DLA DSCC-VID-V62 09611-2009 MICROCIRCUIT DIGITAL CONTROLLER AREA NETWORK (CAN) TRANSCEIVER MONOLITHIC SILICON.pdf

1、 REVISIONS LTR DESCRIPTION DATE APPROVED Prepared in accordance with ASME Y14.24 Vendor item drawing REV PAGE REV PAGE 18 19 20 21 22 REV REV STATUS OF PAGES PAGE 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 PMIC N/A PREPARED BY RICK OFFICER DEFENSE SUPPLY CENTER COLUMBUS COLUMBUS, OHIO 43218-3990 Orig

2、inal date of drawing YY-MM-DD CHECKED BY RAJESH PITHADIA APPROVED BY ROBERT M. HEBER TITLE MICROCIRCUIT, DIGITAL, CONTROLLER AREA NETWORK (CAN) TRANSCEIVER, MONOLITHIC SILICON SIZE A CODE IDENT. NO. 16236 DWG NO. V62/09611 09-01-13 REV PAGE 1 OF 22 AMSC N/A 5962-V020-09 Provided by IHSNot for Resale

3、No reproduction or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 2 1. SCOPE 1.1 Scope. This drawing documents the general requirements of a high performance controller area network (CAN) transce

4、iver microcircuit, with an operating temperature range of -55C to +125C. 1.2 Vendor Item Drawing Administrative Control Number. The manufacturers PIN is the item of identification. The vendor item drawing establishes an administrative control number for identifying the item on the engineering docume

5、ntation: V62/09611 - 01 X E Drawing Device type Case outline Lead finish number (See 1.2.1) (See 1.2.2) (See 1.2.3) 1.2.1 Device type(s). Device type Generic Circuit function 01 SN65HVD233-EP Controller area network (CAN) transceiver 1.2.2 Case outline(s). The case outline(s) are as specified herein

6、. Outline letter Number of pins JEDEC PUB 95 Package style X 8 MS-012-AA Plastic surface mount 1.2.3 Lead finishes. The lead finishes are as specified below or other lead finishes as provided by the device manufacture: Finish designator Material A Hot solder dip B Tin-lead plate C Gold plate D Palla

7、dium E Gold flash palladium Z Other 1.3 Absolute maximum ratings. 1/ 2/ Supply voltage range ( VCC) . -0.3 V to 7.0 V Voltage range at any bus terminal (CANH or CANL) . -36 V to +36 V Voltage input range, transient pulse, CANH and CANL, through 100 (see figure 5) -100 V to +100 V Input voltage range

8、 ( VI) (D, R, RS, LBK) . -0.5 V to 7.0 V Receiver output current (IO) . -10 mA to 10 mA Electrostatic discharge (ESD): Human body model (HBM): 3/ CANH, CANL and GND . 16 kV All pins . 3 kV Charged device model (CDM): 4/ All pins 1 kV 1/ Stresses beyond those listed under “absolute maximum rating” ma

9、y cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect

10、 device reliability. 2/ All voltage values, except differential I/O bus voltages, are with respect to network ground terminal. 3/ Tested in accordance with JEDEC Standard 22, test method A114-A. 4/ Tested in accordance with JEDEC Standard 22, test method C101 Provided by IHSNot for ResaleNo reproduc

11、tion or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 3 1.3 Absolute maximum ratings - continued. 1/ 2/ Continuous total power dissipation See 1.5, dissipation rating table Operating junction te

12、mperature (TJ) +150C Storage temperature range (TSTG) -65C to 150C Lead temperature 1.6 mm from case for 10 seconds +260C Thermal resistance, junction to ambient (JA): 5/ Low K, no air flow . 185C/W 6/ High K, no air flow . 101C/W 7/ Thermal resistance, junction to board (JB): High K, no air flow 82

