC Fail-Safe Mode Data Sheet 136 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_STAT_2 Wake-up Source and Information Status (Address 100 0111B) POR / Soft Reset Value: 0000 0000B; Restart Value: 00xx 0000B 7 6 5 4 3 2 1 0 Reserved Reserved GPIO2_WU GPIO1_WU Reserved Reserved Reserved Reserved r r rc rc r r r r Field Bits Type Description Reserved 7:6 r Reserved, always reads as 0 GPIO2_WU 5 rc Wake up via GPIO2 0B , No Wake up 1B , Wake up GPIO1_WU 4 rc Wake up via GPIO1 0B , No Wake up 1B , Wake up Reserved 3:0 r Reserved, always reads as 0 Data Sheet 137 r Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface WK_LVL_STAT WK Input Level (Address 100 1000B) POR / Soft Reset Value: xx00 0xxxB; Restart Value: xxxx 0xxxB 7 6 5 4 3 2 1 0 SBC_DEV _LVL CFGP GPIO2_LVL GPIO1_LVL Reserved WK3_LVL WK2_LVL WK1_LVL r r r r r r r r r Field Bits Type Description SBC_DEV _LVL 7 r Status of SBC Operating Mode at FO3/TEST Pin 0B , User Mode activated 1B , SBC Software Development Mode activated CFGP 6 r Device Configuration Status 0B , No external pull-up resistor connected on INT (Config 2/4) 1B , External pull-up resistor connected on INT (Config 1/3) GPIO2_LVL 5 r Status of GPIO2 (if selected as GPIO) 0B , Low Level (=0) 1B , High Level (=1) GPIO1_LVL 4 r Status of GPIO1 (if selected as GPIO) 0B , Low Level (=0) 1B , High Level (=1) Reserved 3 r Reserved, always reads as 0 WK3_LVL 2 r Status of WK3 0B , Low Level (=0) 1B , High Level (=1) WK2_LVL 1 r Status of WK2 0B , Low Level (=0) 1B , High Level (=1) WK1_LVL 0 r Status of WK1 0B , Low Level (=0) 1B , High Level (=1) Note: GPIOx_LVL is updated in SBC Normal and Stop Mode if configured as wake input, low-side switch or highside switch. In cyclic sense or wake mode, the registers contain the sampled level, i.e. the registers are updated after every sampling. The GPIOs are not capable of cyclic sensing. If selected as GPIO then the respective level is shown even if configured as low-side or high-side. Data Sheet 138 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface HS_OC_OT_STAT High-Side Switch Overload Status (Address 101 0100B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 xxxxB 7 6 5 4 Reserved Reserved Reserved Reserved r r r r 3 2 1 0 HS4_OC_OT HS3_OC_OT HS2_OC_OT HS1_OC_OT rc rc r rc Field Bits Type Description Reserved 7:4 r Reserved, always reads as 0 HS4_OC_OT 3 rc Over-Current & Over-Temperature Detection HS4 0B , No OC or OT 1B , OC or OT detected HS3_OC_OT 2 rc Over-Current & Over-Temperature Detection HS3 0B , No OC or OT 1B , OC or OT detected HS2_OC_OT 1 rc Over-Current & Over-Temperature Detection HS2 0B , No OC or OT 1B , OC or OT detected HS1_OC_OT 0 rc Over-Current & Over-Temperature Detection HS1 0B , No OC or OT 1B , OC or OT detected rc Note: The OC/OT bit might be set for VPOR,f < VS < 5.5V (see also Chapter 4.2) Data Sheet 139 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface HS_OL_STAT High-Side Switch Open-Load Status (Address 101 0101B) POR / Soft Reset Value: 0000 0000B; Restart Value: 0000 xxxxB 7 6 5 4 3 2 1 0 Reserved Reserved Reserved Reserved HS4_OL HS3_OL HS2_OL HS1_OL r r r r rc rc rc rc Field Bits Type Description Reserved 7:4 r Reserved, always reads as 0 HS4_OL 3 rc Open-Load Detection HS4 0B , No OL 1B , OL detected HS3_OL 2 rc Open-Load Detection HS3 0B , No OL 1B , OL detected HS2_OL 1 rc Open-Load Detection HS2 0B , No OL 1B , OL detected HS1_OL 0 rc Open-Load Detection HS1 0B , No OL 1B , OL detected Data Sheet 140 r Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.6.2 Family and Product Information Register FAM_PROD_STAT Family and Product Identification Register (Address 111 1110B) POR / Soft Reset Value: 0011 yyyy B; Restart Value: 0011 yyyyB 7 6 5 4 3 2 1 0 FAM_3 FAM_2 FAM_1 FAM_0 PROD_3 PROD_2 PROD_1 