AMIS-39101 Octal High Side Driver with Protection General Description The AMIS−39101 is a robust high side driver IC featuring eight independent high current output drive channels along with a number of integrated fault−protection circuits. This highly integrated product is designed for controlled delivery of power to a large variety of loads in industrial applications including motors, relays and LED arrays, among others. With all driver output channels in the conducting state, each channel can source up to 350 mA of continuous current (resistive load). In cases where all output drivers are not active, higher output current per channel can be achieved provided that the thermal limits of the device are not exceeded. Furthermore, in order to minimize system cost each output driver has built−in fly−back diodes. The device withstands short−circuits to ground and supply, respectively. It is designed with an array of integrated protection features including over−temperature and over−current detection and shut down. The integrated charge pump requires only one external capacitor and provides for operation of the critical fault−protection circuitry even in case of low supply voltages. The device can be interfaced to a variety of microcontrollers via the serial interface link, in turn allowing for monitoring and controlling the state of each of the output drivers individually. In this case, at the onset of a potential hazardous situation the drivers are switched off and the diagnostic state of the drivers can be extracted via the serial interface. The device also features a power down mode for reduced power consumption and has high built−in electrostatic discharge (ESD) protection capability for robust operation. Key Features • • • • • • • • • • • • • Eight High Side Output Drivers Up to 830 mA Continuous Current per Driver Pair (Resistive Load) Charge Pump with One External Capacitor Serial Interface Short−circuit Protection Diagnostic Features Power−down Mode Internal Thermal Shutdown 3.3 V and 5 V Microcontroller Compliant Excellent System ESD Automotive Compliant SO28 Package with Low RqJA This is a Pb−Free Device* http://onsemi.com 1 SOIC 28 PN SUFFIX CASE 751AR ORDERING INFORMATION See detailed ordering and shipping information in the package dimensions section on page 2 of this data sheet. *For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. Typical Applications • • • • • Actuator Control LED Drivers Relays and Solenoids Industrial Process Control Automotive Load Management © Semiconductor Components Industries, LLC, 2008 December, 2008 − Rev. 2 1 Publication Order Number: AMIS−39101/D AMIS−39101 ORDERING INFORMATION Product Name Package Shipping Configuration Temperature Range AMIS39101PNPB4G PSOP 300-28 (JEDEC MS-013) Tube/Tray −40°C to 85°C AMIS39101PNPB4RG PSOP 300-28 (JEDEC MS-013) Tape & Reel −40°C to 85°C NOTE: For additional information on our Pb−Free strategy and soldering details, please download the ON Semiconductor Soldering and Mounting Techniques Reference Manual, SOLDERRM/D. VDDN 27 5 Power on Reset 4 OUT1 Thermal shutdown 6 OUT2 10 DIN DOUT CLK WR 12 13 2 9 OUT3 Serial interface VS1 OUT1 OUT2 VS2 OUT3 3 11 OUT4 LOGIC Control Diagnostic 19 18 OUT5 OUT4 VS3 OUT5 Oscillator 20 OUT6 CAPA1 17 24 Charge− pump 23 OUT7 Bandgap 25 OUT8 OUT6 VS4 OUT7 OUT8 AMIS−39101 26 1 14 7 16 8 15 21 22 28 PDB TEST1 TEST2 TEST GND1 GND2 GND3 GND4 GND5 GND6 Figure 1. Block Diagram http://onsemi.com 2 AMIS−39101 CVS CVCC 5V−reg CVDDN VDDN VCC 27 DIN DOUT Micro− controller CLK WR PDB CCP CAPA VS 17 VS1..4 5 12 10 19 24 4 13 2 AMIS−39101 3 26 1 14 16 OUT1 Cout1 6 9 11 18 20 23 25 28 22 21 15 8 7 Lload1 OUT8 Lload8 Cout8 GND TEST1..2 Rload1 Rload8 GND1..6 Figure 2. Typical Application Diagram External Components It is important to properly decouple the power supplies of the chip with external capacitors that have good high frequency properties. The VS1, VS2, VS3, and VS4 pins are shorted on the PCB level. Also GND1, GND2, GND3, GND4, GND5, GND6, TEST, TEST1, and TEST2 are shorted