TLE7250V High Speed CAN-Transceiver TLE7250VLE TLE7250VSJ Data Sheet Rev. 1.0, 2015-08-12 Automotive Power TLE7250VLE TLE7250VSJ Table of Contents Table of Contents . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2 1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 2 Block Diagram . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5 3 3.1 3.2 Pin Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Pin Assignment . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 Pin Definitions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6 4 4.1 4.2 4.2.1 4.2.2 4.3 4.3.1 4.3.2 4.3.3 4.3.4 4.3.5 4.3.6 Functional Description . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 High Speed CAN Physical Layer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 Modes of Operation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Normal-operating Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Power-save Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10 Power-up and Undervoltage Condition . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11 Power-down State . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Forced Power-save Mode . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Power-up . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 12 Undervoltage on the Digital Supply VIO . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13 Undervoltage on the Transmitter Supply VCC . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 Voltage Adaption to the Microcontroller Supply . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 14 5 5.1 5.2 5.3 5.4 5.5 Fail Safe Functions . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Short Circuit Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Unconnected Logic Pins . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . TxD Time-out Function . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Overtemperature Protection . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Delay Time for Mode Change . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 15 15 15 15 16 16 6 6.1 6.2 6.3 General Product Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Absolute Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Functional Range . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Thermal Resistance . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 17 17 18 18 7 7.1 7.2 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Functional Device Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 19 Diagrams . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 24 8 8.1 8.2 8.3 8.3.1 8.3.2 8.4 Application Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ESD Robustness according to IEC61000-4-2 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Application Example . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Examples for Mode Changes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mode Change while the TxD Signal is “low” . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Mode Change while the Bus Signal is “dominant” . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Further Application Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9 Package Outline . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 32 10 Revision History . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 33 Data Sheet 2 26 26 27 28 29 30 31 Rev. 1.0, 2015-08-12 High Speed CAN-Transceiver 1 TLE7250VLE TLE7250VSJ Overview Features • Fully compatible to ISO 11898-2 • Wide common mode range for electromagnetic immunity (EMI) • Very low electromagnetic emission (EME) • Excellent ESD robustness • Guaranteed loop delay symmetry to support CAN FD data frames up to 2 MBit/s • • VIO input for voltage adaption to the microcontroller supply Extended supply range on VCC and VIO supply CAN short circuit proof to ground, battery and VCC • TxD time-out function • Low CAN bus leakage current in power-down state • Overtemperature protection • Protected against automotive transients • Power-save mode • Transmitter supply VCC can be turned off in power-save mode • Green Product (RoHS compliant) • Two package variants: PG-TSON-8 and PG-DSO-8 • AEC Qualified • PG-TSON-8 PG-DSO-8 Description The TLE7250V is a transceiver designed for HS CAN networks in automotive and industrial applications. As an interface between the physical bus layer and the CAN protocol controller, the TLE7250V drives the signals to the bus and protects the microcontroller against interferences generated within the network. Based on the high symmetry of the CANH and CANL signals, the TLE7250V provides a very low level of electromagnetic emission (EME) within a wide frequency range. The TLE7250V is available in a small, leadless PG-TSON-8 package and in a PG-DSO-8 package. Both packages are RoHS compliant and halogen free. Additionally the PG-TSON-8 package supports the solder joint requirements for automated optical inspection (AOI). The TLE7250VLE and the TLE7250VSJ are fulfilling or exceeding the requirements of the ISO11898-2. The