13、.8C/W 7/ Thermal resistance, junction to case (JC) . 26.5C/W Average power dissipation (PAVG) : With RL= 60 , RSat 0 V, input to D a 1 MHz 50% duty cycle square wave, VCCat 3.3 V and TA= +25C 36.4 mW Thermal shutdown junction temperature (TSD) 170C/W 1.4 Recommended operating conditions. 8/ Supply v

14、oltage range ( VCC): . 3.0 V to 3.6 V Voltage at any bus terminal (separately or common mode) -7.0 to 12.0 V High level input voltage, (VIH) D, LBK pins 2.0 V to 5.5 V Low level input voltage (VIL), D, LBK pins . 0 V to 0.8 V Differential input voltage, (VID) . -6.0 V to 6.0 V Resistance from RSto g

15、round . 0.0 V to 100 k Input voltage at RSfor standby 0.75 VCCto 5.5 V High level output current, (IOH): Driver -50 mA minimum Receiver . -10 mA minimum Low level output current, (IOL): Driver 50 mA maximum Receiver . 10 mA maximum Operating junction temperature (TJ) +150C Operating free-air tempera

16、ture range ( TA) -55C to +125C 9/ 1.5. Dissipation rating table. Case outline Circuit board TA 25C power rating Derating factor 10/ above TA= 25C TA= 85C power rating TA= 125C power rating X Low K 596.6 mW 5.7 mW/C 255.7 mW 28.4 mW High K 1076.9 mW 10.3 mW/C 461.5 mW 51.3 mW _ 5/ See manufacturers l

17、iterature number SZZA003 for an explanation of this parameter. 6/ JESD51-3 low effective thermal conductivity test board for leaded surface mount packages. 7/ JESD51-7 high effective thermal conductivity test board for leaded surface mount packages. 8/ Use of this product beyond the manufacturers de

18、sign rules or stated parameters is done at the users risk. The manufacturer and/or distributor maintain no responsibility or liability for product used beyond the stated limits. 9/ Maximum free air temperature operation is allowed as long as the device maximum junction temperature is not exceeded. 1

19、0/ This is the inverse of the junction to ambient thermal resistance when board mounted and with no air flow. Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611

20、 REV PAGE 4 2. APPLICABLE DOCUMENTS JEDEC PUB 95 Registered and Standard Outlines for Semiconductor Devices (Applications for copies should be addressed to the Electronic Industries Alliance, 2500 Wilson Boulevard, Arlington, VA 22201-3834 or online at http:/www.jedec.org) 3. REQUIREMENTS 3.1 Markin

21、g. Parts shall be permanently and legibly marked with the manufacturers part number as shown in 6.3 herein and as follows: A. Manufacturers name, CAGE code, or logo B. Pin 1 identifier C. ESDS identification (optional) 3.2 Unit container. The unit container shall be marked with the manufacturers par

22、t number and with items A and C (if applicable) above. 3.3 Electrical characteristics. The maximum and recommended operating conditions and electrical performance characteristics are as specified in 1.3, 1.4, and table I herein. 3.4 Design, construction, and physical dimension. The design, construct

23、ion, and physical dimensions are as specified herein. 3.5 Diagrams. 3.5.1 Case outline. The case outline shall be as shown in 1.2.2 and figure 1. 3.5.2 Terminal connections. The terminal connections shall be as shown in figure 2. 3.5.3 Functional tables. The functional tables shall be as shown in fi

24、gure 3. 3.5.4 Functional block diagram. The functional block diagram shall be as shown in figure 4. 3.5.5 Timing waveforms and test circuit. The timing waveforms and test circuit shall be as shown in figures 5 through 14. Provided by IHSNot for ResaleNo reproduction or networking permitted without l

25、icense from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 5 TABLE I. Electrical performance characteristics. 1/ Limits Test Symbol Conditions 2/Temperature, TADevice type Min Max Unit Driver electrical characteristics. Bus output voltag