on the PCB level. Table 1. EXTERNAL COMPONENTS Component CVS Function Min. Decoupling capacitor; X7R 100 0.47 Value Max. Tol. [%] Units ±20 nF Ccharge_pump Charge pump capacitor (Note 1) Cout (Note 2) EMC connector on connector 1 Cout (Note 2) Decoupling capacitors; 50 V 22 ±20 nF CVDD Decoupling capacitors; 50 V 22 ±20 nF RLoad Load resistance 65 ±10 W LLoad Load inductance at maximum current 300 1. The capacitor must be placed close to the AMIS−39101 pins on the PCB. 2. Both capacitors are optional and depend on the final application and board layout. http://onsemi.com 3 47 nF nF 350 mH GND3 TEST2 CAPA1 DIN TEST OUT5 OUT4 DOUT VS3 VS2 OUT6 GND4 GND5 OUT7 VS4 OUT8 PDB VDDN GND6 AMIS−39101 OUT3 GND2 GND1 OUT2 VS1 OUT1 WR CLK TEST1 AMIS−39101 Figure 3. Pin Description of the AMIS−39101 Table 2. PIN OUT Pin Name Description 1 TEST1 2 CLK Schmitt trigger serial interface CLK input 3 WR Schmitt trigger serial interface write enable input 4 OUT1 HS driver output 5 VS1 VS power supply 6 OUT2 HS driver output 7 GND1 Power ground and thermal dissipation path junction−to−PCB 8 GND2 Power ground and thermal dissipation path junction−to−PCB 9 OUT3 S driver output 10 VS2 VS power supply HS driver output Connect to GND 11 OUT4 12 DIN 13 DOUT Digital three state output for serial interface 14 TEST2 Connect to GND 15 GND3 Power ground and thermal dissipation path junction−to−PCB 16 TEST Connect to GND 17 CAPA1 Charge pump capacitor pin 18 OUT5 HS driver output 19 VS3 VS power supply 20 OUT6 HS driver output 21 GND4 Power ground and thermal dissipation path junction−to−PCB 22 GND5 Power ground and thermal dissipation path junction−to−PCB 23 OUT7 HS driver output 24 VS4 VS power supply 25 OUT8 HS driver output 26 PDB 27 VDDN Digital supply 28 GND6 Power ground and thermal dissipation path junction−to−PCB Serial interface input pin (Schmitt trigger or CMOS inverter) Schmitt trigger power−down input http://onsemi.com 4 AMIS−39101 ELECTRICAL AND ENVIRONMENTAL RATINGS Table 3. ABSOLUTE MAXIMUM RATINGS Symbol VDDN VS Description Min. Max. Unit Power supply voltage GND − 0.3 6 V VS power supply on pins VS1 to VS4, load dump, Pulse 5b 400 ms GND − 0.3 35 V Iout_ON Maximum output current OUTx pins (Note 3) The HS driver is switched on −3000 350 mA Iout_OFF Maximum output current OUTx pins (Note 3) The HS driver is switched off −350 350 mA Maximum output current VS1, 2, 3, 4 pins −700 3750 mA 0 VS+16.5 V −0.3 VDDN+0.3 V −4 −2 +4 +2 kV kV I_OUT_VS Vcapa1 DC voltage on pin CAPA1 Vdig_in Voltage on digital inputs CLK, PDB, WR, DIN VESD Pins that connect the application (pins VS1..4 and Out1..8) (Note 4) All other pins (Note 4) VESD ESD according charged device model (Note 5) −750 +750 V Junction temperature (T<100 hours) −40 175 °C Ambient temperature under bias −40 85 °C Tj Tmr Stresses exceeding Maximum Ratings may damage the device. Maximum Ratings are stress ratings only. Functional operation above the Recommended Operating Conditions is not implied. Extended exposure to stresses above the Recommended Operating Conditions may affect device reliability. 3. The power dissipation of the chip must be limited not to exceed the maximum junction temperature Tj. 4. According to HBM standard MIL−STD−883 method 3015.7. 5. According to norm EOS/ESD−STM5.3.1−1999 robotic mode. Thermal Characteristics Table 4. THERMAL CHARACTERISTICS OF THE PACKAGE Symbol Rth(vj−a) Description Thermal resistance from junction to ambient in power−SO28 package Conditions Value Unit In free air 145 K/W Table 5. THERMAL CHARACTERISTICS OF THE AMIS−39101 ON A PCB PCB Design Conductivity − Top and Bottom Layer Rthja (Note 6) Unit Two layer (35 mm) Copper planes according to Figure 4 + 25% copper for the remaining areas 24 K/W Two layer (35 mm) Copper planes according to Figure 4 + 0% copper for the remaining areas 53 K/W Four layer JEDEC: EIA/JESD51−7 25% copper coverage 25 K/W One layer JEDEC: EIA/JESD51−3 25% copper coverage 46 K/W 6. These values are informative only. http://onsemi.com 5 AMIS−39101 7.5 17.9 Top PCB view 5 mm 