Automotive Selection Guide 2003 2004 www.ti.com/automot
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Automotive
Selection Guide
2003 2004
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Introduction Table Contents
Operational Amplifiers Comparators Overview Precision Low-Voltage Low-Power Wide-Voltage Range General Purpose Comparators Difference Amplifiers 10-11 Data Converters Overview ADCs 13-15 Pipeline ADCs 16-18 String DACs 19-20 R-2R DACs Current Steering DACs CODECs Voiceband Codecs 23-24 Low-Power Audio Codecs/DACs Video ADCs/DACs Interface Solutions LVDS 26-27 Multipoint-LVDS 28-29 RS-485/422 30-31 33-34 CardBus Controllers 35-36 Bridges IDB-1394 37-39 UARTs Logic Product Life Cycle Performance Postioning High Volume Automotive Families Low-Voltage Market (Coverage Standardization) Q-100 Logic Parts Power Management Linear Dropout Regulators (LDOs) 44-45 Reference Shunt Regulators Switching DC/DC Controllers Power Supply Controllers DC/DC Converters (Integrated Switch) Supervisors Power Management Devices DSPs Power Control Products
Texas Instruments Commitment Automotive
goal Texas Instruments (TI) become premier automotive semiconductor supplier being clear leader with cost-effective total board system solutions benchmark service terms conformance specifications, product documentation, superior quality standards on-time delivery. Availability/Commitment supports requirements defined automotive industry, continues automotive portfolio. With over years experience servicing customers with defined requirements, enables customers achieve quality, reliability, cost goals needed succeed today's marketplace. Automotive Capabilities -TS16949 Certification Roadmap -Customer Print Validation -Major Change Approval -Special electrical test limits electrical screening -Q-100 qualification/new product release procedures hour customer return validations -Special symbolization custom code labeling -Special packaging -Automated factory starts through ordering -JIT delivery remote warehousing -EOL Management
Automotive Selection Guide
2003-2004 Texas Instruments
Operational Amplifiers
Rapid Selector
tables following pages have been divided into several categories help quickly narrow alternatives.
Precision Noise 12nV/ Voltage Power mA/ch Wide Bandwidth Voltage Noise 12nV/ Input Bias Current Power mA/ch Wide Gain Bandwidth Power mA/ch Voltage. Wide Bandwidth Noise 12nV/ Wide Voltage Precision Power mA/ch Input Bias Current Wide Bandwidth Noise 12nV/ General Purpose
Texas Instruments offers wide range types including high precision, micropower, voltage, high speed rail-to-rail several different process technologies. developed industry's largest selection power voltage amps
with features designed satisfy very wide range appplications. help facilitate selection process, interactive online parametric search engine available amplifier.ti.com/search with links specifications.
Common Design Questions
What amplitude input signal? ensure that signal errors small relative input signal, small input signals require high precision, (e.g., offset voltage) amplifiers. Ensure that amplified output signal stays within amplifier output voltage. Will ambient temperature vary? amps sensitive temperature variations, often necessary consider offset voltage drift over temperature. Does common-mode voltage vary? Make sure operated within common-mode range adequate common-mode rejection ratio (CMRR). Commonmode voltage will induce additional offset voltage. Does power supply voltage vary? Power supply variations affect offset voltage. This especially important battery-powered applications. Precision Application Examples High gain circuits >100) Measuring small input signals (i.e., from thermocouple) Wide operating temperature range circuits (i.e. automotive industrial applications) Single-supply data-acquisition systems where input voltage span limited.
Naming Conventions
Texas Instruments 2003-2004
Automotive Selection Guide
Precision Operational Amplifiers (VOS Selection Guide
Slew Rate (25°C) (mA) (MHz) (V/µs) (mV) Device1 Description (min) (max) (max) (typ) (typ) (max) Precision, Noise nV/Hz (typ) TLC450x Precision, Self-Calibrating, 1.5, 0.08, LinEPIC 0.1, 0.05 TLE2027 Precision, Noise, Wide Bandwidth, Wide OPAy350 CMOS, TLC220x Precision, Noise Precision, Voltage (min) OPAy335 Zero Drift, Precision, CMOS OPAy336 CMOS, µPower TLC1078 Voltage, Precision OPAy350 CMOS, 0.35 0.032 0.017 0.085 0.03 0.032 0.005 0.125 0.45 Offset Drift CMRR Rail(µV/°C) (pA) (dB) (nV/Hz) Single to(typ) (max) (min) (typ) Supply Rail 0.02 90000
Package(s) SOIC SOIC PDIP, MSOP, SOIC, SSOP PDIP, SOIC MSOP, SOIC, SOT23 MSOP, PDIP, SOIC, SOT23 SOIC, SOP, PDIP PDIP, MSOP, SOIC, SSOP
Precision, Power mA/ch (max) OPAy335 Zero Drift, Precision, CMOS OPAy336 CMOS, µPower TLC1078 Voltage, Precision TLE202x LT1013 LT1014 Precision, Single Supply Dual Precision Quad Precision
0.35 0.032 0.017
0.085
0.03 0.032
0.005 0.125 0.45
0.02
0.3, 0.35 1.2, 0.55, 0.55,
0.6, 0.3, 0.15, 2.5, 0.3, 0.18 2.5,
70000 -30000 -30000 -20000
MSOP, SOIC, SOT23 MSOP, PDIP, SOIC, SOT23 SOIC, SOP, PDIP SOIC, PDIP, TSSOP, LCCC, CDIP, PDAP LCCC, CDIP, PDIP
Precision, Input Bias Current (max) OPAy340 CMOS, Wide Bandwidth
0.95
OPAy350 CMOS, OPAy335 Zero-Drift, Precision, CMOS OPAy336 CMOS, µPower TLC1078 Voltage, Precision
0.35 0.032 0.017
0.085
0.03 0.032
0.005 0.125 0.45
0.02
MSOP, PDIP, SOIC, SOT23, TSSOP PDIP, MSOP, SOIC, SSOP MSOP, SOIC, SOT23 MSOP, PDIP, SOIC, SOT23 SOIC, SOP, PDIP SOIC
PDIP, MSOP, SOIC, SSOP indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
Precision, Wide Bandwidth (typ) TLE2027 Precision, Noise, Wide Bandwidth, Wide OPAy350 CMOS,
90000
Automotive Selection Guide
2003-2004 Texas Instruments
Low-Voltage Operational Amplifiers Selection Guide
Slew Offset Rate (25°C) Drift Rail(V) (mA) (MHz) (V/µs) (mV) (µV/°C) (pA) (nV/Hz) toSHDN (min) (max) (max) (typ) (typ) (max) (typ) (max) (typ) Rail
Device1
Description
Package(s)
Low-Voltage, Noise nV/Hz (typ) TLV246x Power, Rail-to-Rail TLV236x Dual, High-Performance
0.575 0.25
0.67
0.55
14000 150000
OPA350 High-Speed, Single Supply TLV226x Rail-to-Rail, Power
LCCC, CFP, CDIP, SOIC, SOP, PDIP SOIC, VSSOP, PDIP, SOP, TSSOP VSSOP, PDIP, SOIC LCCC, CFP, CDIP, SOIC, PDIP, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP PDIP, SC70, SOIC MSOP, PDIP, SOIC, SOT23, TSSOP PDIP, MSOP, SOIC, SSOP MSOP(PP), PDIP, SOIC, SOT23, TSSOP(PP) SOIC, TSSOP SOIC, SOP, PDIP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23 MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, SOIC, SOT23
Low-Voltage, Input Bias Current (max) TLV276x µPower, Bias Current TLV278x Power, MHz, Bias Current OPAy336 CMOS, µPower, OPAy347 µPower, Cost, TLV277x RRO, High Slew Rate OPAy350 CMOS, TLV247x Power, Bias Current, 35-mA Drive OPAY343 CMOS Wide Bandwidth Low-Voltage, Power (max) TLC1078 Voltage, Precision TLV276x µPower, Bias Current TLV278x Power, MHz, Bias Current OPAy336 CMOS, µPower, TLV240x sub-µPower, TLV224x TLV245x Voltage, µPower,
0.028 0.82 0.032 0.034 0.75 1.25 0.017 0.028 0.82
0.35
0.03 0.17
0.125 0.45
0.02
5000 14000
0.085 0.032
0.032 0.03 0.125 0.00095 0.0055 0.0025 0.0012 0.0055 0.002 0.035 0.22 0.12 0.35 0.575 0.75 0.005
OPAy335 Zero Drift, Precision, CMOS, TLV246x Noise, Wide Bandwidth, 25-mA Drive TLV247x Power, Bias Current, 35-mA Drive TLV237x MHz, TLV225x Rail-to Rail, Voltage TLV226x Rail-to Rail, Voltage OPAY244 µPower, LMV324/ Rail-to-Rail, Voltage LMV358 Low-Voltage, Wide Bandwidth (typ) TLV278x Power, MHz, Bias Current TLV277x High Slew Rate Noise, Wide Bandwidth, 25-mA Drive TLV263x mA/ch, MHz, OPAy350 CMOS, TLV246x
0.66 0.0625 0.187 0.25 0.67 0.55 0.05 0.3, 0.017
2.3, 25000 25000
MSOP, PDIP, SOIC, SOT23, TSSOP MSOP(PP), PDIP, SOIC, SOT23, TSSOP(PP) SOT23, MSOP LCCC, CFP, CDIP, PDIP, SOIC LCCC, CFP, CDIP, PDIP, SOIC, TSSOP VSSOP, PDIP, SOIC, SOP, TSSOP SOIC, TSSOP, VSSOP
0.82 0.575
14000
MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP ,SOIC, SOT23, TSSOP PDIP, MSOP, SOIC, SSOP SOT23, TSSOP
indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
Texas Instruments 2003-2004
Automotive Selection Guide
Low-Power Operational Amplifiers Selection Guide
Slew Offset Rate (25°C) Drift Rail(V) (mA) (MHz) (V/µs) (mV) (µV/°C) (pA) (nV/Hz) toSHDN (min) (max) (max) (typ) (typ) (max) (typ) (max) (typ) Rail 0.00095 0.0055 0.0025 0.017 0.032 0.035 0.575 0.75 0.82 0.085 0.22 5000 14000
Device1 Description Low-Power, Voltage (min) TLV240x sub-µPower, TLC1078 Voltage, Precision OPAy336 CMOS, µPower, TLV245x µPower, TLV246x
Package(s) MSOP, PDIP, SOIC, SOT23, TSSOP SOIC, SOP, PDIP MSOP, PDIP, SOIC, SOT23 MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP(PP), PDIP, SOIC, SOT23, TSSOP(PP) MSOP, PDIP, SOIC, SOT23, TSSOP LCCC, CFP, CDIP, SOIC LCCC, CFP, CDIP, PDIP, SOIC, TSSOP VSSOP, PDIP, SOIC, SOP, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP PDIP, SOIC, SOT23, TSSOP MSOP, PDIP ,SOIC, SOT23, TSSOP
0.032 0.45 0.03 0.125 0.12
Noise, Wide Bandwidth, 25-mA Drive TLV247x Power, Bias Current, 35-mA Drive TLV278x Power, MHz, Bias Current TLV225x Rail-to-Rail, Voltage TLV226x Rail-to Rail, Voltage OPAY244 µPower, Low-Power, Wide Bandwidth (typ) TLV246x Noise, Wide Bandwidth, 25-mA Drive TLV278x Power, MHz, Bias Current TLV263x mA/ch, MHz, GND, Low-Power, Noise nV/Hz (typ) TLV246x Power, Rail-to-Rail TLV226x Rail-to-Rail, Power
0.0625 0.187 0.25 0.67 0.55 0.05 0.3, 0.575 0.82
2.3, 25000 14000
0.575 0.25
0.67
0.55
14000
LCCC, CFP, CDIP, SOIC, SOP, PDIP LCCC, CFP, CDIP, SOIC, PDIP, TSSOP
Wide-Voltage Range Operational Amplifiers Selection Guide
(mA) Device Description (min) (max) (max) Wide-Voltage, Precision Offset (max) TLC220x Precision, Noise TLE2027 Precision, Noise, Wide Bandwidth, Wide TLE202x Precision, Single Supply 0.3, 0.35 LT1013 Dual Precision 0.55, LT1014 Quad Precision Wide-Voltage, Power mA/ch (max) TLV225x Rail-to-Rail, Voltage 0.55, Slew Offset Rate (25°C) Drift CMRR Rail(MHz) (V/µs) (mV) (µV/°C) (pA) (dB) (nV/Hz) Single to(typ) (typ) (max) (typ) (max) (min) (typ) Supply Rail 1.2, 90000
Package(s) PDIP, SOIC SOIC
0.6, 70000 2.5, -30000 0.15, 0.3, 0.18 2.5, -30000
SOIC, PDIP, TSSOP, LCCC, CDIP, PDAP LCCC, CDIP, PDIP
LCCC, CFP, CDIP, PDIP, SOIC TLV226x Rail-to-Rail, Voltage 0.25 0.67 0.55 LCCC, CFP, CDIP, PDIP, SOIC, TSSOP OPAY244 µPower, 0.05 0.3, 2.3, 25000 VSSOP, PDIP, SOIC, SSOP, TSSOP TLV237x MHz, SHDN 0.66 SOT23, MSOP TLV240x sub-µPower 0.00095 0.0055 0.0025 MSOP, PDIP, SOIC, SOT23, TSSOP TLE206x Power, JFET-Input, 0.35 2000 PDIP, SOIC, High Drive TSSOP TLE202x Power, Wide 70000 PDIP, SOIC, Voltage Supply SSOP, TSSOP indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
0.0625 0.187
Automotive Selection Guide
2003-2004 Texas Instruments
Wide-Voltage Range Operational Amplifiers Selection Guide
Slew Offset Rate (25°C) Drift CMRR Rail(V) (mA) (MHz) (V/µs) (mV) (µV/°C) (pA) (dB) (nV/Hz) Single toDevice Description (min) (max) (max) (typ) (typ) (max) (typ) (max) (min) (typ) Supply Rail Package(s) Wide-Voltage, Input Bias Current (max) TLV237x MHz, SHDN 0.66 SOT23, MSOP TLC227x Noise, Rail-to-Rail 2.18 SOIC, LCCC, CFP, CDIP PDIP, TSSOP TLC227x Noise, Rail-to-Rail 2.18 SOIC, LCCC, CFP, CDIP, PDIP, TSSOP TLC07x Noise, Wide Bandwidth, MSOP(PP), CMOS, SHDN, High Drive, PDIP, SOIC, Input TSSOP(PP) TLC08x Noise, Wide Bandwidth, MSOP(PP), CMOS, Input SHDN, PDIP, SOIC, High Drive TSSOP(PP) Wide-Voltage, Wide Bandwidth (typ) TLC07x Noise, Wide Bandwidth, MSOP(PP), CMOS, SHDN, High Drive, PDIP, SOIC, Input TSSOP(PP) TLC08x Noise, Wide Bandwidth, MSOP(PP), CMOS, Input SHDN, PDIP, SOIC, High Drive TSSOP(PP) Low-Power, Noise nV/Hz (typ) TLV226x Rail-to-Rail, Power 0.25 0.67 0.55 LCCC, CFP, CDIP, SOIC, PDIP, TSSOP TLC227x Rail-to-Rail, Power 2.18 LCCC, CDIP, CFP, SOIC, SSOP, PDIP TLC07x Wide-Band, High-Output SOIC, HTSSOP, SOIC, PDIP TLC08x Wide-Band, High Output SOIC, HTSSOP, SOIC, PDIP, TLE214x High-Speed, Single Supply 0.9, 1.2, 1500000 10.5 CDIP, SOIC, PDIP, LCCC TLE2027 Precision 90000 LCCC, CDIP, SOIC, PDIP
General Purpose Operational Amplifiers Selection Guide
Slew Offset Rate (25°C) Drift CMRR (mA) (MHz) (V/µs) (mV) (µV/°C) (nA) (dB) Single Device Description (min) (max) (max) (typ) (typ) (max) (typ) (max) (min) (nV/Hz) Supply Package(s) LM358, Dual, Quad, 0.6, 0.7, 0.3, -250 PDIP, SOIC, LM324 General Purpose SOP, TSSOP LM2904, General Purpose 0.6, 0.7, 0.3, -250 PDIP, SOIC, SOP, LM2902 TSSOP LMV321, Voltage, 0.17 SOT23, SC70, MSOP, LMV358 Dual Volt., 0.34 -250 SOIC, TSSOP LMV324 Dual Volt., 0.34 -250 SOIC, TSSOP LMV324S Voltage, 0.17 SOIC, TSSOP RRO, SHDN LT1013/A/D Precision, 0.55, 0.3, 2.5, -30, PDIP, SOIC Power 0.5, 0.15, -20, 100, 0.55 LT1014/A/D Precision, 0.55, 0.3, 2.5, -30, PDIP, Wide SOIC, Power 0.5, 0.18, -20, 100, 0.55 TL06x/A/B Power, 0.25 0.4, 0.2, PDIP, SOIC, SOP, TSSOP JFET-Input TL07x/A/B Noise, PDIP, SOIC, SOP, TSSOP, JFET-Input TL347x High Slew Rate PDIP, SOIC TLV236x High Performance, PDIP, SOT23, SOIC, Voltage, SOP, TSSOP indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
Texas Instruments 2003-2004
Automotive Selection Guide
Comparators
Comparator specialized amps designed compare input voltages provide logic state output. They considered one-bit analog-to-digital converters. comparator portfolio consists variety products with various performance characteristics, including: fast (ns) response time, wide input voltage ranges, extremely quiescent current consumption comparator combination ICs. Comparator
Speed (Response time) Logic Output Wide Diff. Input Range Precision Comparator
Response time (propagation delay)- applications requiring "near real-time" signal response should consider comparators with nanosecond (ns) propagation delay. Note that propagation delay decreases, supply current increases. Evaluate what performance power afforded. TLV349x family offers unique combination speed/ power with 6-µs propagation delay only quiescent current.
Hysteresis-positive feedback that pulls input signal through threshold when output switches, preventing unwanted multiple switching. Combination comparator amp- input signals requiring level shifting and/or gain prior comparator, consider TLV230x (open drain) TLV270x (push-pull) comparator combinations. These dual function devices save space cost!
Comparator Product Portfolio Snapshot
general, fast response time required, always comparator.
Design Considerations
Output topology Open collector-connects logic supply through pull-up resistor allows comparators interface variety logic families. Push-pull-does require pull-up resistor. Because output swings rail-to-rail, logic level dependent voltage supplies comparator.
Comparators Selection Guide
(mA) (max) Output tRESP Current Low-to- (25°C) (mA) High (mV) (min) (µs) (min) (max) (max) 0.115
Device Description High Speed tRESP LM211 Single, High Speed, Strobed Power TLV340x Nanopower, Open Drain, RRIO TLV370x Nanopower, Push-Pull, RRIO Voltage, Excellent Speed/Power Sub-Micropower, Comparator, RRIO TLV270x Sub-Micropower, Comparator, RRIO TLC370x Fast, Power
Output Type Open Drain/Collector Open Drain/Collector Push Pull Push Pull Open Drain/Collector Push Pull Push Pull
Package(s) PDIP, SOIC MSOP, PDIP, SOIC, MSOP, PDIP, SOIC, SOT23, TSSOP SOT23, SOIC, TSSOP MSOP, PDIP, SOIC, TSSOP MSOP, PDIP, SOIC, TSSOP PDIP, SOIC, TSSOP
0.00055 0.0008 0.0012 0.0017 0.0019 0.02
TLV349x TLV230x
indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
Automotive Selection Guide
2003-2004 Texas Instruments
Comparators Selection Guide (continued)
(mA) (max) 0.02 0.02 0.025 0.15 0.15 0.15 0.15 0.125 0.15 0.625 Output tRESP Current Low-to- (25°C) (mA) High (mV) (min) (µs) (min) (max) (max) 0.65 0.65
Device1 Description Power TLC393 Linear TLC339 Quad, Power, Open Drain LP339 Quad, Power, General Purpose LMV393 Dual, Voltage LMV339 Quad, Low-Voltage TLC37x Fast, Power TLV1391 Linear Voltage (min) TLC35x TLV1391 Linear Comparator TLV235x Voltage TLC37x Fast, Power LM2901 Quad, General Purpose LM339 Quad, General Purpose TLV340x TLV370x Nanopower, Open Drain, RRIO Nanopower, Push-Pull, RRIO
Output Type
Package(s)
Open Drain/Collector PDIP, SOIC, SOP, TSSOP Open Drain/Collector PDIP, SOIC, TSSOP Open Drain/Collector PDIP, SOIC Open Drain/Collector SOIC, TSSOP Open Drain/Collector SOIC, TSSOP Open Drain/Collector PDIP, SOIC, TSSOP SOT23 Open Drain/Collector Open Drain/Collector Open Drain/Collector Open Drain/Collector Open Drain/Collector Open Drain/Collector Push Pull PDIP, SOIC, TSSOP SOT23 PDIP, SOIC, TSSOP PDIP, SOIC, TSSOP PDIP, SOIC, SOP, TSSOP PDIP, SOIC, SOP, SSOP, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP MSOP, PDIP, SOIC, SOT23, TSSOP SOIC, TSSOP SOIC, TSSOP SOIC, PDIP, SOP, TSSOP
0.00055 0.0008
LMV393 Dual, Voltage Open Drain/Collector LMV339 Quad Voltage Comparators Open Drain/Collector LM2903 Dual, General Purpose Open Drain/Collector Combination Comparators Amps TLV230x Sub-Micropower, 0.0017 Open Drain/Collector MSOP, PDIP, SOIC, Comparator, RRIO TSSOP TLV270x Sub-Micropower, 0.0019 Push Pull MSOP, PDIP, SOIC, Comparator, RRIO TSSOP indicates: single with shutdown, single, dual, dual with shutdown, quad, quad with shutdown. indicates: character single, dual, triple, quad.
Texas Instruments 2003-2004
Automotive Selection Guide
Difference Amplifiers
difference amplifier moderate input impedance, closed-loop, fixed-gain block that allows acquisition signals presence ground loops noise. These devices used variety circuit applications- precision, general-purpose, audio, lowpower, high-speed high-commonmode voltage applications. Difference Amplifier basic difference amplifier employs four on-chip precision, laser-trimmed resistors. INA132, example, operates 2.7-V 36-V supplies consumes only differential gain high common -mode rejection. output signal offset applying voltage pin. output sense connected directly load reduce gain error. Because resistor network divides down input voltages, difference amplifiers operate with input signals that exceed power supplies.
Should Difference Instrumentation Amplifier?
Difference amplifiers excel when measuring signals with common-mode voltages greater than power supply rails, when there power requirement, when small package needed, when source impedance when lowcost differential required. difference building block instrumentation amp. Instrumentation amps designed amplify low-level differential signals presence high-common-mode voltage. Generally, using adjustable gain block, they well suited single-supply applications. three-op-amp topology works well down Gain with performance advantage CMR. two-op-amp topology appropriate tasks requiring small package footprint gain greater. best choice low-voltage, single-supply applications.
measuring current from high-voltage power supply through high-side shunt resistor.
levels common-mode voltage-far beyond supply rails. Gain-signal amplification needed desired circuit function must considered. Sensor impedance-should less than 1/1000 difference impedance retain gain accuracy. other words, input impedance should 1,000 times higher than source impedance. Offset voltage drift (µV/°C)-input offset voltage changes over temperature. This more critical applications with changing ambient temperature.
INA132 Block Diagram
INA117 Block Diagram
Design Considerations
Power supply-common-mode voltage always function supply voltage. Output voltage swing-lower supply voltage often drives need maximize dynamic range swinging close rails. High-Common-Mode Voltage Difference Amplifier Topology five-resistor version simple difference amplifier results device that operate with very high levels common-mode voltage-far beyond power supply rails. example, INA117 sense differential signals presence common-mode voltages high ±200 while being powered from This device very useful Automotive Selection Guide Common-mode input voltage range (CMV)-selection most suitable difference begins with understanding input voltage range. Some offer resistor networks that divide down input voltages, allowing operation with input signals that exceed power supplies. five-resistor version simple difference amplifier results device that operate with very high
Quiescent current-often high importance battery-powered applications, where amplifier power consumption greatly influence battery life. Slew rate-if signal reporting temperature, force pressure, slew rate generally great concern. signal electronic event, (e.g., current, power output) fast transition needed. Common-mode rejection-a measure unwanted signal rejection amp's ability extract signal from surrounding power line other electrical noise.
2003-2004 Texas Instruments
Difference Amplifiers Selection Guide
Offset (µV) (max) 1500 1000 1000 1000 1000 1000 1000 Offset Drift CMRR (µV/°C) (dB) (MHz) (max) (min) (typ) Output Voltage Swing (min) Power Supply (mA) (max) Package(s) 0.185 0.65 0.045 0.125 0.045 0.125 0.125 VSSOP TSSOP TSSOP TSSOP TSSOP TSSOP
Device Description General Purpose INA132 Micropower, High Precision INA152 Single-Supply INA154 High Speed, Precision, High-Common-Mode Voltage INA117 ±200-V Range, Prog. Gain High-Side Current Shunt Monitor INA138 INA139 High Speed, INA168 INA169 High Speed, INA170 High-Side Bi-directional
Gain µA/V 1000 µA/V µA/V 1000 µA/V 1000 µA/V
(V+) (V-) +2.7 (V+) 0.35 (V-) ±1.35V (V+) (V-) (V+) (V+) (V+) (V+) (V+) +2.7 +2.7 +2.7 +2.7 +2.7
Texas Instruments 2003-2004
Automotive Selection Guide
Data Converters
Texas Instruments offers full line data acquisition products such ADCs string DACs, high-speed, pipelined architecture ADCs DACs, well high-performance line converters made especially automotive audio, imaging video applications. New, featured products include TL1548, CMOS 10-bit switched-capacitor ADC. designed operate with wide range supply voltages with very power consumption. serious about data converters dedicated providing easy-to-use products offering best high-performance features, power, small packaging sample support extras make your easier.
Data Converter Selection Tree
Power Management
Processor
String
Pipeline
Current Steering
Automotive Selection Guide
2003-2004 Texas Instruments
ADCs
SAR-type converters frequently architecture choice medium-tohigh-resolution applications with medium sampling rates. ADCs most commonly range resolution from 10to 16-bits with speeds typically less than MSPS. They provide power consumption small form factor. little sample-to-conversion latency compared pipeline deltasigma converter. This combination makes them ideal real-time applications such power management, portable/ battery-powered instruments, data/signal acquisition.
successive approximation register (SAR) ADC, bits decided single high-speed, high-accuracy comparator bit, from down LSB. This done comparing analog input with whose output updated previously decided bits successively approximates analog input.
TLV1548 CMOS 10-bit switched-capacitor ADCs
samples, datasheets, EVMs reports www.ti.com/sc/device/TLV1548 TLV1548 successive-approximation (SAR) ADC. chip select, input-output clock, data input serial data output that provides direct 4-wire synchronous serial peripheral interface (SPITM, QSPITM) port host microprocessor. device allows high-speed data transfers from host. input provides further timing flexibility serial interface. addition high-speed converter versatile control capability, device on-chip 11-channel multiplexer that select eight analog inputs three internal self-test voltages. TLV1548 designed operate with wide range supply voltages with very power consumption. Features Resolution (bits): Sampling rate: kSPS Input Channels (SE): Programmable Power Down: Single-Supply Operation Range: Analog Input Range: Built-In Self Test Modes End-of-Conversion (EOC) Flag Packaging: 20-pin SSOP
TLV1548 eight analog input channels
Sample Hold Function 10-Bit (Switch Capacitors) CLOCK A0±A7 REF+ Output Data Register Analog Self-Test Reference Input Data Register Control Logic Counters 10-to-1 Data Selector DATA
REF± DATA
CSTART
Texas Instruments 2003-2004
Automotive Selection Guide
Single-Channel ADCs Selection Guide
Sample Number Res. Rate Input Input Voltage Linearity NMC2 Device (Bits) (kSPS) Channels1 Interface VREF (Bit) kHz<fs<50 Successive Approximation Architecture ADS7807 Serial ±0.0022 ADS7813 Serial, ±3.3, ±0.003 ADS7806 Serial ±0.011 ADS7812 Serial, ±3.3, ±0.012 ADS1286 Diff Serial, VREF ±0.024 TLC1549 Serial, VREF ±0.1 TLV1549 Serial, VREF ±0.1 TLV0831 Serial, VREF ±0.2 TLC548 45.5 Serial, VREF ±0.2 TLC549 Serial, VREF ±0.2 TLC0831 Serial, VREF ±0.2 kHz<fs<200 Successive Approximation Architecture TLC4541 Serial, VREF ±0.0045 TLC4545 Diff Serial, VREF ±0.0045 ADS7805 P8/P16 ±0.0045 ADS7809 Serial, ±3.3, ±0.0045 ADS8320 Diff Serial, VREF ±0.012 ADS8321 Diff Serial, ±VREF +VREF ±0.012 ADS8325 Diff Serial, VREF ±0.006 TLC3541 Serial, VREF ±0.006 TLC3545 Diff Serial, VREF ±0.006 ADS8324 Diff Serial, ±VREF +VREF ±0.012 ADS7816 Diff Serial, VREF ±0.024 ADS7817 Diff Serial, ±VREF +VREF ±0.024 TLV2541 Serial, VREF ±0.024 TLV2545 Serial, VREF ±0.024 ADS7804 ±0.011 ADS7808 Serial, ±3.3, ±0.011 ADS7822 Diff Serial, VREF ±0.018 ADS7823 Diff Serial, VREF ±0.024 TLC1550 VREF ±0.05 TLC1551 VREF ±0.1 kHz<fs<500 Successive Approximation Architecture ADS7811 ±2.5 ±0.006 ADS7815 ±2.5 ±0.006 (typ) TLC2551 Serial, VREF ±0.024 TLC2555 Serial, VREF ±0.024 ADS7800 P8/P12 ±0.012 TLC0820A VREF ±0.2 kHz<fs<8 Successive Approximation Architecture ADS8381 P16/ VREF ±0.003 ADS8402 1250 Diff VREF ±0.00375 ADS8401 1250 VREF ±0.00375 ADS8371 VREF ±0.003 ADS8322 Diff ±0.009 ADS8323 Diff ±2.5 ±0.009 ADS7810 ±0.018 ADS7818 Diff Serial, ±0.024 ADS7834 Diff Serial, ±0.024 ADS7835 Diff Serial, ±2.5 ±0.024
SINAD (dB) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ)
Power (mW/V) 3.5/ +2.7, 1.3/ +2.7, 0.7/ +3.3 17.5/ 17.5/ 100/ 100/ 1.8/ +2.7, 4.5/ 1.8/ +2.7, 17.5/ 17.5/ 2.5/ +1.8, +3.6 3.5/ +2.7, +2.7, 2.3/ +2.7, 2.3/ +2.7, 100/ 100/ 1.6/ +2.7, 3.5/ +2.7, 250/ 250/ 215/ 37.5/
Number Package3 Leads
100/ +2.7, 150/ +2.7, 150/ +2.7, 100/ 2.7, (typ) (typ) 250/ 17.5/
Single-Ended, Diff Differential. 2NMC missing code resolution. PDIP, SOIC, SSOP, Ceramic, PLCC, TQFP.
Automotive Selection Guide
2003-2004 Texas Instruments
Multichannel Selection Guide
Sample Number Res. Rate Input Device (Bits) (kSPS) Channels1 Interface Type kHz<fs<50 Successive Approximation Architecture ADS7825 Serial ADS7824 Serial TLC1542 Serial, TLC1543 Serial, TLV1543 Serial, TLC1541 Serial, TLV0832 44.7 Serial, TLV0834 Serial, TLC541 Serial, TLV0838 37.9 Serial, TLC542 Serial, TLC0832 Serial, TLC0834 Serial, TLC0838 Serial, kHz<fs<200 Successive Approximation Architecture ADS8341 Diff/4 Serial, ADS8343 Diff/4 Serial, ADS8344 Diff/8 Serial, ADS8345 Diff/8 Serial, TLC3544 Serial, TLC3548 Serial, TLC3574 Serial, TLC3578 Serial, ADS7841 Diff/4 Serial, ADS7842 ADS7844 Diff/8 Serial, TLC2574 Serial, TLC2578 Serial, TLV2542 Serial, TLV2544 Serial, TLV2548 Serial, TLV2553 Serial, TLV2556 Serial, ADS7832 TLC2543 Serial, TLV2543 Serial, ADS7828 Diff/8 Serial, TLV1504 Serial, TLV1508 Serial, TLV1544 Serial, TLV1548 Serial, TLC545 Serial, TLC540 Serial, kHz<fs<500 Successive Approximation Architecture TLC2552 Serial, TLC2554 Serial, TLC2558 Serial, TLC1514 Serial, TLC1518 Serial, kHz<fs<5 Successive Approximation ADS8361 Diff Serial, ADS8364 250/ch Diff ADS7852 ADS7861 Diff Serial, ADS7862 Diff ADS7864 Diff SA1SE
Input Voltage VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF ±VREF +VREF VREF ±VREF +VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF VREF ±2.5 +2.5 ±2.5 +2.5 ±2.5 +2.5 ±2.5 +2.5 ±2.5 +2.5
VREF
Linearity NMC2 SINAD (Bit) (dB) ±0.003 ±0.012 ±0.05 ±0.1 ±0.1 ±0.1 ±0.2 ±0.2 ±0.2 ±0.2 ±0.2 ±0.2 ±0.2 ±0.2 ±0.006 ±0.006 ±0.006 ±0.006 ±0.006 ±0.006 ±0.006 ±0.006 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.024 ±0.018 ±0.024 ±0.024 ±0.024 ±0.05 ±0.05 ±0.1 ±0.1 ±0.2 ±0.2 ±0.024 ±0.024 ±0.024 ±0.012 ±0.012 ±0.009 ±0.0012 ±0.024 ±0.024 ±0.024 ±0.024 (typ) (typ) (typ) (typ) 81.5 (typ) 81.5 (typ) 81.5 (typ) 81.5 (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ) (typ)
Power (mW/V) 2.7/ +3.3 6.5/ +3.3 2.7/ +3.3 2.7/ +3.3 12.5/ 3.2/ +2.7, 3.2/ +2.7, 3.2/ +2.7, 3.2/ +2.7, 0.7/ +2.7, 0.7/ +2.7, 0.7/ +2.7, 4.5/ +2.7, 2.3/ +2.7, 2.3/ +2.7, 4.5/ +2.7, 4.5/ +2.7, 2.2/ +2.7, 2.2/ +2.7, 7.5/ +3.3 3.3/ +3.3 3.5/ +2.7, 2.7/ +2.7, 2.7/ +2.7, 1.1/ +2.7, 1.1/ +2.7, 140/ 140/
Number Package3 Leads
Single-Ended, Diff Differential. 2NMC missing code resolution. PDIP, SOIC, SSOP, Ceramic, PLCC, TQFP.
Texas Instruments 2003-2004
Automotive Selection Guide
Pipeline ADCs
This converter type offers high speed, high resolution excellent performance, along with modest levels power dissipation small size. Within reasonable design limits, they also offer excellent dynamic performance. Pipeline latency typically more clock cycles. Target applications pipeline ADCs include CCD-based imaging systems, digital receiver, digital video. Additionally, communication systems which total harmonic distortion (THD), spurious-free dynamic range (SFDR) other frequencydomain specifications significant.
Pipeline ADCs consist numerous consecutive stages, each containing sample hold (S/H), low-resolution DAC, summing circuit that includes interstage amplifier provide gain.
THS1206 12-bit, 6-MSPS with Integrated FIFO
samples, datasheets, EVMs reports www.ti.com/sc/device/ths1206 THS1206 CMOS, low-power, ADC. speed, resolution, bandwidth, singlesupply operation suited automotive applications. multistage pipelined architecture with output error correction logic provides missing codes over full operating temperature range. Internal control registers used program into desired mode. THS1206 consists four analog inputs, which sampled simultaneously. These inputs selected individually configured single-ended differential inputs. Internal reference voltages (1.5 provided. Features Supply voltage range: Output interface: parallel reference: internal Simultaneous sampling power: SFDR: 75-dB 100-MHz Parallel UC/DSP interface Glueless interface
THS1206 Functional Block Diagram
AVDD DVDD 1.225 REFOUT
REFP
REFM REFIN AINP VREFP AINM Single Ended and/or Differential BVDD Pipeline FIFO D10/RA0 D11/RA1 BGND VREFM DATA_AV
BINP
Buffers BINM
CONV_CLK (CONVST) (R/W)
Logic Control
Control Register
AGND
DGND
Automotive Selection Guide
2003-2004 Texas Instruments
Pipeline ADCs
THS1408 14-bit, 1/3/8-MSPS with Internal Reference
samples, datasheets, EVMs reports www.ti.com/sc/device/THS1408 THS1408 versatile CMOS with internal reference, differential inputs, programmable input gain, on-chip sample hold amplifier. outstanding price/performance power/speed ratios. They designed 3.3-V systems, with high-speed compatible parallel interface, they ideal choice solutions based high-performance DSPs like C6000 series. Features Sampling rate: MSPS Differential inputs 14-bit resolution Programmable gain amplifier Power-down mode Monolithic CMOS Design Applications Automotive High-speed front-end Networking Radar Oversampling control applications
THS1408 features compatible parallel interface.
Pipeline ADCs Selection Guide
Device ADS5422 ADS5421 ADS850 THS1408 THS1403 THS14F03 THS1401 THS14F01 ADS5410 ADS809 ADS808 ADS807 ADS2807 ADS800 ADS2806 THS1230 ADS801 THS1218 ADS805 THS1215 ADS802 ADS804 THS12082 THS1209 THS1206 THS1207 Resolution (Bits) Sample Rate (MSPS) 2.25 Supply Voltage 3.3, Analog Inputs Power (mW) 1200 Analog Input Bandwidth (MHz) 1000 1000 1000 (±LSB) (±LSB) 0.75 2.75 0.75 (dB) 68.9 Package LQFB LQFP TQFP TQFP TQFP TQFP TQFP TQFP TQFP TQFP TQFP SSOP TQFP SOIC TQFP SOIC, TSSOP SOIC SSOP SSOP SOIC, TSSOP SOIC SSOP SSOP SSOP SSOP SSOP
Texas Instruments 2003-2004
Automotive Selection Guide
Pipeline ADCs Selection Guide (continued)
Device ADS803 ADS828 ADS5102 ADS823 ADS826 ADS5103 ADS5120 ADS5203 ADS5204 ADS821 ADS822 ADS825 THS1040 THS1041 THS1030 THS1031 ADS820 ADS900 ADS901 THS10082 THS1009 THS10064 THS1007 TLV1562 TLV1570 TLV1571 TLV1572 TLV1578 ADS831 TLV5580 ADS830 THS0842 TLC5540 TLV5535 ADS930 ADS931 TLC5510 TLC5510A TLC5733A TLV571 Resolution (Bits) Sample Rate (MSPS) 1.25 1.25 1.25 1.25 1.25 Supply Voltage Analog Inputs Power (mW) Analog Input Bandwidth (MHz) (±LSB) (±LSB) 0.75 0.75 0.75 0.75 (dB) 58.1 Package SSOP SSOP TQFP SSOP SSOP TQFP TQFP TQFP SOIC SSOP SSOP SOIC, TSSOP SOIC, TSSOP SOIC, TSSOP SOIC, TSSOP SOIC SSOP SSOP TSSOP SSOP SSOP SSOP SSOP, SOIC SSOP, SOIC SSOP SSOP SSOP SSOP SOIC, TSSOP SSOP TQFP SOP, TSSOP TSSOP SSOP SSOP SOP, TSSOP SSOP, SOIC
Automotive Selection Guide
2003-2004 Texas Instruments
String DACs
Resistor "String" R-2R DACs consist four major elements: logic circuitry, some type resistor network, means switching either reference voltage current proper input terminals network function digital value each digital input reference voltage. Resistor String Resistor string DACs have inherently monotonic transfer function, thus good performance. They typically inexpensive because high yield need trimming. Their speed limited decoding logic, number interconnections need output buffer avoid error load current. achievable resolution limited finite number bits with which digital world must work.
Resistor matching improves accuracy.
TLV5638 Dual 12-bit with Flexible 3-Wire Serial Interface
samples, datasheets, EVMs reports www.ti.com/sc/device/tlv5638 TLV5638 dual 12-bit voltage output with flexible 3-wire serial interface. serial interface allows glueless interface TMS320 SPITM, QSPITM, Microwireserial ports. programmed with 16-bit serial string containing control data bits. programmable settling time allows designer optimize speed power dissipation. With on-chip programmable precision voltage reference, TLV5638 simplifies overall system design. available 8-pin SOIC package reduce board space automotive temperature ranges. Features Programmable internal reference channels: Differential nonlinearity <0.5 Monotonic over temperature Programmable settling time: fast mode, -3.5 slow mode Single supply operation from
TLV5638 Functional Block Diagram
With Output Enable Voltage Bandgap Power Speed Control 2-Bit Control Latch SCLK Serial Interface Control 12-Bit Latch AGND
Power-On Reset
OUTA
Buffer
12-Bit Latch
OUTB
Texas Instruments 2003-2004
Automotive Selection Guide
String DACs Selection Guide
Resolution Device (Bits) DAC8501 DAC8531 DAC8532 DAC8534 DAC8571 DAC8574 DAC8541 DAC7512 DAC7513 1P=PDIP, U=SOIC, E=SSOP, DAC7571 DAC7574 TLV5610 TLV5613 TLV5614 TLV5616 TLV5618A TLV5619 TLV5630 TLV5633 TLV5636 TLV5638 TLV5639 TLC5615 TLV5604 TLV5606 TLV5608 TLV5617A TLV5631 TLV5637 UCC5950 TLC5628 TLC5620 TLV5623 TLV5625 TLV5626 TLV5627 TLV5628 TLV5629 TLV5632
1P=PDIP,
Settling Number Time Output Output (µs) DACs Interface Serial +VREF/MDAC Serial +VREF Serial +VREF Serial +VREF Serial, +VREF Serial, +VREF +VREF Serial +Vcc Serial +VREF H=Ceramic DIP, N=PLCC SOT-23. Serial, +VREF Serial, +VREF Serial VREF VREF Serial VREF Serial VREF 2.5/ Serial VREF VREF Serial VREF Serial Serial 12.5 Serial VREF Serial VREF Serial VREF Serial VREF 2.5/ Serial VREF Serial VREF Serial Serial +1.1, Serial VREF Serial VREF Serial VREF Serial VREF Serial Serial VREF Serial VREF Serial VREF Serial
VREF
Linearity ±0.096 ±0.096 ±0.096 ±0.096 ±0.096 ±0.096 ±0.096 ±0.38 ±0.38 ±0.096 ±0.096 ±0.4 ±0.1 ±0.1 ±0.1 ±0.08 ±0.08 ±0.4 ±0.08 ±0.1 ±0.1 ±0.1 ±0.1 ±0.05 ±0.15 ±0.4 ±0.1 ±0.4 ±0.1 ±0.2 ±0.4 ±0.4 ±0.2 ±0.2 ±0.4 ±0.2 ±0.4 ±0.4 ±0.4
Monotonic (Bits)
Power Voltage (mW/V) +2.7,+5 +2.7, +2.7, +2.7, 0.85/ +2.7, 0.85/ +2.7, +2.7, 0.7/ +2.7, 0.7/ +2.7, 0.85/ +2.7, 0.85/ +2.7, 1.2/ +2.7, 3.6/ +2.7, 0.9/ +2.7, 2.4/ +2.7, 4.3/ +2.7, 2.7/ +2.7, 4.5/ +2.7, 4.5/ +2.7, 4.5/ +2.7, 0.75/ +2.7, 3.3/ +2.7, 0.9/ +2.7, 2.1/ +2.7, 4.2/ 7.5/ 0.9/ +2.7, 2.1/ +2.7, 5.1/ +2.7, +2.7, +2.7, +2.7, +2.7,
Package1
Number Leads
U=SOIC, E=SSOP, H=Ceramic DIP, N=PLCC SOT-23.
Automotive Selection Guide
2003-2004 Texas Instruments
R-2R DACs
Resistor "String" R-2R DACs consist four major elements: logic circuitry, some type resistor network, means switching either reference voltage current proper input terminals network function digital value each digital input reference voltage. R-2R Ladder DACs R-2R resistor networks implement connection scheme, which makes possible appropriate weight each bit. beauty network fact that only resistors used, This makes matching much easier reflected DAC's accuracy.
Resistor matching improves accuracy.
R-2R DACs Selection Guide
Device DAC712 DAC714 DAC715 DAC716 DAC7631 DAC7632 DAC7634 DAC7641 DAC7642 DAC7643 DAC7644 DAC7731 DAC7734 DAC7741 DAC7742 DAC7744 DAC7611 DAC7612 DAC7613 DAC7614 DAC7615 DAC7616 DAC7617 DAC7621 DAC7624 DAC7625 DAC7714 DAC7715 DAC7724 DAC7725 DAC811 DAC813 TLC7225 TLC7226 TLC7524 TLC7528 TLC7628 TLV5620 TLV5621
1P=PDIP,
Resolution (Bits)
Settling Time (µs)
Number Output DACs
Interface Serial Serial Serial Serial Serial Serial Serial P163 Serial Serial Serial Serial Serial Serial Serial Serial Serial Serial
Output +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +10, ±VREF +10, +10, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF +VREF, ±VREF ±VREF +VREF ±VREF ±VREF ±VREF +VREF +10, +10, VREF VREF VREF VREF
VREF
Linearity ±0.003 ±0.0015 ±0.003 ±0.003 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.0015 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.012 ±0.006 ±0.006 ±0.4 ±0.4 ±0.2 ±0.2 ±0.2 ±0.4 ±0.4
Power Monotonic Voltage (Bits) (mW/V) Package1 600/ 625/ 600/ 625/ 170/ 170/ 170/ 170/ 170/ 2.5/ 170/ 170/ 170/ 170/ 800/ 330/ 7.5/ +11, +2.7, 3.6/ +2.7,
Number Leads 16/20 16/20 16/20 16/20
U=SOIC, E=SSOP, H=Ceramic DIP, N=PLCC SOT-23.
Texas Instruments 2003-2004
Automotive Selection Guide
Current Steering DACs
High-speed DACs from Texas Instruments offer wide range bit, speed channel options maximum design flexibility. matter automotive audio application high-speed solution. products, fabricated using CMOS BiCMOS processes, offer lower power smaller packages provide high-speed performance rely
DAC5675 14-bit, 400-MSPS
samples, datasheets, EVMs reports www.ti.com/sc/device/DAC5675 DAC5675 14-bit, 400-MSPS digital-to-analog converter (DAC) manufactured advanced BiCMOS process. Power dissipation fCLK MSPS, fOUT MHz. providing nominal full-scale differential output current DAC5675 supports both single-ended differential applications. Features 400-MSPS update rate LVDS-compatible input interface SFDR Nyquist: 70-MHz MSPS W-CDMA adjacent channel power ratio: 30.72-MHz 122.88 MSPS 61.44-MHz 245.76 MSPS Differential scalable current outputs: On-chip, 1.2-V reference Single supply: Package: 48-pin HTQFP PowerPAD
DAC5675 Functional Block Diagram
Current Steering DACs Selection Guide
Device DAC5675 DAC904 DAC2904 THS5671A DAC902 DAC2902 THS5661A DAC900 DAC2900 THS5651A DAC908 THS5641A TLC5602 Resolution (Bits) Sample Rate (MSPS) Supply Voltage Settling Time (ns) Number Channels Power (mW) (LSB) 1.75 (LSB) Package HTQFP SOIC, TSSOP TQFP SOIC, TSSOP SOIC, TSSOP TQFP SOIC, TSSOP SOIC, TSSOP TQFP SOIC, TSSOP SOIC, TSSOP SOIC, TSSOP DIP, SOIC
Automotive Selection Guide
2003-2004 Texas Instruments
Voiceband Codecs
Texas Instruments provides complete range low-power, highly integrated voice coding solutions with broadest line leading-edge codecs wireless automotive communications, VoIP telematic systems, hands-free kits, digital handset/headset, voice recognition. 16-bit linear codecs offer highest performance most flexibility voice digitization serial interface codecs perform standard law/µ-law encoding (A/D) decoding (D/A) voice 8-kSPS sampling rate. TI's ultra-low power codecs lowest power voice codecs industry.
TLV320AIC23B Low-Power, Portable Audio Converter
samples, datasheets, EVMs reports www.ti.com/sc/device/partnumber Replace partnumber with TLV320AIC23B TLV320AIC23 high-performance stereo audio codec with highly integrated analog functionality. analog-to-digital converters (ADCs) digital-to-analog converters (DACs) within TLV320AIC23 multibit sigma-delta technology with integrated oversampling digital interpolation filters. sigma-delta modulator enables high-fidelity audio compact, power-saving design. sigma-delta modulator enables high-quality digital audio capability, while consuming less than during playback only. TheTLV320AIC23 ideal analog input/output (I/O) choice digital audio-player applications. Features High-Performance Stereo Codec -90-dB Multibit Sigma-Delta (A-weighted kHz) -100-dB Multibit Sigma-Delta (A-weighted kHz) -1.42 Core Digital Supply: Compatible With C54x Core Voltages -2.7 Buffer Analog Supply: Compatible Both C54x Buffer Voltages Software Control McBSPCompatible Multiprotocol Serial Port -2-wire-Compatible SPICompatible Serial-Port Protocols -Glueless Interface McBSPs Audio-Data Input/Output McBSPCompatible Programmable Audio Interface -I2S-Compatible Interface Requiring Only McBSP both -Standard I2S, MSB, JustifiedData Transfers Applications Audio Systems
TLV320AIC23B Functional Block Diagram
Texas Instruments 2003-2004
Automotive Selection Guide
Voiceband Codecs
TLV320AIC12, TLV320AIC13 Programmable 16-bit Linear Codec
samples, datasheets, EVMs reports www.ti.com/sc/device/partnumber Replace partnumber with TLV320AIC12 TLV320AIC13 TLV320AIC12 true, low-cost, low-power, highly integrated, high-performance voiceband codec. integrates critical functions needed most voiceband applications including pre-amp, handset/headset pre-amps, anti-aliasing filter (AAF), input/output programmable gain amplifier (PGA), selectable low-pass IIR/FIR filters. Implementation SMARTDM(Smart Time Division Multiplexed) Serial Port designed optimize performance offers glue-free interface popular DSPs microprocessors. SMARTDM supports both continuous data transfer mode on-the-fly reconfiguration programming. Features 16-bit oversampling Supports master clock (max) Programmable sampling rate kSPS with on-chip IIR/FIR kSPS with IIR/FIR bypassed ADC: DAC: over 13-kHz kSPS (IIR/FIR bypassed) produced 87-dB Integrated microphone cap-free speaker amplifiers Digital core power: Digital I/O: Analog: Power dissipation: standard operation with headset/ handset drivers Packaging: 30-lead TSSOP Applications Automotive Audio
TLV320AIC12 includes separate host port that selectable between
Voiceband Codecs Selection Guide
Sample Codec Rate (kSPS) (dB) Interface Frame, Pulse Frame, Pulse Pulse SMARTDM1 Pulse SMARTDM Pulse SMARTDM Pulse SMARTDM Pulse SMARTDM Pulse SMARTDM Pulse SMARTDM Pulse SMARTDM Core Power Supply (Digital/ Analog Outputs Analog) (1), 1.8/ (1), 1.8/ 1.8/ 1.8/ (1), (2), 1.8/ (1), (2), 1.8/ (1), 1.8/ (1), 1.8/ Power Dissipation (Without Speaker) Number (mW) Package1 Leads
Device TLV320AIC10 TLV320AIC11 TLV320AIC12 TLV320AIC13 TLV320AIC14 TLV320AIC15 TLV320AIC20 TLV320AIC21 TLV320AIC24 TLV320AIC25
Host Interface I2C, I2C, I2C, I2C, I2C, I2C, I2C, I2C,
Logic
PDIP, SOIC, SSOP, Ceramic, PLCC TQFP.
Automotive Selection Guide
2003-2004 Texas Instruments
Low-Power Audio Codecs/DACs Video ADCs/DACs
Low-Power Audio Codec DACs Selection Guide
Device Description Codec TLV320AIC23 Power Stereo Audio Codec with Internal Headphone High-performance DACs TLV320DAC23 Power Stereo Audio with Headphone PCM1770 PCM1771 PCM1772 PCM1773 Power Stereo Audio with Headphone Power Stereo Audio with Headphone Power Stereo Audio with Line Power Stereo Audio with Line Res. (Bits) (max) Dynamic Range (dB) Sampling Rate (kHz) (max) Supply Voltage Configuration Stereo Audio Data Format Standard I2S, Justified-Data Transfers Standard I2S, Justified-Data Transfers Left-, Right-Justified Left-, Right-Justified Left-, Right-Justified Left-, Right-Justified
Stereo Stereo Stereo Stereo Stereo
Video ADCs Selection Guide
Device THS8083A THS8083A95 TLV5734 Resolution (Bits) Sample Rate (MSPS) Supply Voltage Analog Inputs Power (mw) 1470 1640 Analog Input Bandwidth (MSPS) (LSB) (LSB) 0.75 (dB) Package TQFP
Video DACs Selection Guide
Device THS8135 THS8200 THS8133B THS8134B Resolution (Bits) Sample Rate (MSPS) Analog/Digital 3.3/ 3.3/ Analog Inputs Power (mw) Analog Output Bandwidth (MSPS) (LSB) -0.25 ±0.5 -0.2 ±0.2 (LSB) ±0.6 ±1.5 ±0.5 ±0.2 Package TQFP PQFP TQFP TQFP
Audio DACs Selection Guide
Device Description DACs PCM1772 Low-power stereo audio with Line Amplifier PCM1742 Low-cost audio with volume control PCM1748 Low-cost audio with volume control Multichannel DACs PCM1608 Highly integrated 8-ch audio PCM1602 Low-cost CMOS, multi-level PCM1606 Smallest, low-cost 6-ch Res. (Bits) (max) Dynamic Range (dB) 100/106 100/106 100/105 100/105 Sampling Rate (kHz) (max) Configuration Stereo Stereo Stereo Audio Data Format Normal, Normal, Normal, Normal, Normal, Normal,
Audio ADCs Selection Guide
Device PCM1802 Description audio Res. (Bits) (max) Dynamic Range (dB) Sampling Rate (kHz) (max) Configuration Stereo Audio Data Format Normal,
Stereo Audio CODEC Selection Guide
Device PCM3010 Description audio Res. (Bits) (max) Dynamic Range (dB) Sampling Rate (kHz) (max) Supply Voltage Configuration Stereo
Texas Instruments 2003-2004
Automotive Selection Guide
Interface Solutions
Texas Instruments provides complete interface solutions that empower differentiate your products accelerate time-to-market. expertise high-speed, mixed-signal circuits, system-on-a-chip integration advanced product development processes ensures will receive silicon, support tools, software technical documentation create deliver best products time competitive prices. Included this selection guide will find design considerations, technical overviews, graphic representation portfolios, parametric tables resource information following families devices: LVDS, M-LVDS, RS-485/422, CAN, Controllers Peripheral Devices, CardBus Controllers, Bridges, 1394 UARTS.
LVDS
Things Consider
Primary Signaling Rate-Transmitters receivers capable switching data signaling rates Mbps low-voltage swings, typically Repeaters/translators crosspoint switches Gbps. Power Consumption-LVDS (low-voltage differential signaling) offers low-power solution PECL devices. Current-mode drivers LVDS produce constant current, which allows power consumption relatively independent frequency. constant current driver delivers about 100- load. Secondary Jitter-Reducing jitter, deviation signal timing event from ideal position, become high priority ensuring high reliability high-speed data buses. Skew-Excessive skew, time delta between actual expected arrival time clock signal, limit maximum bandwidth performance lead data sampling errors.
Technical Information
LVDS based TIA/EIA-644 standard conceived provide general-purpose electrical-layer specification drivers receivers connected point-to-point multidrop interface.
LVDM050 LVDM051 Automotive Dual LVDS Transmitter Receiver
samples, datasheets, EVMs reports www.ti.com/sc/device/LVDM050 www.ti.com/sc/device/LVDM051 SN65LVDM050, SN65LVDM051 differential line drivers receivers that low-voltage differential signaling (LVDS) achieve signaling rates high Mbps (per TIA/EIA-644 definition). These circuits similar TIA/EIA-644 standard compliant devices (SN65LVDS) counterparts, except that output current drivers doubled. This modification provides minimum differential output voltage magnitude across load simulating transmission lines parallel. This allows having data buses with more than driver with line termination resistors. receivers detect voltage difference with ground potential difference between transmitter receiver. intended application these devices signaling techniques point-to-point multipoint, baseband data transmission over controlled impedance media approximately 100- characteristic impedance. transmission media printed-circuit board traces, backplanes, cables. SN65LVDM050Q SN65LVDM051Q characterized operation from -40°C 125°C. Features Qualified accordance with Q-100 Customer-Specific Configuration Control Major-Change Approval Protection Exceeds 2000 -STD-883 Operates From Single Supply Propagation Delay Times -Driver: -Receiver: Power Dissipation -Driver: Typical -Receiver: Typical Packaging: 16-pin SOIC
Automotive Selection Guide
2003-2004 Texas Instruments
Texas Instruments 2003-2004 Automotive Selection Guide
LVDS Selection Guide
Peak-to-Peak Part-to-Part Signal Output Jitter Skew Rate Signal (ps) (ps) (Mbps) LVDS LVTTL LVDS 2000 LVPECL 2000 1500 LVTTL, LVDS LVTTL, LVDS LVDS LVTTL 1000 LVTTL 1000 1000 1500 1500 1000 1500 1500 1500 1000 1500 (ns) (ns) (mA) 0.65 Integrated Supply Termination Voltage Available (kV) (100-) Pin/Package 5SOP, 5SOP, 8SOP 8SOP, 8VSSOP 8SOP, 8VSSOP 8SOIC, 8MSOP 8SOP, 8VSSOP 14SOP, 14TSSOP 8HTSSOP, 8SOP, 8VSSOP 8HTSSOP, 8SOP, 8VSSOP 8SOP 8SOP 16SOP, 16VTSSOP 16SOP, 16TSSOP 16SOP, 16TSSOP 16SOP, 16TSSOP 16TSSOP 16SOP, 16TSSOP 16SOP, 16TSSOP 16SOP 16SOP, 16TSSOP 16SOP, 16TSSOP 16SOP, 16TSSOP 16SOP 16SOP, 16TSSOP 16SOP 16SOP 16SOP, 16TSSOP 16SOP, 16VTSSOP 24TSSOP 38TSSOP 38TSSOP 38TSSOP 38TSSOP 64TSSOP 64TSSOP 64TSSOP
Device Name SN65LVDS1 SN65LVDS2 SN65LVDS100 SN65LVDS101 SN65CML100 SN65LVDS179 SN65LVDS180 SN65LVDS9638 SN65LVDS9637 SN65LVDS9637B
Description Single LVDS Transmitter Single LVDS Receiver Gbps Translator/Repeater Gbps Translator/Repeater Gbps Translator/Repeater Single Full-Duplex LVDS Transceiver Single Full-Duplex LVDS Transceiver Dual LVDS Transmitter Dual LVDS Receiver Dual LVDS Receiver Extended Common Mode Range SN65LVDS34 Dual LVDS Receiver w/Extended Common Mode Range SN65LVDS122 Gbps Crosspoint Switch SN65LVDS22 Dual Multiplexed LVDS Repeater SN65LVDS050 Dual LVDS Transmitter/Receiver SN65LVDS051 Dual LVDS Transmitter/Receiver SN65LVDS1050 2.7-V Dual LVDS Transmitter/Receiver SN65LVDS31 Quad LVDS Transmitter SN65LVDS047 Quad LVDS Transmitter Flow-through Pinout SN65LVDS3487 Quad LVDS Transmitter SN65LVDS391 Quad LVDS Transmitter SN65LVDS32 Quad LVDS Receiver SN65LVDS048A Quad LVDS Receiver Flow-through Pinout SN65LVDS3486 Quad LVDS Receiver SN65LVDS390 Quad LVDS Receiver SN65LVDS32B Quad LVDS Receiver w/Extended Common Mode Range SN65LVDS3486B Quad LVDS Receiver w/Extended Common Mode Range SN65LVDS33 Quad LVDS Receiver w/Extended Common Mode Range SN65LVDS348 Quad LVDS Receiver w/Extended Common Mode Range SN65LVDS352 Quad LVDS Receiver w/Extended Common Mode Range SN65LVDS125 Gbps Crosspoint Switch SN65LVDS389 8-Channel LVDS Transmitter SN65LVDS388A 8-Channel LVDS Receiver SN65LVDS109 Dual 4-Port LVDS Repeater SN65LVDS117 Dual 8-Port LVDS Repeater SN65LVDS387 16-Channel LVDS Transmitter SN65LVDS386 16-Channel LVDS Receiver
Input Signal LVTTL LVDS LVPECL, CML, LVDS LVPECL, CML, LVDS LVDS, LVPECL, LVTTL, LVDS LVTTL, LVDS LVTTL LVDS LVDS
LVDS, LVPECL, PECL, LVTTL LVECL, ECL, CMOS, LVCMOS CML, LVPECL, LVDS LVDS LVDS LVDS LVDS, LVTTL LVDS, LVTTL LVDS, LVTTL LVDS, LVTTL LVTTL, LVDS LVTTL, LVDS LVTTL LVDS LVTTL LVDS LVTTL LVTTL LVDS LVDS LVDS LVDS LVDS LVDS LVDS, LVPECL, PECL, LVECL, ECL, CMOS, LVCMOS LVDS, LVPECL, PECL, LVECL, ECL, CMOS, LVCMOS LVDS, LVPECL, PECL, LVECL, ECL, CMOS, LVCMOS CML, LVPECL, LVDS LVTTL LVDS LVDS LVDS LVTTL LVDS LVDS LVDS LVTTL LVTTL LVTTL LVTTL LVTTL LVTTL LVTT LVDS LVDS LVDS LVDS LVTTL LVDS LVDS LVDS LVTTL
1000 1500 1000 1000 1000 1000 1000 1000 1000
Multipoint-LVDS (M-LVDS)
Things Consider
Primary Multipoint (Bidirectional) Capability- M-LVDS (Multipoint-LVDS) enables drivers send signals various receivers. MLVDS, LVDM BLVDS (BusLVDS) double driver's output current achieve this. LVDM BLVDS output current approximately M-LVDS Contention-Situations with multiple active drivers avoided with M-LVDS having drivers high impedance when active, limiting output voltage from limiting short-circuit current Secondary Signaling Rates-The M-LVDS standard specifies 500-Mbps maximum line speed. However, limitations such driver edge rates stub lengths restrict operation approximately Mbps. Termination-A multipoint requires termination both ends; nominal media differential impedance multipoint bus. driver's output current twice that LVDS (TIA/EIA-644) support bidirectional point-to-point buses point-to-point architecture requiring additional noise margin. LVDM BLVDS include many provisions necessary when more than drivers expected multipoint bus, such edge-rate control, contention provision, wired-or signaling, etc.
Technical Information
M-LVDS standard released 2002, Multipoint-LVDS (TIA/EIA-899), brings LVDS benefits multipoint configuration. M-LVDS enables multi-driver connections shared bus. specifies that nodes connected shared signaling rates Mbps. also extends common-mode range additional robustness. Devices standard-compliant interoperability. LVDM BLVDS these proprietary solutions
LVDM176 Half-Duplex LVDM Transceiver
samples, datasheets, EVMs reports www.ti.com/sc/device/LVDM176 SN65LVDM176 differential line driver receiver configured transceiver that uses low-voltage differential signaling (LVDS) achieve signaling rates high Mbit/s. These circuits similar TIA/EIA-644 standard compliant devices (SN65LVDS) counterparts except that output current drivers doubled. This modification provides minimum differential output voltage magnitude into load allows double-terminated lines half-duplex operation. receivers detect voltage difference less than with ground potential difference between transmitter receiver. intended application this device signaling technique half-duplex multiplex baseband data transmission over controlled impedance media approximately 100- characteristic impedance. transmission media printed-circuit board traces, backplanes, cables. (Note: ultimate rate distance data transfer dependent upon attenuation characteristics media, noise coupling environment, other application specific characteristics). Features Protection Exceeds Pins Operates From Single 3.3-V Supply Propagation Delay Times -Driver: -Receiver: Power Dissipation -Driver: Typical -Receiver: Typical LVTTL Levels Tolerant Pins High Impedance When Disabled With Less Than Open-Circuit Fail-Safe Receiver Surface-Mount Packaging: -8-pin Package (SOIC) -8-pin Package (MSOP)
Automotive Selection Guide
2003-2004 Texas Instruments
M-LVDS/LVDM Selection Guide
Device Name SN65MLVD200 SN65MLVD201 SN65MLVD202 SN65MLVD203 SN65MLVD204 SN65MLVD205 SN65MLVD206 SN65MLVD207 SN65LVDM176 SN65LVDM179 SN65LVDM180 SN65LVDM050 SN65LVDM051 SN65LVDM22 SN65LVDM320 SN75LVDM976 SN75LVDM977 SN65LVDM1676 SN65LVDM1677 Description Half-Duplex M-LVDS Transceiver Half-Duplex M-LVDS Transceiver Full-Duplex M-LVDS Transceiver Full-Duplex M-LVDS Transceiver Half-Duplex M-LVDS Transceiver Full-Duplex M-LVDS Transceiver Half-Duplex M-LVDS Transceiver Full-Duplex M-LVDS Transceiver Half-Duplex LVDM Transceiver Full-Duplex LVDM Transceiver Full-Duplex LVDM Transceiver Dual LVDM Transmitter/Receiver Dual LVDM Transmitter/Receiver Dual Multiplexed LVDM Repeater 8-Bit Registered Transceiver 9-Channel LVD-SCSI Transceiver 9-Channel LVD-SCSI Transceiver 16-Channel LVDM Transceiver 16-Channel LVDM Transceiver Integrated Termination Quad LVDM Transmitter Input Signal LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVDM LVCMOS CMOS LVTTL, LVDM LVTTL, LVDM Output Signal LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, M-LVDS LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVTTL, LVDM LVDM LVDM LVD-SCSI LVD-SCSI LVTTL, LVDM LVTTL, LVDM Signal Rate (Mbps) Tx_tpd Rxtpd (ns) (ns) (mA) (kV) Supply Voltage Pin/ Package 8SOP 8SOP 14SOP 14SOP 8SOP 14SOP 8SOP 14SOP 8SOP 8VSSOP 8SOP 8VSSOP 14SOP 14TSSOP 16SOP 16TSSOP 16SOP 16TSSOP 16SOP 16TSSOP 64TSSOP 56SSOP 56TSSOP 56SSOP 56TSSOP 64TSSOP 64TSSOP
SN65LVDM31
LVCMOS
LVDM
16SOP
Texas Instruments 2003-2004
Automotive Selection Guide
RS-485/422
Things Consider
Primary Robustness-Differential transmission mode, ground shifts achieved large common-mode voltage range higher than 12-kV indicate robustness only device, also system. Reliability-Integrated fail-safe circuitry protects from interpreting noise valid data when short-circuit, open-circuit idle line fault conditions occur. Secondary Speed Distance-Low noise coupling differential signaling with twisted-pair cabling wide common-mode voltage range allows data exchange signaling rates Mbps distances several kilometers lower rates. Line Loading-RS-422 capable supporting driver receivers line. RS-485 capable supporting drivers and/or receivers line. However, there reduced unit load devices available that support devices.
Technical Information
main difference between RS-422 RS-485 multidrop multipoint architecture-that driver many receivers many drivers many receivers, respectively. Typical signaling rates distances these standards Mbps offers devices capable reaching signaling rates Mbps.
LBC176 Differential Transceivers
samples, datasheets, EVMs reports www.ti.com/sc/device/LBC176 SN65LBC176A, SN65LBC176AQ, SN75LBC176A differential transceivers monolithic, integrated circuits designed bidirectional data communication multipoint bus-transmission lines. They designed balanced transmission lines compatible with ANSI standard TIA/EIA-485-A 8482. version offers improved switching performance over predecessors without sacrificing significantly more power. SN65LBC176A, SN65LBC176AQ, SN75LBC176A combine 3-state, differential line driver differential input line receiver, both which operate from single power supply. driver receiver have active-high active-low enables, respectively, which externally connect together function direction control. driver differential outputs receiver differential inputs connect internally form differential input/output (I/O) port that designed offer minimum loading whenever driver disabled This port features wide positive negative common-mode voltage ranges, making device suitable party-line applications. Very device supply current achieved disabling driver receiver. Features High-Speed Low-Power LinBiCMOSCircuitry Designed Signaling Rates Mbps Bus-Pin Protection Exceeds Designed Multipoint Transmission Long Lines Noisy Environments Very Disabled Supply-Current Requirements.700 Maximum Common Mode Voltage Range Driver Positive Negative Current Limiting Open-Circuit Fail-Safe Receiver Design Receiver Input Sensitivity.±200 Receiver Input Hysteresis.50 Qualified accordance with Q-100 High Reliability Automotive Applications Configuration Control Print Support Qualification Automotive Standards
Automotive Selection Guide
2003-2004 Texas Instruments
RS-485/422 Selection Guide
Temperature Prefix SN75 SN65, SN75 SN75 SN75 SN65, SN75 SN75 SN75 SN65, SN75 SN65, SN75 SN55, SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65 SN65 SN65 SN65 SN65 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN65, SN75 SN75 SN75 SN75 SN75 SN75 SN75 SN75 SN75 SN65, SN75 SN65, SN75 SN75 SN75 SN75 SN75 SN55, SN65, SN75 SN65, SN75 SN55, SN65, SN75 SN65, SN75 SN55, SN75 SN65, SN75 SN75 SN75 SN55, SN65, SN75 SN65, SN75 SN55, SN65, SN75 SN65, SN75 Device 176A 176B 178B 179B ALS176 ALS176A ALS176B ALS180 ALS181 LBC176 LBC176A LBC179 LBC179A LBC180 LBC180A LBC182 LBC184 HVD05 HVD06 HVD07 HVD20 HVD21 HVD22 HVD23 HVD24 HVD3082E HVD08 HVD10 HVD11 HVD12 1177 1178 ALS1177 ALS1178 ALS170 ALS170A ALS171 ALS171A LBC170 LBC171 ALS172A ALS174A LBC172 LBC172A LBC174 LBC174A ALS173 ALS175 LBC173 LBC173A LBC175 LBC175A Supply Voltage 3.3/5 Signaling Rate (Mpbs) 0.25 (mA) 15.5 15.5 15.5 (kV)
Package(s) DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC, LCCC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC, MSOP DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC SOIC SOIC SOIC SSOP, SOIC SSOP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC CFP, DIP, LCCC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, SOIC DIP, CFP, DIP, LCCC DIP, SOIC CFP, DIP, LCCC DIP, SOIC
Footprint SN75176 SN75176 SN75176 SN75179 SN75176 SN75176 SN75176 SN75ALS180 SN75ALS180 SN75176 SN65176 SN75179 SN75179 SN75LBC180 SN75180 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 SN75176 MC34050 MC34051 MC34050 MC34051 SN75ALS170 SN75ALS170 SN75ALS171 SN75ALS171 SN75ALS170 SN75ALS171 AM26LS31 MC3487 AM26LS31 MC3487 AM26LS31 AM26LS31 MC3487 MC3487 AM26LS32 MC3486 AM26LS32 MC3486 AM26LS32 AM26LS32 MC3486 MC3486
Texas Instruments 2003-2004
Automotive Selection Guide
Things Consider
Primary Fault Protection-Features such short-circuit protection, thermal shutdown protection, glitch-free power-up power-down protection, current-limiting circuitry protect transceivers system from damage during fault condition. Electromagnetic Interference (EMI)- Limited slew-rate features reduce reflection systems generated fast rise times resulting harmonics transceivers. Secondary Supply Voltage-In addition supply transceivers, offers low-voltage supply parts. 3.3-V transceivers save cost 3.3-V powered applications.
Technical Information
ISO11898 describes physical-layer implementation which commonly used automotive industrial applications. This specification describes twisted-wire pair with 120- line impedance differential signaling rate Mbps (typ) 40-meter with multipoint topology.
Family Products
Supply Voltage Transceivers SN65HVD230 Standby mode Integrated slope control Vref SN65HVD231 Sleep mode Integrated slope control Vref SN65HVD232 Cost-effective solution Controller TM320LC2406A TMS320LF2406A TMS320LF2407A TMS320LF2403A TMS320F2810 TMS320F2812 TM320F241 TM320F243 SN65HVD251 Drop-in replacement Philips' PCA82C250 PCA82C251 fault protection nodes 3.3-V
Automotive Selection Guide
2003-2004 Texas Instruments
Controllers Peripheral Devices
Things Consider
Functionality-The manages port connect/disconnect activities including configuration, detection downstream port devices, whether port suspend resume mode, various states port, along with fault reconfiguration, power management full-speed/low-speed support. general, onboard used provide this functionality; however, power management more complex requires additional circuitry. Self-powered hubs local power supply power downstream ports local functions. However, interface allowed draw from upstream port, which used maintain functionality interface while remainder powered down. Self-powered hubs required limit report overcurrent conditions, must supply least each downstream port. Bus-powered hubs obtain power from upstream connection required supply each downstream port. configuration purposes, spec limits buspowered current drawn from less power-up. After, bus-powered allowed consume divided supply each downstream port, with remainder used itself. Because selfpowered hubs experience loss local power either through disconnecting power source depleting battery, controller force reenumeration itself bus-powered hub, requiring implement port power switching external ports. Designers choose between standalone hubs, which offer only ports have embedded CPU, compound hubs, which provide downstream other types connectivity single chip, usually MCU. Peripheral Functionality-A peripheral controller enables connectivity peripheral device either host hub. Unlike host, peripheral does support downstream functions does have upstream facing port that must meet spec requirements. peripheral classified low-power, buspowered function, obtaining power from upstream limited high-power bus-powered function, obtaining power from upstream limited to100 maximum, only power-up during configuration. After, draw self-powered function that obtains power from source other than upstream bus. allowed draw from upstream bus, required spec also requires peripherals obtaining power from upstream facing port transition into suspend mode they constant idle state more than During suspend, device operating low-power mode must limit current consumption maximum. device configured high-power remote wake-up feature enabled, maximum current consumption during suspend Regardless classification peripheral, upstream facing port must meet inrush current requirements specification. amount inrush current function defined amount input capacitance. this reason, specification limits amount input capacitance seen upstream facing port maximum across VBUS ground. device requires more bypass capacitance, then some form surge current limiting must implemented. When working USB-based design selecting components, designer will make number initial decisions. side, much data will need transferred fast will transfer need occur? error correction required? much power will device need? What else will device need answers these questions will determine requirements controller.
Technical Information
Speed three speed modes: speed (LS=1.5 Mbps), full speed (FS=12 Mbps) high speed (HS=480 Mbps). spec requires full backward forward compatibility devices cables. three modes offer both asynchronous isochronous (real-time) data transmission over simple inexpensive four-wire cable meet Texas Instruments 2003-2004 requirements peripherals. Transfer Type four types transfers bulk, control, interrupt, isochronous. Bulk transfer intended applications such printers, scanners mass storage, where rate transfer isn't critical accuracy Interrupt transfer devices such mice, keyboards game pads that must receive host's device's attention periodically, isochronous transfer offers guaranteed delivery time errorchecking automatic retransmission data received with errors, making better choice audio video applications.
Automotive Selection Guide
Controller Technical Information (continued)
Technical Information (cont.)
Supply Voltage compliance with standards, offers controllers designed work with supply voltages peripheral devices that operate with supply voltage Number Ports number ports controller determines number downstream devices manage. Options include ports (TUSB2136), ports (TUSB2036), ports (TUSB2046B), ports (TUSB5D52) ports (TUSB2077A).
Family Products
Devices
Controllers TUSB2036 TUSB2046B TUSB2077A TUSB2136 TUSB5052
Peripherals TUSB3210 TUSB3410 TUSB6250
Selection Guide
Controllers Part Number TUSB2036 TUSB2046B TUSB2077A TUSB2136 TUSB5052 Peripherals Part Number TUSB3210 TUSB3410 TUSB6250 Speed Full (1.1) Full (1.1) Full (1.1) Full (1.1) Full (1.1) Ports Voltage Voltage Remote Wakeup Package 32-Pin LQFP 32-Pin LQFP 48-Pin LQFP 64-Pin LQFP 100-Pin LQFP Notes 2/3-Port with Optional Serial EEPROM Interface 4-Port with Optional Serial EEPROM Interface Supporting Win95/DOS Mode 7-Port with Optional Serial EEPROM Interface 2-Port with Integrated General-Purpose Function Controller 5-Port with Integrated Bridge Serial Ports
Speed Full (1.1) Full (1.1) Full (1.1), High (2.0)
Package 64-Pin LQFP 32-Pin LQFP 80-Pin TQFP
Notes General-Purpose Device Controller RS232/IrDA Serial-to-USB Converter ATA/ATAPI Bridge Solution
Automotive Selection Guide
2003-2004 Texas Instruments
Peripheral Component Interconnect (PCI) interconnection system between microprocessor attached devices which expansion slots spaced closely high-speed operation. This area encompasses CardBus Bridges. cards general provide small, durable upgrade extend system's capabilities. They system add-in, rather than add-on device that attached host through physical cabling. offers most comprehensive line CardBus controllers industry, well bridge products broad family swap powermanagement devices. UltraMediaTechnology UltraMedia technology from offers easy multiple Flash memory cards Smart Cards mobile with simple, low-cost passive adapter. TI's UltraMedia-enabled devices support Memory StickTM, SmartMediaTM, Secure Digital (SD), MulitiMedia Cards (MMC), CompactFlashTM. With this function built into laptop, users avoid expensive cumbersome active CardBus card adapters external dongles available today.
Cardbus Controllers
Things Consider
Controllers-PCI CardBus PCMCIA standard-compliant, 32-bit, high-performance bus-mastering architecture cards. TI's CardBus controllers especially suited mobile systems because compact card inserted completely within host device, eliminating need external cabling. Features Standard, broadly-supported card form-factor connector performance level busmaster capability Low-voltage (3.3-V) operation with standardized power management Ease through plug-and-play hot-plug capabilities CardBus slots offer full backward compatibility Card-16 cards
Technical Information
Performance Provides 32-bit multiplexed address/data path, which yield peak bandwidth Mbps using synchronous burst-transfer orientation PCI. CardBus devices assume control system system-bus masters, allowing "intelligent" system adapters.
Hot-Plug Capability interface allows addition/ removal adapter memory module without disruption system's operation. isolation buffers used carefully connect CardBus adapter's host bus. Low-Power Operation CardBus focused supporting card power reduction, which achieved through operation voltage, software control clock, PCI-like power management mechanism. Mechanical Form Factor Features small, thin mechanical card design 68-pin connector enclosed grounded shield. This shield ensures ground-bounce does corrupt signals even high speeds.
Configuration Approach Like PCI, CardBus allows configuration boot time and/or dynamically during run-time. Whenever cards added removed from system, architecture allows reallocation system resources.
Texas Instruments 2003-2004
Automotive Selection Guide
CardBus Controller Selection Guide
Part Number PCI1410A PCI1420 PCI1510 PCI1520 PCI4410A PCI4451 PCI4510 PCI4520 PCI1620 PCI7410 PCI7510 PCI7610 Voltage 3.3, Cold Wake Integrated 1394 Internal UltraMediaPackage 144-Pin BGA, 209-Pin BGA, 144-Pin LGFP 209-Pin BGA, 208-Pin LGFP 144-Pin BGA, 144-Pin LGFP 209-Pin BGA, 208-Pin LGFP 209-Pin BGA, 208-Pin LGFP 256-Pin BGA, 257-Pin 209-Pin 257-Pin 209-Ball BGA, 208-Pin LQFP 209-Pin 209-Pin 209-Pin Notes Single Slot CardBus Controller Card Controller Single Slot CardBus Controller Dual Slot CardBus Controller Integrated Card Integrated Card Single-Slot CardBus/Dual-Port IEEE 1394a Controller Dual-Slot CardBus/Dual-Port IEEE 1394a Controller Card, Flash Media, SmartCard Controller Card, Flash Media, Integrated 1394a-2000 OHCI 2-Port PHY/Link-Layer Controller Integrated Card, Smart Card 1394 Controller Integrated Card, Smart Card, Flash Media, 1394a-2000 OHCI 2-Port-PHY/Link-Layer Controller
Bridges
Things Consider
bridges function traffic coordinator between buses between host port, allowing bridge transactions occur concurrently both. TI's PCIto-PCI bridges make possible extend system's load capability limit allowing more device slots than single support. Features 32-bit, 66-MHz buses Configurable power-management interface specification CompactPCI hot-swap functionality 3.3-V core logic with 3.3-V signaling compatibility Intel bridge compatibility
Technical Information
Capabilities TI's PCI2050 32-bit, 33-MHz bridge with internal two-tier arbitration nine secondary masters support external secondary bus. There independent read/write buffers each direction secondary clock outputs. Functionality PCI2250 similar PCI2050, supports four secondary (bus) masters five secondary clock outputs. Speed PCI2050B very similar PCI2050 supports clock rates MHz.
Bridges Selection Guide
Part Number PCI2040 Intel® Compatible Part Number Speed Expansion (MHz) Interface (bits) Hot-Swap MicroStar Packaging Voltage Package 3.3, 144-Pin BGA, 144-Pin LQFP Notes PCI-to-DSP Bridge Controller, Compliant CompactPCI Swap Specification 32-Bit, PCI-to-PCI Bridge, Compact Hot-Swap Friendly, 9-Master, MicroStar Packaging 32-Bit, MHz, 9-Master PCI-to-PCI Bridge 32-Bit, PCI-to-PCI Bridge, Compact Hot-Swap Friendly, 4-Master
PCI2050
21150
Friendly
3.3,
209-Pin BGA, 208-Pin LQFP
PCI2050B PCI2250
21150 21152
Friendly
3.3, 3.3,
208-Pin LQFP, 256-Pin `03) 176-Pin LQFP, 160-Pin
Automotive Selection Guide
2003-2004 Texas Instruments
IDB-1394
IDB-1394 specification automotive supplement existing IEEE standards which already well established consumer multimedia applications. Through this standard, those consumer multimedia applications will enabled automobile. addition, existing 1394 portable devices plugged directly into through IDB1394 defined customer convenience port. first IDB-1394 supplier, enables consumers entertainment applications such players, displays, navigation systems, radio head units players/changers their vehicles.
Things Consider
Physical-layer Selection Issues 1394 layer should support minimum number nodes ports required product; having only port leaves product unable support multiple devices connecting bus. Having ports permits spanning other devices through daisychaining. Three more nodes enable branching capabilities. Will product need isolation 1394 interface? cable doesn't provide DC-isolated path from node node. cases where there's possibility various equipment connected across 1394 different ground potentials different power domains, grounds need isolated from each other prevent excessive currents noise. However, ground signal 1394 cable must DC-isolated from power-distribution ground plane. Thus when isolation between units required 1394 interface, frequently performed PHY- Link-layer interfaces- often through special cells that allow capacitive coupling PHY-Link signals. While EIA-775 specification requires minimum speed Mbits/s 1394 interface, using 400-Mbps PHYs recommended. Slower nodes present source speed traps. Almost 1394 silicon available today already 400-Mbps capable.
suspend/resume feature layer lets currently inactive ports achieve low-power states while maintaining their connection status. also permits them quickly resume operation soon they detect applied port bias voltage. Other power-management features include ability enter low-power states when attached Link isn't powered, signalled through (lowpower state) input. layers that fully 1394a compliant, along with suspend/ resume feature, bring such advantages arbitration enhancements, connection debounce, gap-count tuning "ping" packets better efficiency. Link-layer Selection Issues Different types (audio/visual) data require different formatting transmission methods 1394. Specifically identifying which types data must supported fundamental choosing right 1394 chip automotive application. Standards define carry MPEG-2 transport streams both (digital video broadcasting) format DirecTV format, which have different 1394 packetization schemes. Digital video also specified packetized format across 1394. System designers should look 1394 interface chip that automates these format-specific packetizations alleviate need special handling compressed stream prior transmission across 1394, equivalent need receiver's 1394 interface.
Another useful feature 1394 interface controller ability filter actual PIDs (program identifier) MPEG transport stream. Depending type MPEG-2 decoder/demultiplexer used, transport stream that's output from auxiliary interface these parts 1394 controller interbox transport ready demultiplexing yet. cases where MPEG-2 chip doesn't have auxiliary stream output, transport stream need input 1394 interface controller directly from demodulator. either case, stream that's output 1394 interface will contain full contents transport stream, instead only those PIDs related desired program display DTV, selected user. Selecting 1394 Link layer device that filter only those desired PIDs from full transport stream directed processor preserve 1394 bandwidth save headache cost demultiplexing stream manually prior 1394 chip set. Along with filtering, ability insert packets into outgoing transport stream from 1394 Link layer required. cases where particular PIDs removed from transport stream, fundamental MPEG-2 (program association table) (program mapping table) must updated correctly identify now-modified MPEG-2 transport stream. These
Texas Instruments 2003-2004
Automotive Selection Guide
IDB-1394 (continued)
packets best inserted that point when 1394 interface does filtering. allowable number isochronous asynchronous streams simultaneously supported Link layer another feature that should considered. Advanced features DSTB require ability simultaneously support three isochronous streams, well asynchronous streams from peripherals connected 1394 network. Another aspect Link layer that should considered amount data-buffer memory supported. Typically, more bandwidth application requires, more simultaneous isochronous/asynchronous traffic that needs supported, larger buffer memories must 61883-4 specification MPEG-2 transmission, minimum amount buffer memory necessary 1394 receiver 3264 bytes- based single 60-Mbps transport stream. number simultaneous isochronous channels present goes rate individual stream increases, receive buffer needs larger. System designers should analyze various applications that require support determine both maximum MPEG rate maximum number isochronous channels simultaneously present. Then, select 1394 Link layer best meet receive-buffer memory requirements. face standard defines transmission method, media protocol. IDB-1394 Features Real-time streaming audio video High-speed: Mbps Plug-and-play pluggable Peer-to-peer communication Automotive Physical Layer Memory-mapped architecture Seamless interconnect Advanced Power Management
Technical Information
1394-1995 IEEE designation high-performance serial bus. revision this standard been published IEEE 1394a-2000, clarifies adds portions IEEE 13941995 standard. 1394b standard increases speed 1394 800, 1600, 3200 Mbps, well providing connection options such Plastic Optical Fiber (POF), Glass Optical Fiber (GOF), UTP-5. This serial defines both backplane (for example, VME, FB+) physical layer point-to-point, cableconnected virtual bus. backplane version operates 12.5, Mbps, whereas cable version supports data rates 100, 200, 400, 800, 1,600 Mbps across cable medium supported current standard. Both versions totally compatible link layer above. inter-
1394 Family Products
IDB-1394
Integrated Devices
Link Layer Controllers TSB12LV01B TSB12LV21B TSB12LV26 TSB12LV32 TSB15LV01 TSB42AA4 TSB42AA9A TSB82AA2
Physical Layer Controllers TSB14AA1AI TSB41AB3 TSB81BA3 TSB41BA3
Cable Transceivers TSB17BA1
TSB43AB21A TSB43AB22A TSB43AB23 TSB43CA43A TSB43CB43A TSB43CA42
Automotive Selection Guide
2003-2004 Texas Instruments
1394 Selection Guide
1394 Integrated Devices Device Speed Voltage Name (Mbps) FIFOs Package Notes TSB43AB21A 128-Pin TQFP OHCI 1.1, 1394a Link Layer Controller Integrated with 1394a, 400Mbps, 1-Port Physical Layer (PHY) TSB43AB22A 128-Pin TQFP OHCI 1.1, 1394a Link Layer Controller Integrated with 1394a, Mbps, 2-Port Physical Layer (PHY) TSB43AB23 128-Pin TQFP OHCI 1.1-Compliant 1394 Link Layer Controller 1394a-2000-Compliant 3-Port PHY, FIFO TSB43CA43A 16.5 176-Ball iceLynx Micro-5C with Streaming Audio Content Protection TSB43CB43A 16.5 176-Pin iceLynx Micro with Streaming Audio TSB43CA42 176-Pin LQFP TSB43CA42 iceLynx-Micro, Port IEEE 1394a-2000 CES, Abbrew. 1394 Link-Layer Controllers Speed Voltage Device Name (Mbps) FIFOs Package Notes TSB12LV01B 100-Pin TQFP High-Performance Link Layer with 32-Bit I/F, Cycle Master, FIFO. Link Timing Compliant with 1394a-2000 Data Control Applications Backplane Cable TSB12LV32 100-Pin LQFP General-Purpose Link Layer Controller (GPSLynx) TSB12LV26 100-Pin TQFP OHCI 1.0-Compliant 1394a-2000 Link Layer Controller. 32-Bit I/F, FIFO, Pin-Compatible with TSB12LV23 TSB12LV32 100-Pin LQFP 1394a-2000-Compliant Link Layer Camera, Printer Scanner Applications. 8/16-Bit Host I/F, FIFO, High-Speed Data TSB15LV01 80-Pin TQFP Integrated 1394 Link Layer Camera ASIC. High-Performance, Cost-Effective Link Layer Cameras TSB42AA4 128-Pin TQFP High-Performance Link MPEG2, DirecTV Applications. Supports Copy Protection. 16/32-Bit Host I/F, FIFO High-Speed Data TSB42AA9A 100-Pin TQFP StorageLynx, Rev. High-Performance 1394a Link-Layer Controller 1394 Mass Storage Apps TSB42AB4 128-Pin TQFP 1394 Link Layer Controller Consumer Electronics Applications; Drop-In Compatible with TSB42AA4 Does Include Copy Protection TSB82AA2 1.8/3.3 144-Pin LQFP High Performance 1394b, 3.3-V ,OHCI Compliant Link Layer Controller 1394 Physical-Layer Controllers Voltage Speed Device Name Ports (Mbps) Package Notes TSB14AA1 48-Pin TQFP IEEE 1394-1995, 1-Port,50/100_Mbps, Backplane TSB41AB3 80-Pin HTQFP IEEE 1394a Three-Port Cable Transceiver/Arbiter TSB14AA1A1 48-Pin TQFP IEEE 1394-1995, 1-port, 50/100 Mbps, Backplane TSB81BA3 1.8/3.3 80-Pin TQFP IEEE 1394b, s800, Three-Port Cable Transceiver/Arbiter TSB41BA3 80-Pin TQFP IEEE 1394b-2002 3-Port Physical Layer Device 1394 Cable Transceivers Voltage Speed Device Name Ports (Mbps) Package Notes TSB17BA1 24-Pin TSSOP IEEE 1394b-2002 Compliant Cat5 Cable Transceiver meters
Texas Instruments 2003-2004
Automotive Selection Guide
UARTs (Universal Asynchronous Receiver/Transmitters)
Things Consider
industry leading supplier automotive Universal Asynchronous Receiver Transmitters (UARTs), Texas Instruments gives system designers ability increase performance next-generation applications. offers industry's highest performing family parallel-to-serial serial-to-parallel UARTs highly integrated, space-saving configurations that allow designers increase system performance while decreasing space requirements. TI's high performance UART family offers onchip FIFO memories relieving system's processor excessive software overhead buffering received transmitted characters. added enhancement Automatic Flow control feature TI's latest UARTs significantly reduces overhead increases system efficiency automatically controlling serial data flow through. world's leading highvolume semiconductor manufacturers, offers designers OEMs satisfaction knowing they backed supplier with resources meet their needs. These include dedicated marketing technical support team assist with issues. Features Single-, dual- quad-channel devices 64-byte FIFOs available Hardware software auto-flow control Programmable sleep mode low-power mode Industrial temperature characterization 3.3-V supply
UART Selection Guide
Part Number TL16C450 TL16C451 TL16C452 TL16C550C Channels FIFOs None None None 16-Byte Voltage Package 40-Pin DIP, 44-Pin PLCC 68-Pin PLCC 68-Pin PLCC 40-Pin DIP, 44-Pin PLCC, 48-Pin TQFP 68-Pin PLCC, 80-Pin TQFP 68-Pin PLCC, 80-Pin TQFP 68-Pin PLCC, 80-Pin TQFP 68-Pin PLCC, 80-Pin TQFP 44-Pin PLCC, 64-Pin TQFP 48-Pin TQFP 68-Pin PLCC, 80-Pin TQFP 100-Pin TQFP 80-Pin Notes Single UART Single UART with Parallel Port Dual UART with Parallel Port Single UART with Hardware Auto Flow Control
TL16C552 TL16C552A TL16C554 TL16C554A TL16C750 TL16C752B TL16C754B TL16PC564B/BLV TL16PIR552
16-Byte 16-Byte 16-Byte 16-Byte 64-Byte 64-Byte 64-Byte 64-Byte 16-Byte
Dual UART with Parallel Port; Recommend using TL16C552A Dual UART with Parallel Port Quad UART; Recommend using TL16554A Quad UART with Hardware Auto-Flow Control Single UART with Auto-Flow Control, Low-Power Modes Dual UART with Auto-Flow Control Low-Power Modes Quad UART with Auto-Flow Control Low-Power Modes Single UART with PCMCIA Interface Dual UART with Selectable 1284 Modes
Automotive Selection Guide
2003-2004 Texas Instruments
Logic
Things Consider
Texas Instruments offers full spectrum logic functions technologies (mature advanced), including bipolar, BiCMOS CMOS families. geared your one-stop logic shop with over families offered, biggest portfolio industry. committed last major supplier each logic family continues heavily invest technology development market.
Logic Product Life Cycle
2003 1996 1985 1981 1964
Bipolar
CMOS
BiCMOS
CD4000
CBTLV
does cross this line family level.
automotive market typically relies mature CMOS products. Other products have been made available depending customer need. back these families with quality (specific customer requirements and/or Q-100), competitive pricing customer satisfaction.
ALVC ALVT Little Logic GTLP SSTV
Introduction
Growth
Maturity
Decline
Obsolescence
Logic Performance Positioning
GTLP AC/T AHC/T ALVC ALVT CBTLV GTLP HC/T Advanced BiCMOS Technology Advanced CMOS Advanced High Speed CMOS Advanced BiCMOS Advanced Voltage CMOS BiCMOS Technology Advanced Very-LV CMOS Advanced Ultra-LV CMOS BiCMOS Technology Cross Technology Voltage Technology Bipolar Technology Fast CMOS Technology Gunning Transceiver Logic Plus High Speed CMOS Voltage HCMOS Voltage CMOS Voltage BiCMOS Technology
ALVT
GTLP
ALVC
AC/ACT
Features Balanced drive tolerance Hold Option (II(HOLD)) Series damping resistor option Ioff spec partial power down protection noise LVCZ power-up 3state insertion
AHC/AHCT HC/HCT
CBTLV
Speed (ns)
LV-A Features Balanced drive tolerance Ioff spec partial power down protection noise
Texas Instruments 2003-2004
Automotive Selection Guide
High Volume Automotive Logic Families*
Wide supply voltage (3.3 Balanced drive strength tolerance Ioff partial power down Cross Reference LCX-Fairchild, Toshiba LVC-Hitachi, Philips Functions Standard functions WideBus functions LVC1G functions LVC2G functions LVC3G functions
LV-A
Wide supply voltage (5.0 Balanced drive strength tolerance Ioff partial power down Cross Reference LVX/LVQ-Fairchild, Toshiba LV-Hitachi, Philips Functions Standard functions
AHC/AHCT
Wide supply voltage (5.0 Balanced drive strength tolerance AHCT offers inputs with CMOS outputs Cross Reference VHC/VHCT-Fairchild, Toshiba AHC/AHCT- Philips Functions Standard functions WideBus functions AHC1G functions AHCT Standard functions AHCT WideBus functions AHCT1G functions
HC/HCT
Wide supply voltage (5.0 Drive strength offers inputs with CMOS outputs Cross Reference HC/HCT-Fairchild, Hitachi Philips, Toshiba Functions Standard functions Standard functions
CD4K
Wide supply voltage power consumption Cross Reference MC14000-On CD4000-Fairchild Functions Standard functions
Other families are/may provided automotive market.
Low-Voltage Market-Coverage Standardization
(mA)
ALVC
ALVC
ALVC
Speed Performance
speed -8/8-mA drive Ultra-low standby power sources Bus-hold tolerant Ioff
speed -12/12-mA drive standby power sources Bus-hold tolerant Ioff
ALVC
-24/24-mA drive standby power sources Bus-hold
speed -24/24-mA drive Very-low standby power sources Bus-hold tolerant Ioff
(3.3 (2.5 -24/24-mA Very-low standby power sources input tolerant Ioff
13.5 (3.3 -8/8 -4/4 (3.3 sources
(4.5 -8/8 sources
Worldwide
Automotive Selection Guide
2003-2004 Texas Instruments
Q-100 Logic Parts*
Device SN74HC138QPWRQ1 SN74HC14QDRQ1 SN74HC14QPWRQ1 CD74HC20QM96Q1 CD74HC4066QM96Q1 CD74HC4066QPWRQ1 SN74AC11IDRQ1 SN74AC11IPWRQ1 SN74ACT00TDRQ1 SN74AHC02QPWRQ1 SN74AHC04QDRQ1 SN74AHC04QPWRQ1 SN74AHC125QDRQ1 SN74AHC125QPWRQ1 SN74AHC1G00QDCKRQ1 SN74AHC1G08QDCKRQ1 SN74AHC1G32QDCKRQ1 SN74AHC244QDWRQ1 SN74AHC244QPWRQ1 SN74AHC245QDWRQ1 SN74AHC245QPWRQ1 SN74AHC595IPWRQ1 CAHCT1G02QDCKRQ1 CAHCT1G32QDCKRQ1 SN74AHCT244QDWRQ1 SN74AHCT244QPWRQ1 SN74AHCT32QDRQ1 SN74AHCT32QPWRQ1 SN74AHCT573QDWRQ1 SN74HC4060QPWRQ1 SN74HC166AIDRQ1 SN74HC166AIPWRQ1 CD74HCT166TM96Q1 SN74LV08ATPWRQ1 SN74LV123ATPWRQ1 SN74LV14ATPWRQ1 SN74LV374ATPWRQ1 SN74LV4051ATDRQ1 SN74LV4051ATPWRQ1 SN74LV4053ATDRQ1 SN74LV4053ATPWRQ1 SN74LV595AIPWRQ1 SN74LVC1G04IDCKRQ1 SN74LVT125QDRQ1 SN74LVT125QPWRQ1 CD74AC573QM96Q1 CD4093BIM96Q1 Description 3-LINE 8-LINE DECODER/DEMUX SCHMITT TRIGGER SCHMITT TRIGGER DUAL 4-INPUT NAND GATE QUAD BILATERAL SWITCHES QUAD BILATERAL SWITCHES TRIPLE 3-INPUT POSITIVE-AND GATE TRIPLE 3-INPUT POSITIVE-AND GATE QUAD 2-INPUT POSITIVE-NAND GATE QUADRUPLE 2-INPUT POSITIVE GATE INVERTER INVERTER QUAD BUFFER GATES WITH 3-STATE QUAD BUFFER GATES WITH 3-STATE SINGLE 2-INPUT POSITIVE-NAND SINGLE 2-INPUT POSITIVE-AND GATE SINGLE 2-INPUT POSITIVE-OR GATE OCTAL BUFFER/DRIVER OCTAL BUFFER/DRIVER OCTAL TRANSCEIVER OCTAL TRANSCEIVER 8-BIT SHIFT REGISTER W/3-ST REGT SINGLE 2-INPUT POSITIVE-NOR GATE SINGLE 2-INPUT POSITIVE-OR GATE OCTAL BUFFER/DRIVER OCTAL BUFFER/DRIVER QUAD 2-INPUT POS-OR GATE QUAD 2-INPUT POS-OR GATE OCTAL D-TYPE TRANSPARENT LATCH 14-STAGE BINARY COUNTER OSCILLATOR PARALLEL-OUT SERIAL SHIFT PARALLEL-OUT SERIAL SHIFT 8-BIT PARALLEL-IN/SERIAL /SHIFT REGISTER QUADRUPLE 2-INPUT POSITIVE-AND GATE DUAL RETRIGGERABLE MONOSTABLE MULTI SCHMITT-TRIGGER INVERTERS OCTAL D-TYPE FLIP-FLOP W/3STATE ANALOG MULTIPLEXER/DEMULTIPLEXER ANALOG MULTIPLEXER/DEMULTIPLEXER TRIPLE 2-CHAN ANALOG MLTPXR/DLTIPXR TRIPLE 2-CHAN ANALOG MLTPXR/DLTIPXR 8-BIT SHIFT REGISTERS SINGLE INVERTER-GATE QUAD BUFFER GATES WITH 3-STATE QUAD BUFFER GATES WITH 3-STATE OCTAL NON-INVERTING LATCHES WITH 3-STATE CMOS QUAD 2-INPUT NAND SCHMITT TRIGGERS
Q-100 Logic Parts*
Device CD74HC153QM96Q1 SN74HC165QDRQ1 SN74HC165QPWRQ1 CD74HC238QM96Q1 SN74HC253QDRQ1 CD74HC4040QM96Q1 CD74HC564QM96Q1 SN74HCT04IDRQ1 SN74LV4052ATPWRQ1 SN74LVC08ATDRQ1 SN74LVC00AQDRQ1 SN74LVC00AQPWRQ1 SN74LVC04AQDRQ1 SN74LVC04AQPWRQ1 SN74LVC08AQDRQ1 SN74LVC08AQPWRQ1 SN74LVC138AQDRQ1 SN74LVC138AQPWRQ1 SN74LVC14AQDRQ1 SN74LVC14AQPWRQ1 SN74LVC157AQDRQ1 SN74LVC157AQPWRQ1 SN74LVC257AQDRQ1 SN74LVC257AQPWRQ1 SN74LVC32AQDRQ1 SN74LVC32AQPWRQ1 SN74LVC373AQDWRQ1 SN74LVC373AQPWRQ1 SN74LVC374AQDWRQ1 SN74LVC374AQPWRQ1 SN74LVC540AQDWRQ1 SN74LVC540AQPWRQ1 SN74LVC541AQDWRQ1 SN74LVC541AQPWRQ1 SN74LVC573AQDWRQ1 SN74LVC573AQPWRQ1 SN74LVC574AQDWRQ1 SN74LVC574AQPWRQ1 SN74LVC74AQDRQ1 SN74LVC74AQPWRQ1 SN74LVC86AQDRQ1 SN74LVC86AQPWRQ1 SN74LVCH244AQDWRQ1 SN74LVCH244AQPWRQ1 SN74LVCH245AQDWRQ1 SN74LVCH245AQPWRQ1 Description DUAL 4-INPUT MULTIPLEXERS 8-BIT PARALLEL-LOAD SHIFT REGISTERS 8-BIT PARALLEL-LOAD SHIFT REGISTERS 3-TO-8 LINE DECODER DEMULTIPLEXER DUAL LINE DATA SELECTORS/MULTIPLEXERS 12-STAGE BINARY COUNTER OCTAL FLIP-FLOP INVERTER DUAL ANALOG MULTIPLXR/DEMULTIPLXR QUAD 2-INPUT POSITIVE-AND GATE QUAD 2-INPUT POSTIVE-NAND GATE QUAD 2-INPUT POSTIVE-NAND GATE INVERTER INVERTER QUAD 2-INPUT POSITIVE-AND GATE QUAD 2-INPUT POSITIVE-AND GATE 3-TO-8 DECODER/DEMULTIPLEXER 3-TO-8 DECODER/DEMULTIPLEXER SCHMITT-TRIGGER INVERTER SCHMITT-TRIGGER INVERTER QUAD 1-OF-2 DATA SELECTOR/MULTIPLEX QUAD 1-OF-2 DATA SELECTOR/MULTIPLEX QUAD 2-TO-1 DATA SELECTOR/MUX 3QUAD 2-TO-1 DATA SELECTOR/MUX 3QUAD 2-INPUT POSITIVE-OR GATE QUAD 2-INPUT POSITIVE-OR GATE OCTAL TRANSPARENT D-TYPE LATCHES OCTAL TRANSPARENT D-TYPE LATCHES OCTAL EDGE-TRIGGERED OCTAL EDGE-TRIGGERED OCTAL BUFFER/LINE DRIVER WITH 3-STA OCTAL BUFFER/LINE DRIVER WITH 3-STA OCTAL BUFFER/LINE DRIVER WITH 3-STATE OCTAL BUFFER/LINE DRIVER WITH 3-STATE OCTAL D-TYPE TRANSPARENT LATCH OCTAL D-TYPE TRANSPARENT LATCH OCTAL EDGE-TRIGGERED OCTAL EDGE-TRIGGERED DUAL D-TYPE FLIP-FLOP DUAL D-TYPE FLIP-FLOP QUAD 2-INPUT EXCLUSIVE-OR GATE QUAD 2-INPUT EXCLUSIVE-OR GATE OCTAL BUFFER/LINE DRIVER W/BUS HOLD OCTAL BUFFER/LINE DRIVER W/BUS HOLD OCTAL TRANSCEIVER W/BUS HOLD OCTAL TRANSCEIVER W/BUS HOLD
Additional Q-100 logic families soon released include: AHC/AHCT HC/HCT CD4k LV-A
Nomenclature
SN74HC138 Q-100 Compliant Package Temperature Device Name
Texas Instruments 2003-2004
Automotive Selection Guide
Linear Dropout Regulators (LDOs)
LDOs with Noise High PSRTPS79328 Ripple Rejection Frequency
Features
32-µVrms output noise 70-dB PSRR 0.1%/V output line regulation Less than 3-mV load regulation overall accuracy over temperature load Input voltage range: 250-mV dropout 1-µA supply current shutdown mode 170-µA supply current under full load (TPS793xx) Ceramic output capacitor
Applications
noise-sensitive application such audio, