Features • • • • • • • • • • • • • • • • • • Master and Slave Operation Possible Supply Voltage up to 40V Operating voltage VS = 5V to 27V Typically 10 µA Supply Current During Sleep Mode Typically 57 µA Supply Current in Silent Mode Linear Low-drop Voltage Regulator: – Normal, Fail-safe, and Silent Mode – ATA6622 VCC = 3.3V ±2% – ATA6624 VCC = 5.0V ±2% – ATA6626 VCC = 5.0V ±2%, TXD Time-out Timer Disabled – In Sleep Mode VCC is Switched Off VCC- Undervoltage Detection (4 ms Reset Time) and Watchdog Reset Logical Combined at Open Drain Output NRES Negative Trigger Input for Watchdog Boosting the Voltage Regulator Possible with an External NPN Transistor LIN Physical Layer According to LIN 2.0, 2.1 and SAEJ2602-2 Wake-up Capability via LIN-bus, Wake Pin, or Kl_15 Pin INH Output to Control an External Voltage Regulator or to Switch off the Master Pull Up Resistor TXD Time-out Timer; ATA6626: TXD Time-out Timer Is Disabled Bus Pin is Overtemperature and Short Circuit Protected versus GND and Battery Adjustable Watchdog Time via External Resistor Advanced EMC and ESD Performance ESD HBM 8 kV at Pins LIN and VS According to STM5.1 Package: QFN 5 mm × 5 mm with 20 Pins LIN Bus Transceiver with 3.3V (5V) Regulator and Watchdog ATA6622 ATA6624 ATA6626 1. Description The ATA6622 is a fully integrated LIN transceiver, which complies with the LIN 2.0, 2.1 and SAEJ2602-2 specifications. It has a low-drop voltage regulator for 3.3V/50 mA output and a window watchdog. The ATA6624 has the same functionality as the ATA6622; however, it uses a 5V/50 mA regulator. The ATA6626 has the same functionality as ATA6624 without a TXD time-out timer. The voltage regulator is able to source 50 mA, but the output current can be boosted by using an external NPN transistor. This chip combination makes it possible to develop inexpensive, simple, yet powerful slave and master nodes for LIN-bus systems. ATA6622/ATA6624/ATA6626 are designed to handle the low-speed data communication in vehicles, e.g., in convenience electronics. Improved slope control at the LIN-driver ensures secure data communication up to 20 kBaud. Sleep Mode and Silent Mode guarantee very low current consumption. The ATA6626 is able to switch the LIN unlimited to dominant level via TXD for low data rates. 4986G–AUTO–09/09 Figure 1-1. Block Diagram 20 VS Normal and Fail-safe Mode 10 INH PVCC Normal Mode Receiver - 9 RXD + 7 RF Filter LIN 4 WAKE 16 KL_15 PVCC Edge Detection Wake-up Bus Timer Slew Rate Control TXD Time-out Timer 11 TXD Short Circuit and Overtemperature Protection *) Control Unit EN GND 1 5 Debounce Time Mode Select Normal/Silent/ Fail-safe Mode 3.3/5V /50 mA/±2% 19 Undervoltage Reset 12 OUT Internal Testing Unit Watchdog 18 VCC PVCC NRES Adjustable Watchdog Oscillator 13 WD_OSC PVCC 15 MODE 14 3 TM NTRIG *) Not in ATA6626 2 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 2. Pin Configuration EN VCC PVCC GND KL15 Pinning QFN20 VS Figure 2-1. 20 19 18 17 16 1 15 MODE 14 TM 13 WD_OSC 12 NRES 11 TXD ATA6622/24/26 Table 2-1. 4 GND 5 6 7 8 9 10 INH WAKE QFN 5 mm × 5 mm 0.65 mm pitch 20 lead RXD 3 GND NTRIG LIN 2 GND GND Pin Description Pin Symbol Function 1 EN 2 GND 3 NTRIG Low-level watchdog trigger input from microcontroller 4 WAKE High-voltage input for local wake-up request; if not needed, connect to VS 5 GND System ground (mandatory) 6 GND System ground (optional) 7 LIN LIN-bus line input/output 8 GND System ground (optional) 9 RXD Receive data output 10 INH Battery related output for controlling an external voltage regulator 11 TXD Transmit data input; active low output (strong pull down) after a local wake-up request Enables the device in Normal Mode System ground (optional) 12 NRES 13 WD_OSC 14 TM 15 MODE For debug mode: low, watchdog is on; high, watchdog is off 16 KL_15 Ignition detection (edge sensitive) 17 GND System ground (optional) 18 PVCC 3.3V/5V regulator sense input pin 19 VCC 3.3V/5V regulator output/driver pin 20 VS Backside Output undervoltage and watchdog reset (open drain) External resistor for adjustable watchdog timing For factory testing only (tie to ground) Battery supply Heat slug is connected to all GND pins 3 4986G–AUTO–09/09 3. Functional Description 3.1 Physical Layer Compatibility Since the LIN physical layer is independent from higher LIN layers (e.g., the LIN protocol layer), all nodes with a LIN physical layer according to revision 2.x can be mixed with LIN physical layer nodes, which, according to older versions (i.e., LIN 1.0, LIN 1.1, LIN 1.2, LIN 1.3), are without any restrictions. 3.2 Supply Pin (VS) The LIN operating voltage is VS = 5V to 27V. An undervoltage detection is implemented to disable data transmission if VS falls below VSth < 4V in order to avoid false bus messages. After switching on VS, the IC starts in Fail-safe Mode, and the voltage regulator is switched on (i.e., 3.3V/5V/50 mA output capability). The supply current is typically 10 µA in Sleep Mode and 57 µA in Silent Mode. 3.3 Ground Pin (GND) The IC is neutral on the LIN pin in the event of GND disconnection. It is able to handle a ground shift up to 11.5% of VS. The mandatory system ground is pin 5. 3.4 Voltage Regulator Output Pin (VCC) The internal 3.3V/5V voltage regulator is capable of driving loads with up to 50 mA. It is able to supply the microcontroller and other ICs on the PCB and is protected against overloads by means of current limitation and overtemperature shut-down. Furthermore, the output voltage is monitored and will cause a reset signal at the NRES output pin if it drops below a defined threshold Vthun. To boost up the maximum load current, an external NPN transistor may be used, with its base connected to the VCC pin and its emitter connected to PVCC. 3.5 Voltage Regulator Sense Pin (PVCC) The PVCC is the sense input pin of the 3.3V/5V voltage regulator. For normal applications (i.e., when only using the internal output transistor), this pin is connected to the VCC pin. If an external boosting transistor is used, the PVCC pin must be connected to the output of this transistor, i.e., its emitter terminal. 3.6 Bus Pin (LIN) A low-side driver with internal current limitation and thermal shutdown and an internal pull-up resistor compliant with the LIN 2.x specification are implemented. The allowed voltage range is between –27V and +40V. Reverse currents from the LIN bus to VS are suppressed, even in the event of GND shifts or battery disconnection. LIN receiver thresholds are compatible with the LIN protocol specification. The fall time from recessive to dominant bus state and the rise time from dominant to recessive bus state are slope controlled. 4 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 3.7 Input/Output Pin (TXD) In Normal Mode the TXD pin is the microcontroller interface used to control the state of the LIN output. TXD must be pulled to ground in order to have a low LIN-bus. If TXD is high or unconnected (internal pull-up resistor), the LIN output transistor is turned off, and the bus is in recessive state. During Fail-safe Mode, this pin is used as output. It is current-limited to < 8 mA. and is latched to low if the last wake-up event was from pin WAKE or KL_15. 3.8 TXD Dominant Time-out Function The TXD input has an internal pull-up resistor. An internal timer prevents the bus line from being driven permanently in dominant state. If TXD is forced to low for longer than tDOM > 6 ms, the LIN-bus driver is switched to recessive state. To reactivate the LIN bus driver, switch TXD to high (> 10 µs). The time-out function is disabled in the ATA6626. Switching to dominant level on the LIN bus occurs without any time limitations. 3.9 Output Pin (RXD) The Output pin reports the state of the LIN-bus to the microcontroller. LIN high (recessive state) is reported by a high level at RXD; LIN low (dominant state) is reported by a low level at RXD. The output has an internal pull-up resistor with typically 5 kΩ to VCC. The AC characteristics can be defined with an external load capacitor of 20 pF. The output is short-circuit protected. RXD is switched off in Unpowered Mode (i.e., VS = 0V). 3.10 Enable Input Pin (EN) The Enable Input pin controls the operation mode of the device. If EN is high, the circuit is in Normal Mode, with transmission paths from TXD to LIN and from LIN to RXD both active. The VCC voltage regulator operates with 3.3V/5V/50 mA output capability. If EN is switched to low while TXD is still high, the device is forced to Silent Mode. No data transmission is then possible, and the current consumption is reduced to IVS typ. 57 µA. The VCC regulator has its full functionality. If EN is switched to low while TXD is low, the device is forced to Sleep Mode. No data transmission is possible, and the voltage regulator is switched off. 3.11 Wake Input Pin (WAKE) The Wake Input pin is a high-voltage input used to wake up the device from Sleep Mode or Silent Mode. It is usually connected to an external switch in the application to generate a local wake-up. A pull-up current source, typically 10 µA, is implemented. If a local wake-up is not needed for the application, connect the Wake pin directly to the VS pin. 3.12 Mode Input Pin (MODE) Connect the MODE pin directly or via an external resistor to GND for normal watchdog operation. To debug the software of the connected microcontroller, connect MODE pin to 3.3V/5V and the watchdog is switched off. 5 4986G–AUTO–09/09 3.13 TM Input Pin The TM pin is used for final production measurements at Atmel®. In normal application, it has to be always connected to GND. 3.14 KL_15 Pin The KL_15 pin is a high-voltage input used to wake up the device from Sleep or Silent Mode. It is an edge sensitive pin (low-to-high transition). It is usually connected to ignition to generate a local wake-up in the application when the ignition is switched on. Although KL_15 pin is at high voltage (VBatt), it is possible to switch the IC into Sleep or Silent Mode. Connect the KL_15 pin directly to GND if you do not need it. A debounce timer with a typical Tdb Kl_15 of 160 µs is implemented. The input voltage threshold can be adjusted by varying the external resistor due to the input current IKL_15. To protect this pin against voltage transients, a serial resistor of 47 kΩ and a ceramic capacitor of 100 nF are recommended. With this RC combination you can increase the wake-up time TwKL_15 and, therefore, the sensitivity against transients on the ignition Kl.15. You can also increase the wake-up time using external capacitors with higher values. 3.15 INH Output Pin The INH Output pin is used to switch an external voltage regulator on during Normal or Fail-safe Mode. The INH pin is switched off in Sleep or Silent Mode. It is possible to switch off the external 1 kΩ master resistor via the INH pin for master node applications. The INH pin is switched off during VCC undervoltage reset. 3.16 Reset Output Pin (NRES) The Reset Output pin, an open drain output, switches to low during VCC undervoltage or a watchdog failure. 3.17 WD_OSC Output Pin The WD_OSC Output pin provides a typical voltage of 1.2V, which supplies an external resistor with values between 34 kΩ and 120 kΩ to adjust the watchdog oscillator time. 3.18 NTRIG Input Pin The NTRIG Input pin is the trigger input for the window watchdog. A pull-up resistor is implemented. A negative edge triggers the watchdog. The trigger signal (low) must exceed a minimum time ttrigmin to generate a watchdog trigger. 