5 mm 5 mm 114.3 5 mm GND copper 76.2 Bottom PCB view 114.3 Ground plane GND copper 25 % filled by GND copper 76.2 Figure 4. Layout Recommendation for Thermal Characteristics http://onsemi.com 6 AMIS−39101 Electrical Parameters Operation outside the operating ranges for extended periods may affect device reliability. Total cumulative dwell time above the maximum operating rating for the power supply or temperature must be less than 100 hours. The parameters below are independent from load type. (see Load Specific Parameters section) Table 6. OPERATING RANGES Symbol Description Min. Max. Unit VDDN Digital power supply voltage 3.1 5.5 V Vdig_in Voltage on digital inputs CLK, PDB, WR, DIN −0.3 VDDN V VS power supply on Pins VS1 to VS4 3.5 28 V Ambient temperature −40 85 °C Min. Max. Unit VS (1) Tamb 7. The power dissipation of the chip must be limited not to exceed maximum junction temperature Tj of 130°C. Table 7. ELECTRICAL CHARACTERISTICS Symbol Description I_VS_norm (Note 8) Consumption on VS without load currents In normal mode of operation PDB = high 3.5 mA I_PDB_3.3 (Notes 8 and 9) Sum of VS and VDDN consumption in power−down mode of operation PDB = low, VDDN 3.3 V, VS = 24 V, 23°C ambient CLK and WR are at VDDN voltage 25 mA I_PDB_5 (Notes 8 and 9) Sum of VS and VDDN consumption in power−down mode of operation PDB = low, VDDN 5 V, VS = 24 V, 23°C ambient CLK and WR are at VDDN voltage 40 mA VS consumption in power−down mode of operation PDB = low, VS = 28 V 10 mA Consumption on VDDN, In normal mode of operation PDB = high CLK is 500 kHz, VDDN = 5.5 V, VS = 28 V 1.6 mA I_PDB_MAX_VS I_VDDN_norm (Note 8) R_on_1..8 On resistance of the output drivers 1 through 8 t VS = 24 V (nominal VS power supply condition) t VS = 4.6 V (worst case VS power supply condition) 1 3 I_OUT_lim_x (Note 8) Internal over−current limitation of HS driver outputs 0.65 T_shortGND_HSdoff The time from short of HS driver OUTx pin to GND and the driver deactivation; driver is Off Detection works from VS minimum of 7 V, VDDN minimum is 3 V 5,4 TSD_H (Note 8) High TSD threshold for junction temperature (temperature rising) 130 170 °C 9 18 °C TSD_HYST TSD hysteresis for junction temperature 8. The power dissipation of the chip must be limited not to exceed maximum junction temperature Tj. 9. The cumulative operation time mentioned above may cause permanent device failure. http://onsemi.com 7 2 W A ms AMIS−39101 Load Specific Parameters High side driver parameters for specific loads are specified in following categories: 1. Parameters for inductive loads up to 350 mH and Tambient up to 85°C 2. Parameters for inductive loads up to 300 mH and Tambient up to 85°C 3. Parameters for resistive loads and Tambient up to 85°C Table 8. LOAD SPECIFIC CHARACTERISTICS Symbol Description Min. Max. Unit 240 mA 275 mA A. Inductive Load up to 350 mH and Tambiant up to 855C I_OUT_ON_max. Maximum output per HS driver, all eight drivers might be active simultaneously B. Inductive Load up to 300 mH and Tambiant up to 855C I_OUT_ON_max. Maximum output per HS driver, all eight drivers might be active simultaneously I_OUT_ON_max. Maximum output per HS driver, all eight drivers might be active simultaneously 350 mA Maximum output per one HS driver, only one can be active 650 mA Maximum output per HS driver, only two HS drivers from a different pair can be active simultaneously 500 mA Maximum output per one HS driver pair 830 mA C. Resistive Load and Tambiant up to 855C NOTE: The parameters above are not tested in production but are guaranteed by design. The overall current capability limitations need to be respected at all times. The maximum current specified in Table 8 cannot always be obtained. The practically obtainable maximum drive current heavily depends on the thermal design of the application PCB (see Thermal Characteristics section). The available power in the package is: (TSD_H − T_ambient) / Rthja With TSD_H = 130°C and Rthja according to Table 5. result in the diagnostic register which is then latched in the output