, DUA PERIPERA DRIVER R00A DECEMBER 98 REVIED NOVEMBER 99 Very ow Power Requirements Very ow Input Current Characterized for Use to 0 ma No atch-up at (After Conducting 00 ma) igh-voltage s ( Min) Clamp Diodes for Transient uppression (0 ma, ) TT- or MO-Compatible Diode-Clamped Inputs tandard upply Voltage uitable for ammer-driver Applications description The and dual peripheral drivers are designed for use in systems that require high current, high voltage, and fast switching times. The and provide AND and NAND drivers, respectively. These devices have diode-clamped inputs as well as high-current, high-voltage inductive-clamp diodes on the outputs. The and drivers are characterized for operation from 0 C to 0 C. A Y D OR P PACKAGE (TOP VIEW) 4 8 Function Tables (each AND driver) INPUT A V CC A Y OUTPUT Y (each NAND driver) INPUT A OUTPUT Y = high level, = low level = irrelevant schematics of inputs and outputs VCC EQUIVAENT OF EAC INPUT TYPICA OF A OUTPUT Input PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright 99, Texas Instruments Incorporated POT OFFICE BO 0 DAA, TEA
, DUA PERIPERA DRIVER R00A DECEMBER 98 REVIED NOVEMBER 99 logic symbols logic diagrams (positive logic) A & Y A Y A Y A Y 4 Positive ogic: Y = A or A+ A & Y A Y A Y A Y 4 This symbol is in accordance with ANI/IEEE td 9-984 and IEC publication -. Positive ogic: Y = A or A+ absolute maximum ratings over operating free-air temperature range (unless otherwise noted) upply voltage, V CC (see Note )............................................................. V Input voltage, V I........................................................................... V current, I O (see Note )........................................................... 400 ma clamp-diode current.............................................................. 400 ma Continuous total power dissipation..................................... ee Dissipation Rating Table Operating free-air temperature range, T A.............................................. 0 C to 0 C torage temperature range, T stg.................................................. C to 0 C ead temperature, mm (/ inch) from case for 0 seconds............................... 0 C tresses beyond those listed under absolute maximum ratings may 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 device reliability. NOTE:. Voltage values are with respect to network.. Both halves of this dual circuit may conduct rated current simultaneously; however, power dissipation averaged over a short time interval must fall within the continuous dissipation ratings. PACKAGE DIIPATION RATING TABE TA C DERATING FACTOR TA = 0 C POWER RATING ABOVE TA = C POWER RATING D mw.8 mw/ C 44 mw P 000 mw 8.0 mw/ C 40 mw POT OFFICE BO 0 DAA, TEA
, DUA PERIPERA DRIVER R00A DECEMBER 98 REVIED NOVEMBER 99 recommended operating conditions MIN NOM MA UNIT upply voltage, VCC 4.. V igh-level input voltage, VI V ow-level input voltage, VI 0.8 V Operating free-air temperature range, TA 0 0 C electrical characteristics over recommended operating free-air temperature range PARAMETER TET CONDITION MIN TYP MA UNIT VIK Input clamp voltage II = ma 0.9. V IO = 00 ma 0. 0. VCC = 4. V, IO = 00 ma 0. 0.4 VO ow-level output voltage VI =V V, V IO = 00 ma 0.4 0. VI = 0.8 V IO = 0 ma 0. 0. VO(BR) breakdown voltage VCC = 4. V, IO = 00 µa 0 0 VR(K) clamp-diode reverse voltage VCC = 4. V, IR = 00 µa 0 0 VF(K) clamp-diode forward voltage VCC = 4. V, IF = 0 ma 0... V IO igh-level output current VCC = 4. V, VI = V, VI = 0.8 V, VO = 00 µa II igh-level input current VCC =. V, VI =. V 0.0 0 µa II ow-level input current A input 0. 0 VCC =. V, VI =08V 0.8 input 0 µa ICC upply current, outputs high VI = V 8 VCC =. V VI = 0 8 ma ICC upply current, outputs low VI = 0 8 VCC =. V VI = V 8 ma All typical values are at VCC = V, TA = C. switching characteristics, V CC = V, T A = C PARAMETER TET CONDITION MIN TYP MA UNIT tp Propagation delay time, low-to-high-level output 00 0 ns tp Propagation delay time, high-to-low-level output C = pf, R = 00 Ω, 00 00 ns tt Transition time, low-to-high-level output ee Figure 0 00 ns tt Transition time, high-to-low-level output 0 00 ns VO igh-level output voltage after switching V = V, IO O 00 ma, ee Figure V 0.0808 V POT OFFICE BO 0 DAA, TEA
, DUA PERIPERA DRIVER R00A DECEMBER 98 REVIED NOVEMBER 99 PARAMETER MEAUREMENT INFORMATION Input.4 V VCC R = 00 Ω Pulse Generator (see Note A) A/ /A Circuit Under Test C = pf (see Note B) 0.4 V TET CIRCUIT Open ns 0 ns V. V. V Input. V. V 0. V 0. V µs ns 0 ns V. V. V Input. V. V 0. V 0. V tp tp VO 90% 90% 0% 0% 0% 0% tt VOTAGE WAVEFORM NOTE: A. The pulse generator has the following characteristics: PRR = 00 kz, ZO = 0 Ω. B. C includes probe and jig capacitance. tt Figure. Test Circuit and Voltage Waveforms, witching Characteristics VO 4 POT OFFICE BO 0 DAA, TEA
, DUA PERIPERA DRIVER PARAMETER MEAUREMENT INFORMATION R00A DECEMBER 98 REVIED NOVEMBER 99 V = V Input.4 V V m 80 Ω Pulse Generator (see Note A) A Circuit Under Test C = pf (see Note B) 0.4 V TET CIRCUIT Input Input 90%. V ns 0% ns 40 µs 0 % 0 ns 90%. V 90% 90%. V. V 0% 0% 0 ns V V VO VOTAGE WAVEFORM VO NOTE: A. The pulse generator has the following characteristics: PRR =. kz, ZO = 0 Ω. B. C includes probe and jig capacitance. Figure. atch-up Test Circuit and Voltage Waveforms POT OFFICE BO 0 DAA, TEA
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