PROD_0 r r r r r r r r r Field Bits Type Description FAM 7:4 r SBC Family Identifier (bit4=LSB; bit7=MSB) 0 0 01B, Driver SBC Family 0 0 10B, DC/DC-SBC Family 0 0 11B, Mid-Range SBC Family x x x xB, reserved for future products PROD 3:0 r SBC Product Identifier (bit0=LSB; bit3=MSB) 0 0 0 0B, TLE9260QX (5V, no LIN, no VCC3, no SWK) 0 1 0 0B, TLE9261QX (5V, no LIN, VCC3, no SWK) 1 0 0 0B, TLE9262QX (5V, 1 LIN, VCC3, no SWK) 1 1 0 0B, TLE9263QX (5V, 2 LIN, VCC3, no SWK) Notes 1. The actual default register value after POR, Soft Reset or Restart of PROD will depend on the respective product. Therefore the value ‘y’ is specified. 2. SWK = Selective Wake feature in CAN Partial Networking standard Data Sheet 141 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface 15.7 Electrical Characteristics Table 27 Electrical Characteristics VS = 5.5 V to 28 V, Tj = -40 °C to +150 °C, all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. – – 4.0 MHz 1) P_16.7.1 V – P_16.7.2 SPI frequency Maximum SPI frequency fSPI,max SPI Interface; Logic Inputs SDI, CLK and CSN H-input Voltage Threshold VIH – – 0.7* L-input Voltage Threshold VIL 0.3* – – V – P_16.7.3 VIHY – 0.12* – V 1) P_16.7.4 P_16.7.5 Hysteresis of input Voltage Pull-up Resistance at pin CSN RICSN VCC1 VCC1 VCC1 20 40 80 kΩ 20 40 80 kΩ VCSN = 0.7 x VCC1 VSDI/CLK = 0.2 x VCC1 – 10 – pF 1) P_16.7.7 VCC1 - VCC1 - – V IDOH = -1.6 mA P_16.7.8 0.4 0.2 – 0.2 0.4 V -10 – 10 µA IDOL = 1.6 mA VCSN = VCC1; 0 V < VDO < VCC1 P_16.7.9 Tristate Leakage Current VSDOL ISDOLK P_16.7.10 Tristate Input Capacitance CSDO – 10 15 pF 1) P_16.7.11 tpCLK tCLKH tCLKL tbef tlead tlag tbeh tDISU tDIHO trIN 250 – – ns – P_16.7.12 125 – – ns – P_16.7.13 125 – – ns – P_16.7.14 125 – – ns – P_16.7.15 250 – – ns – P_16.7.16 250 – – ns – P_16.7.17 125 – – ns – P_16.7.18 100 – – ns – P_16.7.19 50 – – ns – P_16.7.20 – – 50 ns – P_16.7.21 Input Signal Fall Time at pin SDI, CLK and CSN tfIN – – 50 ns – P_16.7.22 Delay Time for Mode Changes2) tDel,Mode – – 6 µs includes internal P_16.7.23 oscillator tolerance Pull-down Resistance at pin SDI and CLK RICLK/SDI Input Capacitance at pin CSN, CI SDI or CLK P_16.7.6 Logic Output SDO H-output Voltage Level L-output Voltage Level VSDOH 1) Data Input Timing Clock Period Clock High Time Clock Low Time Clock Low before CSN Low CSN Setup Time CLK Setup Time Clock Low after CSN High SDI Set-up Time SDI Hold Time Input Signal Rise Time at pin SDI, CLK and CSN Data Sheet 142 Rev. 1.1, 2014-09-26 TLE9261QX Serial Peripheral Interface Table 27 Electrical Characteristics (cont’d) VS = 5.5 V to 28 V, Tj = -40 °C to +150 °C, all voltages with respect to ground, positive current flowing into pin (unless otherwise specified) Parameter Symbol CSN High Time Values Unit Note / Test Condition Number Min. Typ. Max. tCSN(high) 3 – – µs – P_16.7.24 trSDO tfSDO tENSDO tDISSDO tVASDO – 30 80 ns P_16.7.25 – 30 80 ns CL = 100 pF CL = 100 pF – – 50 ns low impedance P_16.7.27 – – 50 ns high impedance P_16.7.28 – – 50 ns CL = 100 pF P_16.7.29 1) Data Output Timing SDO Rise Time SDO Fall Time SDO Enable Time SDO Disable Time SDO Valid Time P_16.7.26 1) Not subject to production test; specified by design 2) Applies to all mode changes triggered via SPI commands 24 CSN 15 16 13 17 14 18 CLK 19 SDI not defined 27 SDO Figure 53 20 LSB MSB 28 29 Flag LSB MSB SPI Timing Diagram Note: Numbers in drawing correlate to the last 2 digits of the Number field in the Electrical Characteristics table. Data Sheet 143 Rev. 1.1, 2014-09-26 TLE9261QX Application Information 16 Application Information 16.1 Application Diagram Note: The following information is given as a hint for the implementation of the device only and shall not be regarded as a description or warranty of a certain functionality, condition or quality of the