26、e (Dominant) VO(D)CANH pin, D = 0 V, RS= 0 V, see figures 6 and 7 -55C to +125C 01 2.45 VCCV CANL pin, D = 0 V, RS= 0 V, see figures 6 and 7 0.5 1.25 Bus output voltage (Recessive) VOCANH pin, D = 3 V, RS= 0 V, see figures 6 and 7 +25C 01 2.3 typical V CANL pin, D = 3 V, RS= 0 V, see figures 6 and 7

27、 2.3 typical Differential output voltage VOD(D)D = 0 V, RS= 0 V, see figures 6 and 7 -55C to +125C 01 1.5 3 V (Dominant) D = 0 V, RS= 0 V, see figures 7 and 8 1.2 3 Differential output voltage VODD = 3 V, RS= 0 V, see figures 6 and 7 -55C to +125C 01 -120 12 mV (Recessive) D = 3 V, RS= 0 V, no load

28、-0.5 0.05 V Peak to peak common mode output voltage VOC(PP)VCC= 3.3 V, see figure 9 +25C 01 1 typical V High level input current IIHD, LBK pins, D = 2 V -55C to +125C 01 -30 30 A Low level input current IILD, LBK pins, D = 0.8 V -55C to +125C 01 -30 30 A Short circuit output current IOSVCANH= -7 V,

29、CANL open, see figure 10 -55C to +125C 01 -250 mA VCANH= 12 V, CANL open, see figure 10 1 VCANL= -7 V, CANH open, see figure 10 -1 VCANL= 12 V, CANH open, see figure 10 250 Output capacitance COSee receiver input capacitance See footnotes at end of table. Provided by IHSNot for ResaleNo reproduction

30、 or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 6 TABLE I. Electrical performance characteristics Continued. 1/ Limits Test Symbol Conditions 2/Temperature, TA Device type Min Max Unit Driver

31、electrical characteristics continued. RSinput current for standby IIRS(S)RS= 0.75 VCC-55C to +125C 01 -10 A Supply current ICCStandby, RS= VCC, D = VCC, LBK = 0 V -55C to +125C 01 600 A Dominant, no load, D = 0 V, LBK = 0 V, RS= 0 V 6 mA Recessive, no load, D = VCC, LBK = 0 V, RS= 0 V 6 mA Driver sw

32、itching characteristics. tPLHRS= 0 V, see figure 11 -55C to +125C 01 95 ns Propagation delay time, low to high level output RSwith 10 k to ground, see figure 11 125 RSwith 100 k to ground, see figure 11 870 tPHLRS= 0 V, see figure 11 -55C to +125C 01 120 ns Propagation delay time, high to low level

33、output RSwith 10 k to ground, see figure 11 180 RSwith 100 k to ground, see figure 11 1200 Pulse skew 3/ tsk(p)RS= 0 V, see figure 11 -55C to +125C 01 35 typical ns (| tPHL tPLH|) RSwith 10 k to ground, see figure 11 60 typical RSwith 100 k to ground, see figure 11 370 typical See footnotes at end o

34、f table. Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 7 TABLE I. Electrical performance characteristics Continued. 1/ Limits Test Symbol Conditio

35、ns 2/Temperature, TA Device type Min Max Unit Driver switching characteristics continued. Differential output signal rise time trRS= 0 V, see figure 11 -55C to +125C 01 20 70 ns Differential output signal fall time tfRS= 0 V, see figure 11 -55C to +125C 01 20 70 ns Differential output signal rise ti

36、me trRSwith 10 k to ground, see figure 11 -55C to +125C 01 30 135 ns Differential output signal fall time tfRSwith 10 k to ground, see figure 11 -55C to +125C 01 30 135 ns Differential output signal rise time trRSwith 100 k to ground, see figure 11 -55C to +125C 01 300 1400 ns Differential output si

37、gnal fall time tfRSwith 100 k to ground, see figure 11 -55C to +125C 01 300 1400 ns Enable time from standby to dominant ten(s)See figure 12 -55C to +125C 01 1.5 s See footnotes at end of table. Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-DEFENSE