3.19 Wake-up Events from Sleep or Silent Mode • LIN-bus • WAKE pin • EN pin • KL_15 6 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 4. Modes of Operation Figure 4-1. Modes of Operation a: VS > 5V Unpowered Mode VBatt = 0V b b: VS < 4V c: Bus wake-up event d: Wake up from WAKE or KL_15 pin a e: NRES switches to low b Fail-safe Mode VCC: 3.3V/5V/50 mA with undervoltage monitoring Communication: OFF Watchdog: ON b e EN = 1 b c+d+e EN = 1 c+d Go to silent command EN = 0 Silent Mode TXD = 1 VCC: 3.3V/5V/50 mA with undervoltage monitoring Communication: OFF Watchdog: OFF Local wake-up event Normal Mode EN = 1 VCC: 3.3V/5V/50 mA with undervoltage monitoring Go to sleep command EN = 0 Communication: ON Watchdog: ON Sleep Mode TXD = 0 Table 4-1. VCC: switched off Communication: OFF Watchdog: OFF Table of Modes Mode of Operation Transceiver VCC Fail-safe Off 3.3V/5V On 1.23V On Normal On 3.3V/5V On 1.23V On LIN depending TXD depending Silent Off 3.3V/5V Off 0V Off High Recessive Sleep Off 0V Off 0V Off 0V Recessive Watchdog WD_OSC INH RXD LIN High, Recessive except after wake-up 7 4986G–AUTO–09/09 4.1 Normal Mode This is the normal transmitting and receiving mode of the LIN Interface in accordance with the LIN specification LIN 2.x. The voltage regulator is active and can source up to 50 mA. The undervoltage detection is activated. The watchdog needs a trigger signal from NTRIG to avoid resets at NRES. If NRES is switched to low, the IC changes its state to Fail-safe Mode. 4.2 Silent Mode A falling edge at EN when TXD is high switches the IC into Silent Mode. The TXD Signal has to be logic high during the Mode Select window (see Figure 4-2 on page 8). The transmission path is disabled in Silent Mode. The overall supply current from V Batt is a combination of the IVSsi = 57 µA plus the VCC regulator output current IVCC. The 3.3V/5V regulator with 2% tolerance can source up to 50 mA. The internal slave termination between the LIN pin and the VS pin is disabled in Silent Mode, only a weak pull-up current (typically 10 µA) between the LIN pin and the VS pin is present. Silent Mode can be activated independently from the actual level on the LIN, WAKE, or KL_15 pins. If an undervoltage condition occurs, NRES is switched to low, and the IC changes its state to Fail-safe Mode. A voltage less than the LIN Pre_Wake detection VLINL at the LIN pin activates the internal LIN receiver and switches on the internal slave termination between the LIN pin and the VS pin. Figure 4-2. Switch to Silent Mode Normal Mode Silent Mode EN TXD Mode select window td = 3.2 µs NRES VCC Delay time silent mode td_silent = maximum 20 µs LIN LIN switches directly to recessive mode 8 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 A falling edge at the LIN pin followed by a dominant bus level maintained for a certain time period (tbus) and the following rising edge at the LIN pin (see Figure 4-3 on page 9) results in a remote wake-up request. The device switches from Silent Mode to Fail-safe Mode. The remote wake-up request is indicated by a low level at the RXD pin to interrupt the microcontroller (see Figure 4-3 on page 9). EN high can be used to switch directly to Normal Mode. Figure 4-3. LIN Wake Up from Silent Mode Bus wake-up filtering time tbus Fail-safe mode Normal mode LIN bus Node in silent mode RXD High Low High TXD Watchdog VCC voltage regulator Watchdog off Start watchdog lead time td Silent mode 3.3V/5V/50 mA Fail safe mode 3.3V/5V/50 mA Normal mode EN High EN NRES 4.3 Undervoltage detection active Sleep Mode A falling edge at EN when TXD is low switches the IC into Sleep Mode. The TXD Signal has to be logic low during the Mode Select window (Figure 4-4 on page 10). In order to avoid any influence to the LIN-pin during switching into sleep mode it is possible to switch the EN up to 3.2 µs earlier to LOW than the TXD. Therefore, the best and easiest way are two falling edges at TXD and EN at the same time.The transmission path is disabled in Sleep Mode. The supply current IVSsleep from VBatt is typically 10 µA. 9 4986G–AUTO–09/09 The VCC regulator is switched off. NRES and RXD are low. The internal slave termination between the LIN pin and VS pin is disabled, only a weak pull-up current (typically 10 µA) between the LIN pin and the VS pin is present. Sleep Mode can be activated independently from the current level on the LIN, WAKE, or KL_15 pin. A voltage less than the LIN Pre_Wake detection VLINL at the LIN pin activates the internal LIN receiver and switches on the internal slave termination between the LIN pin and the VS pin. A falling edge at the LIN pin followed by a dominant bus level maintained for a certain time period (tbus) and a following rising edge at pin LIN results in a remote wake-up request. The device switches from Sleep Mode to Fail-safe Mode. The VCC regulator is activated, and the remote wake-up request is indicated by a low level at the RXD pin to interrupt the microcontroller (see Figure 4-5 on page 11). EN high can be used to switch directly from Sleep/Silent to Fail-safe Mode. If EN is still high after VCC ramp up and undervoltage reset time, the IC switches to the Normal Mode. Figure 4-4. Switch to Sleep Mode Normal Mode Sleep Mode EN Mode select window TXD td = 3.2 µs NRES VCC Delay time sleep mode td_sleep = maximum 20 µs LIN LIN switches directly to recessive mode 4.4 Fail-safe Mode The device automatically switches to Fail-safe Mode at system power-up. The voltage regulator is switched on (VCC = 3.3V/5V/2%/50 mA) (see Figure 5-1 on page 14). The NRES output switches to low for tres = 4 ms and gives a reset to the microcontroller. LIN communication is switched off. The IC stays in this mode until EN is switched to high. The IC then changes to Normal Mode. A power down of VBatt (VS < 4V) during Silent or Sleep Mode switches the IC into Fail-safe Mode after power up. A low at NRES switches into Fail-safe Mode directly. During Fail-safe Mode the TXD pin is an output and signals the last wake-up source. 10 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 4.5 Unpowered Mode If you connect battery voltage to the application circuit, the voltage at the VS pin increases according to the block capacitor (see Figure 5-1 on page 14). After VS is higher than the VS undervoltage threshold VSth, the IC mode changes from Unpowered Mode to Fail-safe Mode. The VCC output voltage reaches its nominal value after tVCC. This time, tVCC, depends on the VCC capacitor and the load. The NRES is low for the reset time delay treset . During this time, treset, no mode change is possible. Figure 4-5. LIN Wake Up from Sleep Mode Bus wake-up filtering time tbus Fail-safe Mode Low or floating Low Normal Mode LIN bus RXD TXD VCC voltage regulator On state Off state Regulator wake-up time EN High EN Reset time NRES Floating Microcontroller start-up time delay Watchdog Watchdog off Start watchdog lead time td 11 4986G–AUTO–09/09 5. Wake-up Scenarios from Silent or Sleep Mode 5.1 Remote Wake-up via Dominant Bus State A voltage less than the LIN Pre_Wake detection VLINL at the LIN pin activates the internal LIN receiver. A falling edge at the LIN pin followed by a dominant bus level VBUSdom maintained for a certain time period (tBUS) and a rising edge at pin LIN result in a remote wake-up request. The device switches from Silent or Sleep Mode to Fail-safe Mode. The VCC voltage regulator is/remains activated, the INH pin is switched to high, and the remote wake-up request is indicated by a low level at the RXD pin to generate an interrupt for the microcontroller. A low level at the LIN pin in the Normal Mode starts the bus wake-up filtering time, and if the IC is switched to Silent or Sleep Mode, it will receive a wake-up after a positive edge at the LIN pin. 5.2 Local Wake-up via Pin WAKE A falling edge at the WAKE pin followed by a low level maintained for a certain time period (tWAKE) results in a local wake-up request. The device switches to Fail-safe Mode. The local wake-up request is indicated by a low level at the RXD pin to generate an interrupt in the microcontroller and a strong pull down at TXD. When the Wake pin is low, it is possible to switch to Silent or Sleep Mode via pin EN. In this case, the wake-up signal has to be switched to high > 10 µs before the negative edge at WAKE starts a new local wake-up request. 5.3 Local Wake-up via Pin KL_15 A positive edge at pin KL_15 followed by a high voltage level for a certain time period (> tKL_15) results in a local wake-up request. The device switches into the Fail-safe Mode. The extra long wake-up time ensures that no transients at KL_15 create a wake up. The local wake-up request is indicated by a low level at the RXD pin to generate an interrupt for the microcontroller and a strong pull down at TXD. During high-level voltage at pin KL_15, it is possible to switch to Silent or Sleep Mode via pin EN. In this case, the wake-up signal has to be switched to low > 250 µs before the positive edge at KL_15 starts a new local wake-up request. With external RC combination, the time is even longer. 5.4 Wake-up Source Recognition The device can distinguish between a local wake-up request (Wake or KL_15 pins) and a remote wake-up request (dominant LIN bus state). The wake-up source can be read on the TXD pin in Fail-safe Mode. A high level indicates a remote wake-up request (weak pull up at the TXD pin); a low level indicates a local wake-up request (strong pull down at the TXD pin). The wake-up request flag (signalled on the RXD pin), as well as the wake-up source flag (signalled on the TXD pin), is immediately reset if the microcontroller sets the EN pin to high (see Figure 4-2 on page 8 and Figure 4-3 on page 9) and the IC is in Normal Mode. The last wake-up source flag is stored and signalled in Fail-safe Mode at the TXD pin. 12 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 5.5 Fail-safe Features • During a short-circuit at LIN to VBattery, the output limits the output current to IBUS_lim. Due to the power dissipation, the chip temperature exceeds TLINoff, and the LIN output is switched off. The chip cools down and after a hysteresis of Thys, switches the output on again. RXD stays on high because LIN is high. During LIN overtemperature switch-off, the VCC regulator works independently. • During a short-circuit from LIN to GND the IC can be switched into Sleep or Silent Mode. If the short-circuit disappears, the IC starts with a remote wake-up. • The reverse current is very low < 2 µA at the LIN pin during loss of VBatt. This is optimal behavior for bus systems where some slave nodes are supplied from battery or ignition. • During a short circuit at VCC, the output limits the output current to IVCClim. Because of undervoltage, NRES switches to low and sends a reset to the microcontroller. The IC switches into Fail-safe Mode. If the chip temperature exceeds the value TVCCoff, the VCC output switches off. The chip cools down and after a hysteresis of Thys, switches the output on again. Because of the Fail-safe Mode, the VCC voltage will switch on again although EN is switched off from the microcontroller. The microcontroller can start with its normal operation. • EN pin provides a pull-down resistor to force the transceiver into recessive mode if EN is disconnected. • RXD pin is set floating if VBatt is disconnected. • TXD pin provides a pull-up resistor to force the transceiver into recessive mode if TXD is disconnected. • If TXD is short-circuited to GND, it is possible to switch to Sleep Mode via ENABLE after tdom > 20 ms (only for ATA6622/ATA6624). • If the WD_OSC pin has a short-circuit to GND or the resistor is disconnected, the watchdog runs with an internal oscillator and guarantees a reset after the second NTRIG signal at the latest. 5.6 Voltage Regulator The voltage regulator needs an external capacitor for compensation and for smoothing the disturbances from the microcontroller. It is recommended to use an electrolythic capacitor with C > 1.8 µF and a ceramic capacitor with C = 100 nF. The values of these capacitors can be varied by the customer, depending on the application. The main power dissipation of the IC is created from the VCC output current IVCC , which is needed for the application. In Figure 5-2 on page 14 the safe operating area of the ATA6622/ATA6624/ATA6626 is shown. 13 4986G–AUTO–09/09 Figure 5-1. VCC Voltage Regulator: Ramp-up and Undervoltage Detection VS 12V 5.5V/3.8V t VCC 5V/3.3V Vthun TVCC Tres_f TReset t NRES 5V/3.3V t Figure 5-2. Power Dissipation: Safe Operating Area versus VCC Output Current and Supply Voltage VS at Different Ambient Temperatures Due to Rthja = 35 K/W 60 Tamb = 105°C 50 IVCC (mA) Tamb = 125°C 40 30 20 10 0 3 5 7 9 11 13 15 17 19 VS (V) For programming purposes of the microcontroller it is potentially necessary to supply the VCC output via an external power supply while the VS Pin of the system basis chip is disconnected. This behavior is no problem for the system basis chip. 14 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 6. Watchdog The watchdog anticipates a trigger signal from the microcontroller at the NTRIG (negative edge) input within a time window of T w d . The trigger signal must exceed a minimum time ttrigmin > 200 ns. If a triggering signal is not received, a reset signal will be generated at output NRES. The timing basis of the watchdog is provided by the internal oscillator. Its time period, Tosc, is adjustable via the external resistor Rwd_osc (34 kΩ to 120 kΩ). During Silent or Sleep Mode the watchdog is switched off to reduce current consumption. The minimum time for the first watchdog pulse is required after the undervoltage reset at NRES disappears. It is defined as lead time td. After wake up from Sleep or Silent Mode, the lead time td starts with the negative edge of the RXD output. 6.1 Typical Timing Sequence with RWD_OSC = 51 kΩ The trigger signal T wd is adjustable between 20 ms and 64 ms using the external resistor RWD_OSC. For example, with an external resistor of RWD_OSC = 51 kΩ ±1%, the typical parameters of the watchdog are as follows: tosc = 0.405 × RWD_OSC – 0.0004 × (RWD_OSC)2 (RWD_OSC in kΩ; tosc in µs) tOSC = 19.6 µs due to 51 kΩ td = 7895 × 19.6 µs = 155 ms t1 = 1053 × 19.6 µs = 20.6 ms t2 = 1105 × 19.6 µs = 21.6 ms tnres = constant = 4 ms After ramping up the battery voltage, the 3.3V/5V regulator is switched on. The reset output NRES stays low for the time treset (typically 4 ms), then it switches to high, and the watchdog waits for the trigger sequence from the microcontroller. The lead time, td, follows the reset and is td = 155 ms. In this time, the first watchdog pulse from the microcontroller is required. If the trigger pulse NTRIG occurs during this time, the time t1 starts immediately. If no trigger signal occurs during the time td, a watchdog reset with tNRES = 4 ms will reset the microcontroller after td = 155 ms. The times t1 and t2 have a fixed relationship between each other. A triggering signal from the microcontroller is anticipated within the time frame of t2 = 21.6 ms. To avoid false triggering from glitches, the trigger pulse must be longer than tTRIG,min > 200 ns. This slope serves to restart the watchdog sequence. If the triggering signal fails in this open window t2, the NRES output will be drawn to ground. A triggering signal during the closed window t1 immediately switches NRES to low. 15 4986G–AUTO–09/09 Figure 6-1. Timing Sequence with RWD_OSC = 51 kΩ VCC 3.3V/5V Undervoltage Reset NRES Watchdog Reset tnres = 4 ms treset = 4 ms td = 155 ms t1 t1 = 20.6 ms t2 t2 = 21 ms twd NTRIG ttrig > 200 ns 6.2 Worst Case Calculation with RWD_OSC = 51 kΩ The internal oscillator has a tolerance of 20%. This means that t1 and t2 can also vary by 20%. The worst case calculation for the watchdog period twd is calculated as follows. The ideal watchdog time twd is between the maximum t1 and the minimum t1 plus the minimum t2. t1,min = 0.8 × t1 = 16.5 ms, t1,max = 1.2 × t1 = 24.8 ms t2,min = 0.8 × t2 = 17.3 ms, t2,max = 1.2 × t2 = 26 ms twdmax = t1min + t2min = 16.5 ms + 17.3 ms = 33.8 ms twdmin = t1max = 24.8 ms twd = 29.3 ms ±4.5 ms (±15%) A microcontroller with an oscillator tolerance of ±15% is sufficient to supply the trigger inputs correctly. Table 6-1. 16 Typical Watchdog Timings RWD_OSC kΩ Oscillator Period tosc/µs Lead Time td/ms Closed Window t1/ms Open Window t2/ms Trigger Period from Microcontroller Reset Time twd/ms tnres/ms 34 13.3 105 14.0 14.7 19.9 4 51 19.61 154.8 20.64 21.67 29.32 4 91 33.54 264.80 35.32 37.06 50.14 4 120 42.84 338.22 45.11 47.34 64.05 4 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 7. Absolute Maximum Ratings Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or any other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Parameters Symbol Min. Supply voltage VS VS –0.3 Pulse time ≤ 500 ms; Ta = 25°C Output current IVCC ≤ 50 mA Pulse time ≤ 2 min; Ta = 25°C Output current IVCC ≤ 50 mA Max. Unit +40 V VS +40 V VS 27 V –1 –150 +40 +100 V V INH - DC voltage –0.3 VS + 0.3 V LIN - DC voltage –27 +40 V Logic pins (RxD, TxD, EN, NRES, NTRIG, WD_OSC, MODE, TM) –0.3 +5.5 WAKE (with 33 kΩ serial resistor) KL_15 (with 50 kΩ/100 nF) DC voltage Transient voltage due to ISO7637 (coupling 1 nF) Output current NRES Typ. INRES PVCC DC voltage VCC DC voltage –0.3 –0.3 ESD according to IBEE LIN EMC Test Spec. 1.0 following IEC 61000-4-2 - Pin VS, LIN to GND - Pin WAKE (33 kΩ serial resistor) to GND V +2 mA +5.5 +6.5 V V ±6 ±5 KV KV ESD HBM following STM5.1 with 1.5 kΩ 100 pF - Pin VS, LIN, WAKE to GND ±8 KV HBM ESD ANSI/ESD-STM5.1 JESD22-A114 AEC-Q100 (002) ±3 KV CDM ESD STM 5.3.1 ±750 V Machine Model ESD AEC-Q100-RevF(003) ±200 V Junction temperature Tj –40 +150 °C Storage temperature Ts –55 +150 °C Symbol Min. Max. Unit 10 K/W 8. Thermal Characteristics Parameters Thermal resistance junction to heat slug Rthjc Thermal resistance junction to ambient, where heat slug is soldered to PCB Rthja Typ. 35 K/W Thermal shutdown of VCC regulator 150 165 170 °C Thermal shutdown of LIN output 150 165 170 °C Thermal shutdown hysteresis 10 °C 17 4986G–AUTO–09/09 9. Electrical Characteristics 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. 1 1.1 1.2 1.3 Parameters Test Conditions Pin Symbol Min. VS VS 5 Sleep Mode VLIN > VS – 0.5V VS < 14V (Tj = 25°C) VS IVSsleep 3 Sleep Mode VLIN > VS – 0.5V VS < 14V (Tj = 125°C) VS IVSsleep Bus recessive VS < 14V (Tj = 25°C) Without load at VCC VS Bus recessive VS < 14V (Tj = 125°C) Without load at VCC Typ. Max. Unit Type* 27 V A 10 14 µA A 5 11 16 µA A IVSsi 47 57 67 µA A VS IVSsi 56 66 76 µA A VS Pin Nominal DC voltage range Supply current in Sleep Mode Supply current in Silent Mode 1.4 Bus recessive Supply current in Normal VS < 14V Mode Without load at VCC VS IVSrec 0.3 0.8 mA A 1.5 Bus dominant Supply current in Normal VS < 14V Mode VCC load current 50 mA VS IVSdom 50 53 mA A 1.6 Supply current in Fail-safe Mode VS IVSfail 250 550 µA A 1.7 VS undervoltage threshold VS VSth 4.0 5 V A 1.8 VS undervoltage threshold hysteresis VS VSth_hys V A RXD IRXD 8 mA A 0.4 V A 7 kΩ A 2 Bus recessive VS < 14V Without load at VCC 4.5 0.2 RXD Output Pin Normal Mode VLIN = 0V VRXD = 0.4V 2.1 Low-level output sink current 2.2 Low-level output voltage IRXD = 1 mA RXD VRXDL 2.3 Internal resistor to VCC RXD RRXD 3 3 TXD Input/Output Pin 3.1 Low-level voltage input TXD VTXDL –0.3 +0.8 V A 3.2 High-level voltage input TXD VTXDH 2 VCC + 0.3V V A 3.3 Pull-up resistor VTXD = 0V TXD RTXD 125 400 kΩ A 3.4 High-level leakage current VTXD = VCC TXD ITXD –3 +3 µA A 1.3 2.5 5 250 *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 18 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters 3.5 Fail-safe Mode Low-level output sink VLIN = VS current at local wake-up VWAKE = 0V request VTXD = 0.4V 4 4.1 Pin Symbol Min. Typ. Max. Unit Type* TXD ITXDwake 2 2.5 8 mA A EN VENL –0.3 +0.8 V A VCC + 0.3V V A 200 kΩ A EN Input Pin Low-level voltage input 4.2 High-level voltage input 4.3 Pull-down resistor 4.4 Low-level input current 5 Test Conditions EN VENH 2 VEN = VCC EN REN 50 VEN = 0V EN IEN –3 +3 µA A 125 NTRIG Watchdog Input Pin 5.1 Low-level voltage input NTRIG VNTRIGL –0.3 +0.8 V A 5.2 High-level voltage input NTRIG VNTRIGH 2 VCC + 0.3V V A 5.3 Pull-up resistor VNTRIG = 0V NTRIG RNTRIG 125 400 kΩ A 5.4 High-level leakage current VNTRIG = VCC NTRIG INTRIG –3 +3 µA A 6 250 Mode Input Pin 6.1 Low-level voltage input MODE VMODEL –0.3 +0.8 V A 6.2 High-level voltage input MODE VMODEH 2 VCC + 0.3V V A 6.3 Leakage current MODE IMODE –3 +3 µA A 7 INH Output Pin INH VINHH VS – 0.8 VS V A INH RINH 50 Ω A INH IINHL +3 µA A 7.1 High-level voltage 7.2 Switch-on resistance between VS and INH 7.3 Leakage current 8 VMODE = VCC or VMODE = 0V IINH = –15 mA Sleep Mode VINH = 0V/27V, VS = 27V 30 –3 LIN Bus Driver: Bus Load Conditions: Load 1 (Small): 1 nF, 1 kΩ; Load 2 (Large): 10 nF, 500Ω; Internal Pull-up RRXD = 5 kΩ; CRXD = 20 pF Load 3 (Medium): 6.8 nF, 660Ω, Characterized on Samples 10.6 and 10.7 Specifies the Timing Parameters for Proper Operation at 20 kBit/s and 10.8 and 10.9 at 10.4 kBit/s 8.1 Driver recessive output voltage Load1/Load2 LIN VBUSrec 8.2 Driver dominant voltage VVS = 7V Rload = 500 Ω LIN 8.3 Driver dominant voltage VVS = 18V Rload = 500 Ω 8.4 Driver dominant voltage 8.5 Driver dominant voltage 0.9 × VS VS V A V_LoSUP 1.2 V A LIN V_HiSUP 2 V A VVS = 7.0V Rload = 1000 Ω LIN V_LoSUP_1k 0.6 V A VVS = 18V Rload = 1000 Ω LIN V_HiSUP_1k 0.8 V A *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 19 4986G–AUTO–09/09 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters Test Conditions Pin Symbol Min. Typ. Max. Unit Type* 8.6 Pull-up resistor to VS The serial diode is mandatory LIN RLIN 20 30 60 kΩ A 8.7 Voltage drop at the serial In pull-up path with Rslave diodes ISerDiode = 10 mA LIN VSerDiode 0.4 1.0 V D 8.8 LIN current limitation VBUS = VBatt_max LIN IBUS_LIM 40 120 200 mA A 8.9 Input leakage current at the receiver including pull-up resistor as specified Input leakage current Driver off VBUS = 0V VBatt = 12V LIN IBUS_PAS_dom –1 –0.35 mA A 8.10 Leakage current LIN recessive Driver off 8V < VBatt < 18V 8V < VBUS < 18V VBUS ≥ VBatt LIN IBUS_PAS_rec 8.11 Leakage current when control unit disconnected from ground. GNDDevice = VS VBatt = 12V Loss of local ground 0V < VBUS < 18V must not affect communication in the residual network. LIN IBUS_NO_gnd 8.12 Leakage current at a disconnected battery. Node has to sustain the VBatt disconnected current that can flow VSUP_Device = GND under this condition. Bus 0V < VBUS < 18V must remain operational under this condition. LIN IBUS_NO_bat LIN VBUS_CNT –10 10 20 µA A +0.5 +10 µA A 0.1 2 µA A 0.5 × VS 0.525 × VS V A 0.4 × VS V A V A 0.175 × VS V A 9 LIN Bus Receiver 9.1 Center of receiver threshold 9.2 Receiver dominant state VEN = 5V LIN VBUSdom 9.3 Receiver recessive state VEN = 5V LIN VBUSrec 0.6 × VS 9.4 Receiver input hysteresis LIN VBUShys 0.028 × VS 9.5 Pre_Wake detection LIN High-level input voltage LIN VLINH VS – 2V VS + 0.3V V A 9.6 Pre_Wake detection LIN Activates the LIN receiver Low-level input voltage LIN VLINL –27 VS – 3.3V V A 10 Internal Timers VBUS_CNT = (Vth_dom + Vth_rec)/2 Vhys = Vth_rec – Vth_dom 0.475 × VS 0.1 × VS 10.1 Dominant time for wake-up via LIN bus VLIN = 0V LIN tbus 30 90 150 µs A 10.2 Time delay for mode change from Fail-safe into Normal Mode via EN pin VEN = 5V EN tnorm 5 15 20 µs A *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 20 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters Pin Symbol Min. Typ. Max. Unit Type* 10.3 Time delay for mode change from Normal V = 0V Mode to Sleep Mode via EN EN pin EN tsleep 2 7 12 µs A 10.4 TXD dominant time-out = 0V V time (ATA6626 disabled) TXD TXD tdom 6 13 20 ms A 10.5 Time delay for mode change from Silent V = 5V Mode into Normal Mode EN via EN EN ts_n 5 15 40 µs A Duty cycle 1 THRec(max) = 0.744 × VS THDom(max) = 0.581 × VS VS = 7.0V to 18V tBit = 50 µs D1 = tbus_rec(min)/(2 × tBit) LIN D1 0.396 Duty cycle 2 THRec(min) = 0.422 × VS THDom(min) = 0.284 × VS VS = 7.6V to 18V tBit = 50 µs D2 = tbus_rec(max)/(2 × tBit) LIN D2 Duty cycle 3 THRec(max) = 0.778 × VS THDom(max) = 0.616 × VS VS = 7.0V to 18V tBit = 96 µs D3 = tbus_rec(min)/(2 × tBit) LIN D3 10.9 Duty cycle 4 THRec(min) = 0.389 × VS THDom(min) = 0.251 × VS VS = 7.6V to 18V tBit = 96 µs D4 = tbus_rec(max)/(2 × tBit) LIN D4 10.10 Slope time falling and rising edge at LIN VS = 7.0V to 18V LIN tSLOPE_fall tSLOPE_rise 10.6 10.7 10.8 11 Test Conditions 0.581 A 0.417 A 0.590 3.5 A 22.5 µs A 6 µs A +2 µs A Receiver Electrical AC Parameters of the LIN Physical Layer LIN Receiver, RXD Load Conditions: CRXD = 20 pF 11.1 Propagation delay of receiver (Figure 9-1 on page 24) 11.2 Symmetry of receiver VS = 7.0V to 18V propagation delay rising =t –t t edge minus falling edge rx_sym rx_pdr rx_pdf 12 A VS = 7.0V to 18V trx_pd = max(trx_pdr , trx_pdf) RXD trx_pd RXD trx_sym NRES VNRESL 0.2 0.14 V V A 0.2 V A 6 ms A –2 NRES Open Drain Output Pin 12.1 VS ≥ 5.5V Low-level output voltage INRES = 1 mA INRES = 250 µA 12.2 Low-level output low 10 kΩ to VCC VCC = 0V NRES VNRESLL 12.3 Undervoltage reset time VS ≥ 5.5V CNRES = 20 pF NRES treset 2 4 *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 21 4986G–AUTO–09/09 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters Test Conditions 12.4 Reset debounce time for VS ≥ 5.5V falling edge CNRES = 20 pF Pin Symbol Min. NRES tres_f 1.5 WD_ OSC VWD_OSC 1.13 WD_ OSC ROSC 34 Typ. Max. Unit Type* 10 µs A 1.33 V A 120 kΩ A 13 Watchdog Oscillator 13.1 Voltage at WD_OSC in Normal Mode 13.2 Possible values of resistor 13.3 Oscillator period ROSC = 34 kΩ tOSC 10.65 13.3 15.97 µs A 13.4 Oscillator period ROSC = 51 kΩ tOSC 15.68 19.6 23.52 µs A 13.5 Oscillator period ROSC = 91 kΩ tOSC 26.83 33.5 40.24 µs A 13.6 Oscillator period ROSC = 120 kΩ tOSC 34.2 42.8 51.4 µs A 14 IWD_OSC = –200 µA VVS ≥ 4V 1.23 Watchdog Timing Relative to tOSC 14.1 Watchdog lead time after Reset td 7895 cycles A 14.2 Watchdog closed window t1 1053 cycles A 14.3 Watchdog open window t2 1105 cycles A 14.4 Watchdog reset time NRES 4.8 ms A 15 NRES tnres 3.2 4 KL_15 VKL_15H 4 VS + 0.3V V A KL_15 VKL_15L –1 +2 V A 50 65 µA A KL_15 Pin Positive edge initializes a wake-up 15.1 High-level input voltage RV = 47 kΩ 15.2 Low-level input voltage RV = 47 kΩ 15.3 KL_15 pull-down current VS < 27V VKL_15 = 27V KL_15 IKL_15 15.4 Internal debounce time Without external capacitor KL_15 TdbKL_15 80 160 250 µs A 15.5 KL_15 wake-up time RV = 47 kΩ, C = 100 nF KL_15 TwKL_15 0.4 2 4.5 ms C WAKE VWAKEH VS – 1V VS + 0.3V V A VS – 3.3V V A µA A +5 µA A 150 µs A 16 WAKE Pin 16.1 High-level input voltage 16.2 Low-level input voltage Initializes a wake-up signal WAKE VWAKEL –1 16.3 WAKE pull-up current VS < 27V VWAKE = 0V WAKE IWAKE –30 16.4 High-level leakage current VS = 27V VWAKE = 27V WAKE IWAKEL –5 16.5 Time of low pulse for wake-up via WAKE pin VWAKE = 0V WAKE IWAKEL 30 –10 70 *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 22 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters Test Conditions 17 VCC Voltage Regulator ATA6622, PVCC = VCC Pin Symbol Min. Typ. Max. Unit Type* 17.1 Output voltage VCC 4V < VS < 18V (0 mA to 50 mA) VCC VCCnor 3.234 3.366 V A 17.2 Output voltage VCC at low VS 3V < VS < 4V VCC VCClow VS – VD 3.366 V A 17.3 Regulator drop voltage VS > 3V IVCC = –15 mA VS, VCC VD1 200 mV A 17.4 Regulator drop voltage VS > 3V IVCC = –50 mA VS, VCC VD2 500 700 mV A 17.5 Line regulation 4V < VS < 18V VCC VCCline 1 % A 17.6 Load regulation 5 mA < IVCC < 50 mA VCC VCCload 0.5 2 % A 17.7 Power supply ripple rejection 10 Hz to 100 kHz CVCC = 10 µF VS = 14V, IVCC = –15 mA VCC dB A 17.8 Output current limitation VS > 4V 17.9 Load capacity 17.10 50 VCC IVCClim –240 –160 mA A 0.2Ω < ESR < 5Ω at 100 kHz VCC Cload 1.8 10 µF D VCC undervoltage threshold Referred to VCC VS > 4V VCC VthunN 2.8 V A 17.11 Hysteresis of undervoltage threshold Referred to VCC VS > 4V VCC Vhysthun 150 mV A 17.12 Ramp-up time VS > 4V to CVCC = 2.2 µF VCC = 3.3V Iload = –5 mA at VCC VCC TVCC 100 250 µs A 18 3.2 VCC Voltage Regulator ATA6624/ATA6626, PVCC = VCC 18.1 Output voltage VCC 5.5V < VS < 18V (0 mA to 50 mA) VCC VCCnor 4.9 5.1 V A 18.2 Output voltage VCC at low VS 4V < VS < 5.5V VCC VCClow VS – VD 5.1 V A 18.3 Regulator drop voltage VS > 4V IVCC = –20 mA VS, VCC VD1 250 mV A 18.4 Regulator drop voltage VS > 4V IVCC = –50 mA VS, VCC VD2 600 mV A 18.5 Regulator drop voltage VS > 3.3V IVCC = –15 mA VS, VCC VD3 200 mV A 18.6 Line regulation 5.5V < VS < 18V VCC VCCline 1 % A 18.7 Load regulation 5 mA < IVCC < 50 mA VCC VCCload 2 % A 18.8 Power supply ripple rejection 10 Hz to 100 kHz CVCC = 10 µF VS = 14V, IVCC = –15 mA VCC dB A 18.9 Output current limitation VS > 5.5V 18.10 Load capacity 0.2Ω < ESR < 5Ω at 100 kHz 400 0.5 50 VCC IVCClim –240 –130 mA A VCC VthunN 1.8 10 µF D *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter 23 4986G–AUTO–09/09 9. Electrical Characteristics (Continued) 5V < VS < 27V, -40°C < Tj < 150°C, unless otherwise specified. All values refer to GND pins No. Parameters Test Conditions Pin Symbol Min. Typ. 18.11 VCC undervoltage threshold Referred to VCC VS > 5.5V VCC VthunN 4.2 18.12 Hysteresis of undervoltage threshold Referred to VCC VS > 5.5V VCC Vhysthun 250 18.13 Ramp-up time VS > 5.5V CVCC = 2.2 µF to VCC = 5V Iload = –5 mA at VCC VCC tVCC 130 Max. Unit Type* 4.8 V A mV A µs A 300 *) Type means: A = 100% tested, B = 100% correlation tested, C = Characterized on samples, D = Design parameter Figure 9-1. Definition of Bus Timing Characteristics tBit tBit tBit TXD (Input to transmitting node) tBus_dom(max) tBus_rec(min) Thresholds of receiving node1 THRec(max) VS (Transceiver supply of transmitting node) THDom(max) LIN Bus Signal Thresholds of receiving node2 THRec(min) THDom(min) tBus_dom(min) tBus_rec(max) RXD (Output of receiving node1) trx_pdf(1) trx_pdr(1) RXD (Output of receiving node2) trx_pdr(2) 24 trx_pdf(2) ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 Figure 9-2. Application Circuit Ignition KL15 VBattery KL30 22 µF + 100 nF 47 kΩ Master node pull-up KL_15 10 kΩ PVCC VS + VCC 100 nF 1 kΩ Debug 100 nF 10 µF 20 Microcontroller NTRIG 33 kΩ WAKE GND EN Wake switch 15 2 ATA6622/24/26 14 3 MLP 5 mm 5 mm 0.65 mm pitch 20 lead 13 4 12 5 11 6 NTRIG 16 7 8 9 MODE 10 kΩ TM WD_OSC NRES 51 kΩ TXD LIN sub bus 10 kΩ 17 10 RXD VCC 18 1 LIN EN 19 RXD 220 pF TXD GND RESET INH 25 4986G–AUTO–09/09 Figure 9-3. Application Circuit with External NPN Ignition KL15 VBattery KL30 22 µF + 100 nF MJD31C 47 kΩ Master node pull-up + 2.2 µF 10 kΩ PVCC VS VCC 3.3Ω + KL_15 100 nF 1 kΩ Debug 100 nF 10 µF 20 Microcontroller NTRIG 33 kΩ WAKE GND EN Wake switch 16 15 2 ATA6622/24/26 14 3 MLP 5 mm 5 mm 0.65 mm pitch 20 lead 13 4 12 5 11 6 NTRIG 7 8 9 MODE 10 kΩ TM WD_OSC NRES 51 kΩ TXD LIN sub bus 10 kΩ 17 10 RXD VCC 18 1 LIN EN 19 RXD 220 pF TXD GND RESET INH 26 ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 ATA6622/ATA6624/ATA6626 10. Ordering Information Extended Type Number Package Remarks ATA6622-PGPW QFN20 3.3V LIN system-basis-chip, Pb-free, 1.5k, taped and reeled ATA6624-PGPW QFN20 5V LIN system-basis-chip, Pb-free, 1.5k, taped and reeled ATA6622-PGQW QFN20 3.3V LIN system-basis-chip, Pb-free, 6k, taped and reeled ATA6624-PGQW QFN20 5V LIN system-basis-chip, Pb-free, 6k, taped and reeled ATA6626-PGQW QFN20 5V LIN system-basis-chip, Pb-free, 6k, taped and reeled 11. Package Information Package: VQFN_5 x 5_20L Exposed pad 3.1 x 3.1 Dimensions in mm Not indicated tolerances ±0.05 Bottom 0 0.05-0.05 3.1±0.15 Top 20 Pin 1 identification 16 20 1 15 1 5 11 5 10 0.2 5 6 0.65 nom. 0.9±0.1 0.6±0.1 2.6 Drawing-No.: 6.543-5129.01-4 Issue: 2; 09.02.07 0.28±0.07 technical drawings according to DIN specifications 27 4986G–AUTO–09/09 12. Revision History Please note that the following page numbers referred to in this section refer to the specific revision mentioned, not to this document. Revision No. History 4986G-AUTO-08/09 • complete datasheet: “LIN 2.0 specicfication” changed in “LIN 2.1 specicfication” • Figures changed: 1-1, 4-2, 4-3, 4-4, 4-5, 5-1, 9-2, 9-3 • Sections changed: 3.1, 3.6, 3.8, 3.9, 3.10, 3.14, 4.1, 4.2, 4,3, 5.1, 5.2, 5.3, 5.5, 5.6 • Features and Description changed • Table 4-1 changed • Abs. Max. Ratings table changed • Thermal Characteristics table inserted • El. Characteristics table changed 4986F-AUTO-05/08 • Section 3.15 “INH Output Pin” on page 6 changed • Section 5.5 “Fail-safe Features” on page 13 changed • Section 6.1 “Typical Timing Sequence with RWD_OSC = 51 kΩ” on page 15 changed • Section 8 “Electrical Characteristics” numbers 1.6 to 1.8 on page 18 changed 4986E-AUTO-02/08 • Figure 2-1 on page 3 renamed • Figure 6-1 “Timing Sequence with RWD_OSC = 51 kΩ” on page 16 changed • Figure 8-3 “Application Circuit with External NPN” on page 26 added 4986D-AUTO-10/07 • Section 9 “Ordering Information” on page 26 changed 4986C-AUTO-09/07 • • • • • 4986B-AUTO-06/07 28 Features changed Sections 4.2, 4.3, 4.4 and 4.5 changed Figures 4-2, 4-3, 4-4, 5-1, 5-2, 5-3, 5-6, 6-1 and 6-2 changed Section 7 “Absolute Maximum Ratings” changed” Section 8 “Electrical Characteristics”: numbers 17.9 and 18.9 changed • • • • • • • • • • • Put datasheet into a new template Part number ATA6626 added Features changed Description text changed Figure 1-1 “Block Diagram” changed Figure 2-1 “Pinning SO8 changed” Figure 4-3 “LIN Wake Up from Silent Mode” changed Figure 4-5 “LIN Wake Up from Sleep Mode” changed Sections 3.2, 3.4, 3.7, 3.8, 3.9, 3.10, 3.11, 3.12, 3.13 and 3.14 changed Sections 4.2, 4.3, 4.4, 4.5, 5.1, 5.2, 5.3, 5.5, 5.6, 6.1 and 6.2 changed Section 8 “Electrical Characteristics”: numbers 1.3, 3.5, 8.4, 12.1, 15.5, 17.9, 18 and 18.9 changed • Figure 8-2 “Application Circuit” changed • Section 9 “Ordering Information” changed • Section 10 “Package Information” changed ATA6622/ATA6624/ATA6626 4986G–AUTO–09/09 Headquarters International Atmel Corporation 2325 Orchard Parkway San Jose, CA 95131 USA Tel: 1(408) 441-0311 Fax: 1(408) 487-2600 Atmel Asia Room 1219 Chinachem Golden Plaza 77 Mody Road Tsimshatsui East Kowloon Hong Kong Tel: (852) 2721-9778 Fax: (852) 2722-1369 Atmel Europe Le Krebs 8, Rue Jean-Pierre Timbaud BP 309 78054 Saint-Quentin-en-Yvelines Cedex France Tel: (33) 1-30-60-70-00 Fax: (33) 1-30-60-71-11 Atmel Japan 9F, Tonetsu Shinkawa Bldg. 1-24-8 Shinkawa Chuo-ku, Tokyo 104-0033 Japan Tel: (81) 3-3523-3551 Fax: (81) 3-3523-7581 Technical Support [email protected] Sales Contact www.atmel.com/contacts Product Contact Web Site www.atmel.com Literature Requests www.atmel.com/literature Disclaimer: The information in this document is provided in connection with Atmel products. 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