TLE7250V provides a digital supply input VIO and a power-save mode. It is designed to fulfill the enhanced physical layer requirements for CAN FD and supports data rates up to 2 MBit/s. On the basis of a very low leakage current on the HS CAN bus interface the TLE7250V provides an excellent passive behavior in power-down state. These and other features make the TLE7250V exceptionally suitable for Type Package Marking TLE7250VLE PG-TSON-8 7250V TLE7250VSJ PG-DSO-8 7250V Data Sheet 3 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Overview mixed supply HS CAN networks. Based on the Infineon Smart Power Technology SPT, the TLE7250V provides excellent ESD immunity together with a very high electromagnetic immunity (EMI). The TLE7250V and the Infineon SPT technology are AEC qualified and tailored to withstand the harsh conditions of the automotive environment. Two different operating modes, additional fail-safe features like a TxD time-out and the optimized output slew rates on the CANH and CANL signals, make the TLE7250V the ideal choice for large HS CAN networks with high data transmission rates. Data Sheet 4 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Block Diagram 2 Block Diagram 3 5 VCC VIO Transmitter CANH CANL 1 7 Driver Tempprotection 6 TxD Timeout Mode control 8 NEN Receiver Normal-mode receiver 4 RxD VCC/2 = Bus-biasing GND 2 Figure 1 Data Sheet Functional block diagram 5 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Pin Configuration 3 Pin Configuration 3.1 Pin Assignment TxD 1 GND 2 8 NEN 7 CANH CANL TxD 1 8 NEN GND 2 7 CANH VCC 3 6 CANL RxD 4 5 PAD VCC 3 6 RxD 4 5 VIO (Top-side x-ray view) Figure 2 Pin configuration 3.2 Pin Definitions Table 1 Pin definitions and functions Pin No. Symbol Function 1 TxD Transmit Data Input; internal pull-up to VIO, “low” for “dominant” state. 2 GND Ground 3 VCC Transmitter Supply Voltage; 100 nF decoupling capacitor to GND required, VCC can be turned off in power-save mode. 4 RxD Receive Data Output; “low” in “dominant” state. 5 VIO Digital Supply Voltage; supply voltage input to adapt the logical input and output voltage levels of the transceiver to the microcontroller supply, 100 nF decoupling capacitor to GND required. 6 CANL CAN Bus Low Level I/O; “low” in “dominant” state. 7 CANH CAN Bus High Level I/O; “high” in “dominant” state. Data Sheet 6 VIO Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Pin Configuration Table 1 Pin definitions and functions (cont’d) Pin No. Symbol Function 8 NEN Not Enable Input; internal pull-up to VIO, “low” for normal-operating mode. PAD – Connect to PCB heat sink area. Do not connect to other potential than GND. Data Sheet 7 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description 4 Functional Description HS CAN is a serial bus system that connects microcontrollers, sensors and actuators for real-time control applications. The use of the Controller Area Network (abbreviated CAN) within road vehicles is described by the international standard ISO 11898. According to the 7-layer OSI reference model the physical layer of a HS CAN bus system specifies the data transmission from one CAN node to all other available CAN nodes within the network. The physical layer specification of a CAN bus system includes all electrical and mechanical specifications of a CAN network. The CAN transceiver is part of the physical layer specification. Several different physical layer standards of CAN networks have been developed in recent years. The TLE7250V is a High Speed CAN transceiver without a wake-up function and defined by the international standard ISO 11898-2. 4.1 High Speed CAN Physical Layer VIO = VCC = TxD = TxD VIO RxD = CANH = t CANH CANL CANL = VDiff = VCC Digital supply voltage Transmitter supply voltage Transmit data input from the microcontroller Receive data output to the microcontroller Bus level on the CANH input/output Bus level on the CANL input/output Differential voltage between CANH and CANL VDiff = VCANH – VCANL t VDiff VCC “dominant” receiver threshold “recessive” receiver threshold t RxD VIO tLoop(H,L) Figure 3 Data Sheet tLoop(L,H) t High speed CAN bus signals and logic signals 8 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description The TLE7250V is a High-Speed CAN transceiver, operating as an interface between the CAN controller and the physical bus medium. A HS CAN network is a two wire, differential network which allows data transmission rates for CAN FD frames up to 2 MBit/s. Characteristic for HS CAN networks are the two signal states on the HS CAN bus: “dominant” and “recessive” (see Figure 3). VCC, VIO and GND are the supply pins for the TLE7250V. The pins CANH and CANL are the interface to the HS CAN bus and operate in both directions, as an input and as an output. RxD and TxD pins are the interface to the CAN controller, the TxD pin is an input pin and the RxD pin is an output pin. The NEN pin is the input pin for the mode selection (see Figure 4). By setting the TxD input pin to logical “low” the transmitter of the TLE7250V drives a “dominant” signal to the CANH and CANL pins. Setting TxD input to logical “high” turns off the transmitter and the output voltage on CANH and CANL discharges towards the “recessive” level. The “recessive” output voltage is provided by the bus biasing (see Figure 1). The output of the transmitter is considered to be “dominant”, when the voltage difference between CANH and CANL is at least higher than 1.5 V (VDiff = VCANH - VCANL). Parallel to the transmitter the normal-mode receiver monitors the signal on the CANH and CANL pins and indicates it on the RxD output pin. A “dominant” signal on the CANH and CANL pins sets the RxD output pin to logical “low”, vice versa a “recessive” signal sets the RxD output to logical “high”. The normal-mode receiver considers a voltage difference (VDiff) between CANH and CANL above 0.9 V as “dominant” and below 0.5 V as “recessive”. To be conform with HS CAN features, like the bit to bit arbitration, the signal on the RxD output has to follow the signal on the TxD input within a defined loop delay tLoop ≤ 255 ns. The thresholds of the digital inputs (TxD and NEN) and also the RxD output voltage are adapted to the digital power supply VIO. Data Sheet 9 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description 4.2 Modes of Operation The TLE7250V supports two different modes of operation, power-save mode and normal-operating mode while the transceiver is supplied according to the specified functional range. The mode of operation is selected by the NEN input pin (see Figure 4). power-save mode VCC = “don’t care” VIO > VIO(UV,R) NEN = 1 NEN = 0 VCC > VCC(UV,R) NEN = 1 normal-operating mode VIO > VIO(UV,R) NEN = 0 Figure 4 Mode state diagram 4.2.1 Normal-operating Mode In normal-operating mode the transmitter and the receiver of the HS CAN transceiver TLE7250V are active (see Figure 1). The HS CAN transceiver sends the serial data stream on the TxD input pin to the CAN bus. The data on the CAN bus is displayed at the RxD pin simultaneously. A logical “low” signal on the NEN pin selects the normal-operating mode, while the transceiver is supplied by VCC and VIO (see Table 2 for details). 4.2.2 Power-save Mode The power-save mode is an idle mode of the TLE7250V with optimized power consumption. In power-save mode the transmitter and the normal-mode receiver are turned off. The TLE7250V can not send any data to the CAN bus nor receive any data from the CAN bus. The RxD output pin is permanently “high” in the power-save mode. A logical “high” signal on the NEN pin selects the power-save mode, while the transceiver is supplied by the digital supply VIO (see Table 2 for details). In power-save mode the bus input pins are not biased. Therefore the CANH and CANL input pins are floating and the HS CAN bus interface has a high resistance. The undervoltage detection on the transmitter supply VCC is turned off, allowing to switch off the VCC supply in power-save mode. Data Sheet 10 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description 4.3 Power-up and Undervoltage Condition By detecting an undervoltage event, either on the transmitter supply VCC or the digital supply VIO, the transceiver TLE7250V changes the mode of operation. Turning off the digital power supply VIO, the transceiver powers down and remains in the power-down state. While switching off the transmitter supply VCC, the transceiver either changes to the forced power-save mode, or remains in power-save mode (details see Figure 5). normal-operating mode VIO “on” VCC “on” NEN “0” power-down state NEN VCC VIO “X” “X” “off” NEN VCC VIO 0 “on” “on” VIO “on” VCC “on” NEN “0” VIO “on” VCC “off” NEN “0” VIO “on” VCC “X” NEN “1” power-save mode VIO “on” VCC “X” NEN “1” Figure 5 Power-up and undervoltage Table 2 Modes of operation NEN VCC VIO 1 “X” “on” VIO “on” VCC “on” NEN “0” VIO “on” VCC “off” NEN “0” forced power-save mode NEN VCC VIO 0 “off” “on” VIO “on” VCC “X” NEN “1” Mode NEN VIO VCC Bus Bias Transmitter Normal-mode Low-power Receiver Receiver Normal-operating “low” “on” “on” VCC/2 “on” “on” not available Power-save “high” “on” “X” floating “off” “off” not available Forced power-save “low” “on” “off” floating “off” “off” not available Power-down state “off” “X” floating “off” “off” not available Data Sheet “X” 11 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description 4.3.1 Power-down State Independent of the transmitter supply VCC and of the NEN input pin, the TLE7250V is in power-down state when the digital supply voltage VIO is turned off (see Figure 5). In the power-down state the input resistors of the receiver are disconnected from the bus biasing VCC/2. The CANH and CANL bus interface of the TLE7250V is floating and acts as a high-impedance input with a very small leakage current. The high-ohmic input does not influence the “recessive” level of the CAN network and allows an optimized EME performance of the entire HS CAN network (see also Table 2). 