38、 SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 8 TABLE I. Electrical performance characteristics Continued. 1/ Limits Test Symbol Conditions 2/Temperature, TA Device type Min Max Unit Receiver electrical characteristics. Positive going input 4/ thresho

39、ld voltage VIT+LBK = 0 V, see table II -55C to +125C 01 900 mV Negative going 4/ input threshold voltage VIT-LBK = 0 V, see table II -55C to +125C 01 500 mV Hysteresis voltage (VIT+- VIT-) VhysLBK = 0 V, see table II +25C 01 100 typical mV High level output voltage VOHIO= -4 mA, see figure 13 -55C t

40、o +125C 01 2.4 V Low level output voltage VOLIO= 4 mA, see figure 13 -55C to +125C 01 0.4 V Bus input current IICANH or CANL = 12 V, Other bus pin = 0, D = 3, LBK = 0 V, RS= 0 V -55C to +125C 01 150 500 A CANH or CANL = 12 V, Other bus pin = 0, D = 3, LBK = 0 V, RS= 0 V, VCC= 0 V 200 600 CANH or CAN

41、L = -7 V, Other bus pin = 0, D = 3, LBK = 0 V, RS= 0 V -610 -150 CANH or CANL = -7 V, Other bus pin = 0, D = 3, LBK = 0 V, RS= 0 V, VCC= 0 V -450 -130 Input capacitance (CANH or CANL) CINPin to ground, D = 3 V, LBK = 0 V, VI= 0.4 sin (4E6t) + 0.5 V +25C 01 40 typical pF Differential input capacitanc

42、e CIDPin to pin, D = 3 V, LBK = 0 V, VI= 0.4 sin (4E6t) + 0.5 V +25C 01 20 typical pF Differential input resistance RIDD = 3 V, LBK = 0 V -55C to +125C 01 40 100 k Input resistance (CANH or CANL) RIND = 3 V, LBK = 0 V -55C to +125C 01 20 50 k See footnotes at end of table. Provided by IHSNot for Res

43、aleNo reproduction or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/09611 REV PAGE 9 TABLE I. Electrical performance characteristics Continued. 1/ Limits Test Symbol Conditions 2/Temperature, TA Device type Mi

44、n Max Unit Receiver electrical characteristics continued. Supply current ICCSleep, D = VCC, RS= 0 V or VCC-55C to +125C 01 2 A Standby, D = VCC, RS= VCC, LBK = 0 V 600 Dominant, D = 0 V, no load, RS= 0 V, LBK = 0 V 6 mA Recessive, D = VCC, no load, RS= 0 V, LBK = 0 V 6 Receiver switching characteris

45、tics. Propagation delay time, low to high level output tPLHSee figure 13 -55C to +125C 01 60 ns Propagation delay time, high to low level output tPHLSee figure 13 -55C to +125C 01 60 ns Pulse skew 3/ (| tPHL tPLH|) tsk(p)See figure 13 +25C 01 7 typical ns Output signal rise time trSee figure 13 -55C

46、 to +125C 01 6.5 ns Output signal fall time tfSee figure 13 -55C to +125C 01 6.5 ns See footnotes at end of table. Provided by IHSNot for ResaleNo reproduction or networking permitted without license from IHS-,-,-DEFENSE SUPPLY CENTER, COLUMBUS COLUMBUS, OHIO SIZE A CODE IDENT NO. 16236 DWG NO. V62/

47、09611 REV PAGE 10 TABLE I. Electrical performance characteristics Continued. 1/ Limits Test Symbol Conditions 2/Temperature, TA Device type Min Max Unit Device switching characteristics. Loopback delay, driver input to receiver output t(LBK)See figure 14 -55C to +125C 01 13 ns t(loop1)RS= 0 V, see figure 15 -55C to +125C 01 135 ns Total loop delay, driver input to receiver output, recessive to dominant RSwith 10 k to ground, see figure 15 190 RSwith 100 k to ground, see figure 15 1000 t(loop2)RS= 0 V, see figure 15 -55C to +125C 01 135 ns Total