device. VBAT VBAT VS D1 C1 D2 T2 R12 V CC3 C 13 C2 IC1Q1 Q1 VCC C3 C14 R8 VS VCC3SH VSHS VS VSHS D3 VCC3REF VCC3B HS1 Q2 VCC1 VCC1 VCC2 VS C5 C4 C6 R9 VSHS C 17 CSN R7 CSN CLK SDI SDO CLK SDI SDO HS2 VSHS C8 Q2 V CC2 C7 D4 GND C 18 VDD µC HS3 Other loads , e.g. sensor , opamp, ... LOGIC State Machine VSHS TxD CAN RxD CAN INT TxD CAN RxD CAN INT RO Reset HS4 R5 R3 S3 R6 C9 Hall1 Q2 Hall2 V SS TLE9261 R4 VBAT S2 WK1 Q1 WK2 C 10 S1 VCC2 R1 C 11 R2 WK3 VCAN CANH CANH R10 CAN cell C 12 R11 CANL CANL VS FOx GND T1 LH Note: The external capacitance on FO3/TEST must be <=10nF in oder to ensure proper detection of SBC Development Mode und SBC user mode operation Application _information _TLE9261 .vsd Figure 54 Data Sheet Simplified Application Diagram 144 Rev. 1.1, 2014-09-26 TLE9261QX Application Information Note: Unused outputs are recommended to be left unconnected on the application board. If unused output pins are routed to an external connector which leaves the ECU, then these pins should have provision for a zero ohm jumper (depopulated if unused) or ESD protection. Table 28 Ref. Bill of Material for Simplified Application Diagram Typical Value Purpose / Comment Capacitances C1 68µF Buffering capacitor to cut off battery spikes, depending on application C2 100nF EMC, blocking capacitor C3 22µF Buffering capacitor to cut off battery spikes from VSHS as separate supply input; Depending on application, only needed if VSHS is not connected to VS; C4 2.2µF low ESR As required by application, min. 470nF for stability C5 100nF ceramic Spike filtering, improve stability of supply for microcontroller; not needed for SBC C6 2.2µF low ESR Blocking capacitor, min. 470nF for stability; if used for CAN supply place a 100nF ceramic capacitor in addition very close to VCAN pin for optimum EMC behavior C7 33nF As required by application, mandatory protection for off-board connections C8 33nF As required by application, mandatory protection for off-board connections C17 47pF Only required in case of off-board connection to optimize EMC behavior, place close to pin C18 47pF Only required in case of off-board connection to optimize EMC behavior, place close to pin C9 10nF Spike filtering, as required by application, mandatory protection for off-board connections (see also Simplified Application Diagram with the Alternate Measurement Function) C10 10nF Spike filtering, as required by application, mandatory protection for off-board connections C11 10nF Spike filtering, as required by application, mandatory protection for off-board connections C12 4.7nF / OEM dependent Split termination stability C13 10µF low ESR Stability of VCC3, e.g. Murata 10 µF/10 V GCM31CR71A106K64L C14 47nF Only required in case of off-board connection to optimize EMC behavior, place close to connector Resistances R1 10kΩ Wetting current of the switch, as required by application R2 10kΩ Limit the WK pin current, e.g. for ISO pulses R3 10kΩ Wetting current of the switch, as required by application R4 10kΩ Limit the WK pin current, e.g. for ISO pulses R5 10kΩ Wetting current of the switch, as required by application R6 10kΩ Limit the WK pin current, e.g. for ISO pulses R7 depending on LED config. LED current limitation, as required by application R8 depending on LED config. LED current limitation, as required by application Data Sheet 145 Rev. 1.1, 2014-09-26 TLE9261QX Application Information Table 28 Bill of Material for Simplified Application Diagram (cont’d) Ref. Typical Value Purpose / Comment R9 47kΩ Selection of hardware configuration 1/3, i.e. in case of WD failure SBC Restart Mode is entered. If not connected, then hardware configuration 2/4 is selected R10 60Ω / OEM dependent CAN bus termination R11 60Ω / OEM dependent CAN bus termination R12 Sense shunt for ICC3 current limitation (configured to typ. 235mA with 1Ω 1Ω shunt, depending on required current limitation shunt) for stand-alone configuration; Setting of load sharing ratio (here ICC3/ICC1 = 1) in load sharing or load sharing ratio configuration. R15 10kΩ WK1 pin current limitation, e.g. for ISO pulses, for alternate measurement function (see also Simplified Application Diagram with the Alternate Measurement Function) R16 depending on application and microcontroller Voltage Divider resistor to adjust measurement voltage to microcontroller ADC input range (see also Simplified Application Diagram with the Alternate Measurement Function) R17 depending on application and microcontroller Voltage Divider resistor to adjust measurement voltage to microcontroller ADC input range (see also Simplified Application Diagram with the Alternate Measurement Function) Active Components D1 e.g. BAS 3010A, Infineon Reverse polarity protection for VS supply pins D2 e.g. BAS 3010A, Infineon Reverse polarity protection for VSHS supply pin; if separate supplies are not needed, then connect VSHS to VS pins D3 LED As required by application, configure series resistor accordingly D4 LED As required by application, configure series resistor accordingly T1 e.g. BCR191W High active FO control T2 BCP 52-16, Infineon Power element of VCC3, current limit or load sharing ratio to be configured via shunt MJD 253, ON Semi µC e.g. TC2xxx Alternative power element of VCC3 Microcontroller Note: This is a simplified example of an application circuit. The function must be verified in the real application. Data Sheet 146 Rev. 1.1, 2014-09-26 TLE9261QX Application Information VBAT D2 VS D1 VBAT C2 C1 e.g. 470uF VS VCC1 VCC1 C5 C4 VS CSN CSN VDD CLK SDI SDO CLK SDI SDO LOGIC State Machine µC TxD CAN RxD CAN TxD CAN RxD CAN INT max. 500uA ISO Pulse protection Vbat_uC R 17 Figure 55 C9 ≥10n TLE9261 R6 WK1 INT RO Reset Vbat_uC ADC_x VSS ≥10k S1 WK2 Note: Max. WK1 input current limited to 500µA to ensure accuracy and proper operation ; R 16 GND Simplified Application Diagram with the Alternate Measurement Function via WK1 and WK2 Note: This is a very simplified example of an application circuit. The function must be verified in the real application.WK1 must be connected to signal to be measured and WK2 is the output to the microcontroller supervision function. The maximum current into WK1 must be <500uA. The minimum current into WK1 should be >5uA to ensure proper operation. Data Sheet 147 Rev. 1.1, 2014-09-26 TLE9261QX Application Information 16.2 ESD Tests Note: Tests for ESD robustness according to IEC61000-4-2 “gun test” (150pF, 330Ω) will been performed. The results and test condition will be available in a test report. The target values for the test are listed in Table 29 below. Table 29 ESD “Gun Test” Performed Test Result Unit Remarks ESD at pin CANH, CANL, VS, WK1..3, HSx, VCC2, VCC3 versus GND >6 kV 1)2) positive pulse 1)2) ESD at pin CANH, CANL, < -6 kV negative pulse VS, WK1..3, HSx, VCC2, VCC3 versus GND 1)ESD Test “Gun Test” is specified with external components for pins VS, WK1..3, HSx, VCC3 and VCC2. See the application diagram in Chapter 16.1 for more information. 2) ESD susceptibility “ESD GUN” according LIN EMC 1.3 Test Specification, Section 4.3 (IEC 61000-4-2). Tested by external test house (IBEE Zwickau, EMC Test report Nr. 07-10-13) EMC and ESD susceptibility tests according to SAE J2962-2 (2010) have been performed. Tested by external test house (UL LLC, Test report Nr. 2013-474A) Data Sheet 148 Rev. 1.1, 2014-09-26 TLE9261QX Application Information 16.3 Thermal Behavior of Package Below figure shows the thermal resistance (Rth_JA) of the device vs. the cooling area on the bottom of the PCB for Ta = 85°C. Every line reflects a different PCB and thermal via design. Figure 56 Data Sheet Thermal Resistance (Rth_JA) vs. Cooling Area 149 Rev. 1.1, 2014-09-26 TLE9261QX Application Information Cross Section (JEDEC 2s2p) with Cooling Area Cross Section (JEDEC 1s0p) with Cooling Area 1,5 mm 1,5 mm 70µm modelled (traces) 35µm, 90% metalization* 35µm, 90% metalization* 70µm / 5% metalization + cooling area *: means percentual Cu metalization on each layer PCB (top view) Figure 57 PCB (bottom view) Detail SolderArea Board Setup Board setup is defined according to JESD 51-2,-5,-7. Board: 76.2x114.3x1.5mm³ with 2 inner copper layers (35µm thick), with thermal via array under the exposed pad contacting the first inner copper layer and 300mm2 cooling area on the bottom layer (70µm). Data Sheet 150 Rev. 1.1, 2014-09-26 TLE9261QX Package Outlines Package Outlines 6.8 11 x 0.5 = 5.5 0.5 0.1±0.03 +0.03 1) 0.1 ±0.05 B 0.4 x 45° Index Marking 0.15 ±0.05 48 13 5) 0.05 MAX. 1) Vertical burr 0.03 max., all sides 2) This four metal areas have exposed diepad potential Figure 58 1 12 (0.2) 2) 37 .3 C 24 (0 SEATING PLANE 7 ±0.1 6.8 48x 0.08 36 25 0.5 ±0.07 A (6) 7 ±0.1 0.9 MAX. (0.65) (5.2) 17 0.23 ±0.05 (5.2) Index Marking 48x 0.1 M A B C (6) PG-VQFN-48-29, -31-PO V03 PG-VQFN-48-31 Note: For assembly recommendations please also refer to the documents "Recommendations for Board Assembly (VQFN and IQFN)" and "VQFN48 Layout Hints" on the Infineon website (www.infineon.com). The PG-VQFN-48-31 package is a leadless exposed pad power package featuring Lead Tip Inspection (LTI) to support Automatic Optical Inspection (AOI). Green Product (RoHS compliant) To meet the world-wide customer requirements for environmentally friendly products and to be compliant with government regulations the device is available as a green product. Green products are RoHS-Compliant (i.e Pb-free finish on leads and suitable for Pb-free soldering according to IPC/JEDEC J-STD-020). For further information on alternative packages, please visit our website: http://www.infineon.com/packages. Data Sheet 151 Dimensions in mm Rev. 1.1, 2014-09-26 TLE9261QX Revision History 18 Revision History Table 30 Revision History Revision Date Changes Rev 1.1 2014-09-26 Initial Release Data Sheet 152 Rev. 1.1, 2014-09-26 Edition 2014-09-26 Published by Infineon Technologies AG 81726 Munich, Germany © 2014 Infineon Technologies AG All Rights Reserved. Legal Disclaimer The information given in this document shall in no event be regarded as a guarantee of conditions or characteristics. With respect to any examples or hints given herein, any typical values stated herein and/or any information regarding the application of the device, Infineon Technologies hereby disclaims any and all warranties and liabilities of any kind, including without limitation, warranties of non-infringement of intellectual property rights of any third party. Information For further information on technology, delivery terms and conditions and prices, please contact the nearest Infineon Technologies Office (www.infineon.com). Warnings Due to technical requirements, components may contain dangerous substances. For information on the types in question, please contact the nearest Infineon Technologies Office. Infineon Technologies components may be used in life-support devices or systems only with the express written approval of Infineon Technologies, if a failure of such components can reasonably be expected to cause the failure of that life-support device or system or to affect the safety or effectiveness of that device or system. Life support devices or systems are intended to be implanted in the human body or to support and/or maintain and sustain and/or protect human life. If they fail, it is reasonable to assume that the health of the user or other persons may be endangered.