4.3.2 Forced Power-save Mode The forced power-save mode is a fail-safe mode to avoid any disturbance on the HS CAN bus, while the TLE7250V faces a loss of the transmitter supply VCC. In forced power-save mode, the transmitter and the normal-mode receiver are turned off and therefore the transceiver TLE7250V can not disturb the bus media. The RxD output pin is permanently set to logical “high”. The bus biasing is floating (details see Table 2). The forced power-save mode can only be entered when the transmitter supply VCC is not available, either by powering up the digital supply VIO only or by turning off the transmitter supply in normal-operating mode. While the transceiver TLE7250V is in forced power-save mode, switching the NEN input to logical “high” triggers a mode change to power-save mode (see Figure 5). 4.3.3 Power-up The HS CAN transceiver TLE7250V powers up if at least the digital supply VIO is connected to the device. By default the device powers up in power-save mode, due to the internal pull-up resistor on the NEN pin to VIO. In case the device needs to power-up to normal-operating mode, the NEN pin needs to be pulled active to logical “low” and the supplies VIO and VCC have to be connected. By supplying only the digital power supply VIO the TLE7250V powers up either in forced power-save mode or in power-save mode, depending on the signal of the NEN input pin (see Figure 5). Data Sheet 12 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description Undervoltage on the Digital Supply VIO 4.3.4 If the voltage on VIO supply input falls below the threshold VIO < VIO(UV,F), the transceiver TLE7250V powers down and changes to the power-down state. The undervoltage detection on the digital supply VIO has the highest priority. It is independent of the transmitter supply VCC and also independent of the currently selected operating mode. An undervoltage event on VIO always powers down the TLE7250V. transmitter supply voltage VCC = “don’t care” VIO VIO undervoltage monitor VIO(UV,F) VIO undervoltage monitor VIO(UV,R) hysteresis VIO(UV,H) tDelay(UV) delay time undervoltage t any mode of operation power-down state stand-by mode NEN “high” due the internal pull-up resistor1) “X” = don’t care 1) Figure 6 Data Sheet assuming no external signal applied t Undervoltage on the digital supply VIO 13 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Functional Description 4.3.5 Undervoltage on the Transmitter Supply VCC In case the transmitter supply VCC falls below the threshold VCC < VCC(UV,F), the transceiver TLE7250V changes the mode of operation to forced power-save mode. The transmitter and also the normal-mode receiver of the TLE7250V are powered by the VCC supply. In case of an insufficient VCC supply, the TLE7250V can neither transmit the CANH and CANL signals correctly to the bus, nor can it receive them properly. Therefore the TLE7250V blocks the transmitter and the receiver in forced power-save mode (see Figure 7). The undervoltage detection on the transmitter supply VCC is only active in normal-operating mode (see Figure 5). digital supply voltage VIO = “on” VCC VCC undervoltage monitor VCC(UV,F) VCC undervoltage monitor VCC(UV,R) hysteresis VCC(UV,H) tDelay(UV) delay time undervoltage t normal-operating mode forced stand-by mode normal-operating mode NEN Assuming the NEN remains “low”. The “low” signal is driven by the external microcontroller Figure 7 Undervoltage on the transmitter supply VCC 4.3.6 Voltage Adaption to the Microcontroller Supply t The HS CAN transceiver TLE7250V has two different power supplies, VCC and VIO. The power supply VCC supplies the transmitter and the normal-mode receiver. The power supply VIO supplies the digital input and output buffers and it is also the main power domain for the internal logic. To adjust the digital input and output levels of the TLE7250V to the I/O levels of the external microcontroller, connect the power supply VIO to the microcontroller I/O supply voltage (see Figure 13). Note: In case the digital supply voltage VIO is not required in the application, connect the digital supply voltage VIO to the transmitter supply VCC. Data Sheet 14 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Fail Safe Functions 5 Fail Safe Functions 5.1 Short Circuit Protection The CANH and CANL bus outputs are short circuit proof, either against GND or a positive supply voltage. A current limiting circuit protects the transceiver against damages. If the device is heating up due to a continuous short on the CANH or CANL, the internal overtemperature protection switches off the bus transmitter. 5.2 Unconnected Logic Pins All logic input pins have an internal pull-up resistor to VIO. In case the VIO supply is activated and the logical pins are open, the TLE7250V enters into the power-save mode by default. In power-save mode the transmitter of the TLE7250V is disabled and the bus bias is floating. 5.3 TxD Time-out Function The TxD time-out feature protects the CAN bus against permanent blocking in case the logical signal on the TxD pin is continuously “low”. A continuous “low” signal on the TxD pin might have its root cause in a locked-up microcontroller or in a short circuit on the printed circuit board, for example. In normal-operating mode, a logical “low” signal on the TxD pin for the time t > tTxD enables the TxD time-out feature and the TLE7250V disables the transmitter (see Figure 8). The receiver is still active and the data on the bus continues to be monitored by the RxD output pin. t > tTxD TxD time-out CANH CANL TxD time–out released t TxD t RxD t Figure 8 TxD time-out function Figure 8 illustrates how the transmitter is deactivated and activated again. A permanent “low” signal on the TxD input pin activates the TxD time-out function and deactivates the transmitter. To release the transmitter after a TxD time-out event the TLE7250V requires a signal change on the TxD input pin from logical “low” to logical “high”. Data Sheet 15 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Fail Safe Functions 5.4 Overtemperature Protection The TLE7250V has an integrated overtemperature detection to protect the TLE7250V against thermal overstress of the transmitter. The overtemperature protection is active in normal-operating mode and disabled in power-save mode. In case of an overtemperature condition, the temperature sensor will disable the transmitter (see Figure 1) while the transceiver remains in normal-operating mode. After the device has cooled down the transmitter is activated again (see Figure 9). A hysteresis is implemented within the temperature sensor. TJSD (shut down temperature) TJ cool down ˂T switch-on transmitter t CANH CANL t TxD t RxD t Figure 9 Overtemperature protection 5.5 Delay Time for Mode Change The HS CAN transceiver TLE7250V changes the mode of operation within the time window tMode. During the mode change the RxD output pin is permanently set to logical “high” and does not reflect the status on the CANH and CANL input pins (see as an example Figure 14 and Figure 15). Data Sheet 16 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ General Product Characteristics 6 General Product Characteristics 6.1 Absolute Maximum Ratings Table 3 Absolute maximum ratings voltages, currents and temperatures1) 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 VCC VIO VCANH VCANL VCAN_Diff -0.3 – 6.0 V – P_6.1.1 -0.3 – 6.0 V – P_6.1.2 -40 – 40 V – P_6.1.3 -40 – 40 V – P_6.1.4 -40 – 40 V – P_6.1.5 Voltages at the input pins: NEN, TxD VMAX_IN -0.3 – 6.0 V – P_6.1.6 Voltages at the output pin: RxD VMAX_OUT -0.3 – VIO V – P_6.1.7 IRxD -20 – 20 mA – P_6.1.8 Tj TS -40 – 150 °C – P_6.1.9 -55 – 150 °C – P_6.1.10 – 9 kV HBM P_6.1.11 (100 pF via 1.5 kΩ)2) – 2 kV HBM P_6.1.12 2) (100 pF via 1.5 kΩ) – 750 V CDM3) Voltages Transmitter supply voltage Digital supply voltage CANH DC voltage versus GND CANL DC voltage versus GND Differential voltage between CANH and CANL Currents RxD output current Temperatures Junction temperature Storage temperature ESD Resistivity ESD immunity at CANH, CANL versus GND VESD_HBM_ -9 ESD immunity at all other pins VESD_HBM_ -2 ESD immunity to GND VESD_CDM -750 CAN ALL P_6.1.13 1) Not subject to production test, specified by design 2) ESD susceptibility, Human Body Model “HBM” according to ANSI/ESDA/JEDEC JS-001 3) ESD susceptibility, Charge Device Model “CDM” according to EIA/JESD22-C101 or ESDA STM5.3.1 Note: 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. 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 continuos repetitive operation. Data Sheet 17 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ General Product Characteristics 6.2 Functional Range Table 4 Functional range Parameter Symbol Values Unit Note / Test Condition Number Min. Typ. Max. VCC VIO 4.5 – 5.5 V – P_6.2.1 3.0 – 5.5 V – P_6.2.2 Tj -40 – 150 °C 1) P_6.2.3 Supply Voltages Transmitter supply voltage Digital supply voltage Thermal Parameters Junction temperature 1) Not subject to production test, specified by design. 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. 6.3 Thermal Resistance Note: This thermal data was generated in accordance with JEDEC JESD51 standards. For more information, please visit www.jedec.org. Table 5 Thermal resistance1) Parameter Symbol Values Min. Typ. Max. – 55 – Unit Note / Test Condition Number K/W 2) TLE7250VLE P_6.3.1 TLE7250VSJ P_6.3.2 Thermal Resistances Junction to Ambient PG-TSON-8 Junction to Ambient PG-DSO-8 RthJA RthJA – 130 – K/W 2) 150 175 200 °C – P_6.3.3 – 10 – K – P_6.3.4 Thermal Shutdown (junction temperature) Thermal shutdown temperature Thermal shutdown hysteresis TJSD ∆T 1) Not subject to production test, specified by design 2) Specified RthJA value is according to Jedec JESD51-2,-7 at natural convection on FR4 2s2p board. The product (TLE7250V) was simulated on a 76.2 x 114.3 x 1.5 mm board with 2 inner copper layers (2 x 70µm Cu, 2 x 35µm Cu). Data Sheet 18 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics 7 Electrical Characteristics 7.1 Functional Device Characteristics Table 6 Electrical characteristics 4.5 V < VCC < 5.5 V; 3.0 V < VIO < 5.5 V; RL = 60 Ω; -40 °C < Tj < 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 Current Consumption