register at the rising edge of the WR−pin. Each driver has its corresponding diagnostic bit DIAG_x. By comparing the actual output status (DIAG_x) with the requested driver status (CMD_x) you can diagnose the correct operation of the application according to Table 9. Charge Pump In case of TSD activation, all bits DIAG1 to DIAG8 in the serial interface output register are set into the fault state and all drivers will be switched off (see Table 9). The TSD error condition is active until it is reset by the next correct communication on serial interface (i.e. number of clock pulses during WR = 0 is divisible by 8), provided that the device has cooled down under the TSD trip point. Thermal Shutdown (TSD) Diagnostic The high side drivers use floating NDMOS transistors as power devices. To provide the gate voltages for the NDMOS of the high side drivers, a charge pump is integrated. The storage capacitor is an external one. The charge pump oscillator has typical frequency of 4 MHz. DIAGNOSTICS Short Circuit Diagnostics The diagnostic circuit in the AMIS−39101 monitors the actual output status at the pins of the device and stores the Table 9. OUT DIAGNOSTICS Requested Driver Status CMD_x Actual Output Status DIAG_x Diagnosis On 1 High 1 Normal state On 1 Low 0 Short to ground or TSD (Note 11) Off 0 High 1 Short to VS or missing load (Note 10) or TSD (Note 11) Off 0 Low 0 Normal state (Note 10) 10. The correct diagnostic information is available after T_diagnostic_OFF time. 11. All 8 diagnostic bits DIAG_x must be in the fault condition to conclude a TSD diagnostic. Ground Loss Due to its design, the AMIS−39101 is protected for withstanding module ground loss and driver output shorted to ground at the same time. http://onsemi.com 8 AMIS−39101 Table 10. POWER LOSS VDDN VS Possible Case Action 0 0 System stopped 0 1 Start case or sleeping mode with missing VDDN 1 0 Missing VS supply VDDN normally present 1 1 System functional Nothing Eight switches in the off−state Power down consumption on VS Eight switches in the off−state Normal consumption on VDDN Nominal functionality Serial Interface The serial interface is used to allow an external microcontroller (MCU) to communicate with the device. The AMIS−39101 always acts as a slave and it can’t initiate any transmission. Serial Interface Transfer Format and Pin Signals Communication starts with a falling edge on the WR−pin which latches the status of the diagnostic register into the serial interface output register. Subsequently, the CMD_x bits – representing the newly requested driver status – are shifted into the input register and simultaneously, the DIAG_x bits – representing the actual output status – are shifted out. The bits are shifted with x = 1 first and ending with x = 8. At the rising edge of the WR−pin, the data in the input register is latched into the command register and all drivers are simultaneously switching to the newly requested status. Serial interface communication is ended. In case the serial interface master does only support 16−bit communication, then the master must first send 8 clock pulses with dummy DIN data and ignoring the DOUT data. For the next 8 clock pulses the above description can be applied. The required timing for serial to peripheral interface is shown in Table 11. The serial interface block diagram and timing characteristics are shown in Figures 6 and 7. During a serial interface transfer, data is simultaneously sent to and received from the device. A serial clock line (CLK) synchronizes shifting and sampling of the information on the two serial data lines (DIN and DOUT). DOUT signal is the output from the AMIS−39101 to the external MCU and DIN signal is the input from the MCU to the AMIS−39101. The WR−pin selects the AMIS−39101 for communication and can also be used as a chip select (CS) in a multiple−slave system. The WR−pin is active low. If AMIS−39101 is not selected, DOUT is in high impedance state and it does not interfere with serial interface bus activities. Since AMIS−39101 always shifts data out on the rising edge and samples the input data also on the rising edge of the CLK signal, the MCU serial interface port must be configured to match this operation. Serial interface clock idles high between the transferred bytes. The diagram in Figure 7 represents the serial interface timing diagram for 8−bit communication. Table 11. DIGITAL CHARACTERISTICS Symbol T_CLK T_DATA_ready T_CLK_first Description Min. Maximum applied clock frequency on CLK input Time between falling edge on WR and first bit of data ready on DOUT output (driver going from HZ state to output of first diagnostic bit) Max. Unit 500 kHz 2 ms First clock edge from falling edge on WR 3 ms T_setup (Note 12) Setup time on DIN 20 ns T_hold (Note 12) Hold time on DIN 20 ns T_DATA_next Time between rising edge on CLK and next bit ready on DOUT (capa on DOUT is 30 pF max.) T_serial interface_END Time between last CLK edge and WR rising edge 1 Rise and fall time of all applied signals (maximum loading capacitance is 30 pF) 5 T_risefall T_WR Time between two rising edge on WR (repetition of the same command) 12. Guaranteed by design http://onsemi.com 9 100 300 ns ms 20 ns ms AMIS−39101 Normal mode verification: • The command is the set of eight bits loaded via serial interface, which drives the eight HS drivers on or off. • The command is activated with rising edge on WR pin. Table 12. DIGITAL CHARACTERISTICS Symbol Description T_command_L_max. (Note 13) Min. Max. Unit Minimum time between two opposite commands for inductive loads and maximum HS driver current of 275 mA 1 s T_command_R (Note 13) Minimum time between two opposite commands for resistive loads and maximum HS driver current of 350 mA 2 ms T_PDB_recov The time between the rising edge on the PDB input and 90 percent of VS−1V on all HS driver outputs. (all drivers are activated, pure resistive load 35 mA on all outputs) 1 ms 13. Guaranteed by design PD 50% t_PD_recov VOUTi 90% {VBi − 1 V} t Figure 5. Timing for Power−down Recovery DOUT DIN Input Register Output Register CMD8 CMD7 CMD6 CMD5 CMD4 CMD3 CMD2 CMD1 DIAG8 DIAG7 DIAG6 DIAG5 DIAG4 DIAG3 DIAG2 DIAG1 Diagnostic Register Command Register CMD8 CMD7 CMD6 CMD5 CMD4 CMD3 CMD2 CMD1 DIAG8 DIAG7 DIAG6 DIAG5 DIAG4 DIAG3 DIAG2 DIAG1 DOUT HS driver OUT1 HS driver Figure 6. Serial interface Block Diagram http://onsemi.com 10 OUT8 AMIS−39101 WR Data transfer from Input Register to Command Register at rising edge WR Data transfer from Diagnostic Register to Output Register at falling edge WR CLK 1 2 3 4 5 6 7 CMD2 CMD3 CMD4 CMD5 CMD6 8 DIN CMD1 CMD7 CMD8 DOUT HiZ DIAG1 DIAG2 DIAG3 DIAG4 DIAG5 DIAG6 DIAG7 DIAG8 X HiZ OUT OUT 1 TO 8 Figure 7. Timing Diagram Quality and Reliability All products are tested using a production test program. Lot conformance to specification in volume production is guaranteed by means of following quality conformance tests: A quality system with certification against TS16949 is maintained. An AEC−Q100 compatible product qualification is performed. Monitoring of production is performed according to the dedicated AMIS specifications for assembly and wafer fabrication. Table 13. QUALIFICATION QC Test AQL Level Inspection Level To product data sheet 0.04 II External visual (mechanical) Physical damage to body or leads (e.g. bent leads) Dimensions affecting PCB manufacturability (e.g. coplanarity) 0.15 II External visual (cosmetic) Correctness of marking All other cosmetic defects 0.65 II Electrical functional and parametric NOTE: Conditions Each production lot will be accompanied with a Certificate of Conformance. Company or Product Inquiries For more information about ON Semiconductor’s products or services visit our Web site at http://www.onsemi.com. http://onsemi.com 11 AMIS−39101 PACKAGE DIMENSIONS SOIC 28 W CASE 751AR−01 ISSUE O ON Semiconductor and are registered trademarks of Semiconductor Components Industries, LLC (SCILLC). SCILLC reserves the right to make changes without further notice to any products herein. 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