Current consumption at VCC normal-operating mode ICC – 2.6 4 mA “recessive” state, VTxD = VIO, VNEN = 0 V; P_7.1.1 Current consumption at VCC normal-operating mode ICC – 38 60 mA “dominant” state, VTxD = VNEN = 0 V; P_7.1.2 Current consumption at VIO normal-operating mode IIO – – 1 mA VNEN = 0 V; P_7.1.3 Current consumption at VCC power-save mode ICC(PSM) – – 5 µA VTxD = VNEN = VIO; P_7.1.4 Current consumption at VIO power-save mode IIO(PSM) – 5 8 µA VTxD = VNEN = VIO, 0 V < VCC < 5.5 V; P_7.1.5 VCC(UV,R) 3.8 4.0 4.3 V – P_7.1.6 VCC(UV,F) 3.65 3.85 4.3 V – P_7.1.7 VCC(UV,H) – 150 – mV 1) P_7.1.8 VIO undervoltage monitor rising edge VIO(UV,R) 2.0 2.5 3.0 V – P_7.1.9 VIO undervoltage monitor falling edge VIO(UV,F) 2.3 3.0 V – P_7.1.10 VIO undervoltage monitor VIO(UV,H) – 200 – mV 1) P_7.1.11 – – 100 µs 1) (see Figure 6 and Figure 7); P_7.1.12 P_7.1.13 VRxD = VIO - 0.4 V, VDiff < 0.5 V; VRxD = 0.4 V, VDiff > 0.9 V; P_7.1.14 Supply Resets VCC undervoltage monitor rising edge VCC undervoltage monitor falling edge VCC undervoltage monitor hysteresis 1.8 hysteresis VCC and VIO undervoltage delay tDelay(UV) time Receiver Output RxD “High” level output current IRD,H – -4 -2 mA “Low” level output current IRD,L 2 4 – mA Data Sheet 19 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics Table 6 Electrical characteristics (cont’d) 4.5 V < VCC < 5.5 V; 3.0 V < VIO < 5.5 V; RL = 60 Ω; -40 °C < Tj < 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 Transmission Input TxD “High” level input voltage threshold VTxD,H – 0.5 × VIO 0.7 × VIO V “recessive” state; P_7.1.15 “Low” level input voltage threshold VTxD,L 0.3 × VIO 0.4 × VIO – V “dominant” state; P_7.1.16 Pull-up resistance RTxD VHYS(TxD) CTxD tTxD 10 25 50 kΩ – P_7.1.17 mV 1) P_7.1.18 P_7.1.19 “High” level input voltage threshold Input hysteresis – 450 – – – 10 pF 1) 4.5 – 16 ms normal-operating mode; P_7.1.20 VNEN,H – 0.5 × VIO 0.7 × VIO V power-save mode; P_7.1.21 “Low” level input voltage threshold VNEN,L 0.3 × VIO 0.4 × VIO – V normal-operating mode; P_7.1.22 Pull-up resistance RNEN 10 CNEN – VHYS(NEN) – 25 50 kΩ – P_7.1.23 pF 1) P_7.1.24 200 – mV 1) P_7.1.25 Differential receiver threshold “dominant” normal-operating mode VDiff_D – 0.75 0.9 V 2) P_7.1.26 Differential receiver threshold “recessive” normal-operating mode VDiff_R 0.5 0.66 – V 2) P_7.1.27 Common mode range CMR -12 – 12 V VCC = 5 V; P_7.1.28 P_7.1.29 Input capacitance TxD permanent “dominant” time-out Not Enable Input NEN Input capacitance Input hysteresis – 10 Bus Receiver Differential receiver hysteresis normal-operating mode VDiff,hys – 90 – mV 1) CANH, CANL input resistance Ri RDiff ∆R i 10 20 30 kΩ “recessive” state; P_7.1.30 20 40 60 kΩ “recessive” state; P_7.1.31 “recessive” state; P_7.1.32 Differential input resistance Input resistance deviation between CANH and CANL Input capacitance CANH, CANL CIn versus GND Differential input capacitance Data Sheet CIn_Diff -1 – 1 % 1) – 20 40 pF 1) VTxD = VIO; P_7.1.33 – 10 20 pF 1) VTxD = VIO; P_7.1.34 20 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics Table 6 Electrical characteristics (cont’d) 4.5 V < VCC < 5.5 V; 3.0 V < VIO < 5.5 V; RL = 60 Ω; -40 °C < Tj < 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 Bus Transmitter CANL/CANH “recessive” output voltage normal-operating mode VCANL/H 2.0 2.5 3.0 V VTxD = VIO, no load; P_7.1.35 CANH, CANL “recessive” output voltage difference normal-operating mode VDiff_NM -500 – 50 mV VTxD = VIO, P_7.1.36 CANL “dominant” output voltage normal-operating mode VCANL 0.5 – 2.25 V VTxD = 0 V; P_7.1.37 CANH “dominant” output voltage normal-operating mode VCANH 2.75 – 4.5 V VTxD = 0 V; P_7.1.38 CANH, CANL “dominant” output voltage difference normal-operating mode according to ISO 11898-2 VDiff = VCANH - VCANL VDiff 1.5 – 3.0 V VTxD = 0 V, 50 Ω < RL < 65 Ω, 4.75 < VCC < 5.25 V; P_7.1.39 CANH, CANL “dominant” output voltage difference normal-operating mode VDiff = VCANH - VCANL VDiff_R45 1.4 – 3.0 V VTxD = 0 V, 45 Ω < RL < 50 Ω, 4.75 < VCC < 5.25 V; P_7.1.40 Driver “dominant” symmetry normal-operating mode VSYM = VCANH + VCANL VSYM 4.5 5 5.5 V VCC = 5.0 V, VTxD = 0 V; P_7.1.41 CANL short circuit current ICANLsc 40 75 100 mA P_7.1.42 CANH short circuit current ICANHsc -100 -75 -40 mA Leakage current, CANH ICANH,lk -5 – 5 µA Leakage current, CANL ICANL,lk -5 – 5 µA VCANLshort = 18 V, VCC = 5.0 V, t < tTxD, VTxD = 0 V; VCANHshort = 0 V, VCC = 5.0 V, t < tTxD, VTxD = 0 V; VCC = VIO = 0 V, 0 V < VCANH < 5 V, VCANH = VCANL; VCC = VIO = 0 V, 0 V < VCANL < 5 V, VCANH = VCANL; Data Sheet no load; 21 P_7.1.43 P_7.1.44 P_7.1.45 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics Table 6 Electrical characteristics (cont’d) 4.5 V < VCC < 5.5 V; 3.0 V < VIO < 5.5 V; RL = 60 Ω; -40 °C < Tj < 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 Dynamic CAN-Transceiver Characteristics Propagation delay TxD-to-RxD “low” (“recessive to “dominant”) tLoop(H,L) – 180 255 ns CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; P_7.1.46 Propagation delay TxD-to-RxD “high” (“dominant” to “recessive”) tLoop(L,H) – 180 255 ns P_7.1.47 Propagation delay extended load TxD-to-RxD “low” (“recessive to “dominant”) tLoop_Ext(H – – 300 ns Propagation delay extended load TxD-to-RxD “high” (“dominant” to “recessive”) tLoop_Ext(L – – 300 ns Propagation delay TxD “low” to bus “dominant” td(L),T – 90 140 ns Propagation delay TxD “high” to bus “recessive” td(H),T – 90 140 ns Propagation delay bus “dominant” to RxD “low” td(L),R – 90 140 ns Propagation delay bus “recessive” to RxD “high” td(H),R – 90 140 ns CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; 1) CL = 200 pF, RL = 120 Ω, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; 1) CL = 200 pF, RL = 120 Ω, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF; tMode – – 20 µs 1) P_7.1.52 ,L) ,H) P_7.1.53 P_7.1.54 P_7.1.48 P_7.1.49 P_7.1.50 P_7.1.51 Delay Times Delay time for mode change Data Sheet 22 (see Figure 14 and Figure 15); Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics Table 6 Electrical characteristics (cont’d) 4.5 V < VCC < 5.5 V; 3.0 V < VIO < 5.5 V; RL = 60 Ω; -40 °C < Tj < 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. 500 550 ns CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF, tBit = 500 ns, (see Figure 12); P_7.1.55 500 530 ns CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF, tBit = 500 ns, (see Figure 12); P_7.1.56 – 40 ns CL = 100 pF, 4.75 V < VCC < 5.25 V, CRxD = 15 pF, tBit = 500 ns, (see Figure 12); P_7.1.57 CAN FD Characteristics Received recessive bit width at 2 MBit/s tBit(RxD)_2 400 Transmitted recessive bit width at 2 MBit/s tBit(Bus)_2 435 Receiver timing symmetry at 2 MBit/s ∆tRec = tBit(RxD) - tBit(Bus) ΔtRec_2MB -65 MB MB 1) Not subject to production test, specified by design. 2) In respect to common mode range. Data Sheet 23 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics 7.2 Diagrams VIO 7 100 nF CANH TxD NEN CL 5 1 8 RL RxD 6 4 CRxD CANL GND VCC 3 100 nF 2 Figure 10 Test circuits for dynamic characteristics TxD 0.7 x VIO 0.3 x VIO t td(L),T td(H),T VDiff 0.9 V 0.5 V t td(L),R td(H),R tLoop(H,L) tLoop(L,H) RxD 0.7 x VIO 0.3 x VIO t Figure 11 Data Sheet Timing diagrams for dynamic characteristics 24 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Electrical Characteristics TxD 0.7 x VIO 0.3 x VIO 0.3 x VIO 5 x tBit VDiff tBit t tLoop(H,L) tBit(Bus) VDiff = VCANH - VCANL 0.9 V 0.5 V t tLoop(L,H) tBit(RxD) RxD 0.7 x VIO 0.3 x VIO t Figure 12 Data Sheet “Recessive” bit time - five “dominant” bits followed by one “recessive” bit 25 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8 Application Information 8.1 ESD Robustness according to IEC61000-4-2 Test for ESD robustness according to IEC61000-4-2 “Gun test” (150 pF, 330 Ω) have been performed. The results and test conditions are available in a separate test report. Table 7 ESD robustness according to IEC61000-4-2 Performed Test Result Unit Remarks Electrostatic discharge voltage at pin CANH and ≥ +8 CANL versus GND kV 1) Positive pulse Electrostatic discharge voltage at pin CANH and ≤ -8 CANL versus GND kV 1) Negative pulse 1) ESD susceptibility “ESD GUN” according to GIFT / ICT paper: “EMC Evaluation of CAN Transceivers, version 03/02/IEC TS62228”, section 4.3. (DIN EN61000-4-2) Tested by external test facility (IBEE Zwickau, EMC test report no. TBD). Data Sheet 26 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8.2 Application Example VBAT I Q1 22 uF TLE4476D CANH CANL EN GND 100 nF 100 nF Q2 3 VCC 22 uF 120 Ohm VIO TLE7250VLE 7 6 optional: common mode choke NEN CANH TxD RxD CANL 100 nF 5 8 VCC Out 1 Out 4 In Microcontroller e.g. XC22xx GND GND 2 I Q1 22 uF TLE4476D EN GND 100 nF Q2 3 VCC 22 uF VIO TLE7250VLE 7 6 NEN CANH TxD RxD CANL optional: common mode choke Figure 13 Data Sheet 8 1 4 100 nF 100 nF VCC Out Out In Microcontroller e.g. XC22xx GND 120 Ohm CANH 5 GND 2 CANL example ECU design Application circuit 27 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8.3 Examples for Mode Changes Changing the status on the NEN input pin triggers a change of the operating mode, disregarding the actual signal on the CANH, CANL and TxD pins (see also Chapter 4.2). Mode changes are triggered by the NEN pin, when the device TLE7250V is fully supplied. Setting the NEN pin to logical “low” changes the mode of operation to normal-operating mode: • The mode change is executed independently of the signal on the HS CAN bus. The CANH, CANL inputs may be either “dominant” or “recessive”. They can be also permanently shorted to GND or VCC. • A mode change is performed independently of the signal on the TxD input. The TxD input may be either logical “high” or “low”. Analog to that, changing the NEN input pin to logical “high” changes the mode of operation to the power-save mode independent on the signals at the CANH, CANL and TxD pins. Note: In case the TxD signal is “low” setting the NEN input pin to logical “low” changes the operating mode of the device to normal-operating mode and drives a “dominant” signal to the HS CAN bus. Note: The TxD time-out is only effective in normal-operating mode. The TxD time-out timer starts when the TLE7250V enters normal-operating mode and the TxD input is set to logical “low”. Data Sheet 28 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8.3.1 Mode Change while the TxD Signal is “low” The example in Figure 14 shows a mode change to normal-operating mode while the TxD input is logical “low”. The HS CAN signal is “recessive”, assuming all other HS CAN bus subscribers are also sending a “recessive” bus signal. While the transceiver TLE7250V is in power-save mode, the transmitter and the normal-mode receiver are turned off. The TLE7250V drives no signal to the HS CAN bus nor does it receive any signal from the HS CAN bus. Changing the NEN to logical “low” turns the mode of operation to normal-operating mode, while the TxD input signal remains logical “low”. The transmitter and the normal-mode receiver remain disabled until the mode transition is completed. In normal-operating mode the transmitter and the normal-mode receiver are active. The “low” signal on the TxD input drives a “dominant” signal to the HS CAN bus and the RxD output becomes logical “low” following the “dominant” signal on the HS CAN bus. Changing the NEN pin back to logical “high”, disables the transmitter and normal-mode receiver again. The RxD output pin is blocked and set to logical “high” with the start of the mode transition. The TxD input and the transmitter are blocked and the HS CAN bus becomes “recessive”. Note: The signals on the HS CAN bus are “recessive”, the “dominant” signal is generated by the TxD input signal t = tMode t = tMode NEN t TxD t VDiff t RxD t power-save transition normal-operating transition power-save mode normal-mode receiver disabled RxD output blocked normal-mode receiver active RxD output blocked normal-mode receiver disabled TxD input and transmitter blocked Figure 14 Data Sheet TxD input and transmitter active TxD input and transmitter blocked Example for a mode change while the TxD is “low” 29 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8.3.2 Mode Change while the Bus Signal is “dominant” The example in Figure 15 shows a mode change while the bus is “dominant” and the TxD input signal is set to logical “high”. While the transceiver TLE7250V is in power-save mode, the transmitter and the normal-mode receiver are turned off. The TLE7250V drives no signal to the HS CAN bus nor does it receive any signal from the HS CAN bus. Changing the NEN to logical “low” turns the mode of operation to normal-operating mode, while the TxD input signal remains logical “high”. The transmitter and the normal-mode receiver remain disabled until the mode transition is completed. In normal-operating mode the transmitter of TLE7250V remains “recessive”, because of the logical “high” signal on the TxD input. The normal-mode receiver becomes active and the RxD output signal changes to logical “low” following the “dominant” signal on the HS CAN bus. Changing the NEN pin back to logical “high”, disables the transmitter and normal-mode receiver again. The RxD output pin is blocked and set to logical “high” with the start of the mode transition. Note: The “dominant” signal on the HS CAN bus is set by another HS CAN bus subscriber. t = tMode t = tMode NEN t TxD t VDiff t RxD power-save mode transition normal-operating transition t power-save mode normal-mode receiver disabled RxD output blocked normal-mode receiver active RxD output blocked normal-mode receiver disabled TxD input and transmitter blocked Figure 15 Data Sheet TxD input and transmitter active TxD input and transmitter blocked Example for a mode change while the HS CAN is “dominant” 30 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Application Information 8.4 Further Application Information • Please contact us for information regarding the pin FMEA. • Existing application note. • For further information you may visit: http://www.infineon.com/ Data Sheet 31 Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Package Outline 0 +0.05 1±0.1 Package Outline 0.3 ±0.1 Pin 1 Marking 1.63 ±0.1 0.56 ±0.1 0.25 ±0.1 3 ±0.1 0.05 Z 0.38 ±0.1 0.4 ±0.1 3 ±0.1 2.4 ±0.1 1.58 ±0.1 0.1 ±0.1 0.81 ±0.1 0.2 ±0.1 9 0.65 ±0.1 Pin 1 Marking 0.3 ±0.1 PG-TSON-8-1-PO V01 Z (4:1) 0.07 MIN. PG-TSON-8 (Plastic Thin Small Outline Nonleaded PG-TSON-8-1) 0.1 2) 0.41+0.1 -0.06 0.2 8 5 1 4 5 -0.2 1) M 0.19 +0.06 C B 8 MAX. 1.27 0.35 x 45˚ 4 -0.2 1) 1.75 MAX. 0.175 ±0.07 (1.45) Figure 16 0.64 ±0.25 6 ±0.2 A B 8x 0.2 M C 8x A Index Marking 1) Does not include plastic or metal protrusion of 0.15 max. per side 2) Lead width can be 0.61 max. in dambar area GPS01181 Figure 17 PG-DSO-8 (Plastic Dual Small Outline PG-DSO-8-44) 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 32 Dimensions in mm Rev. 1.0, 2015-08-12 TLE7250VLE TLE7250VSJ Revision History 10 Revision History Revision Date Changes 1.00 2015-08-12 Data Sheet created. Data Sheet 33 Rev. 1.0, 2015-08-12 Edition 2015-08-12 Published by Infineon Technologies AG 81726 Munich, Germany © 2006 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.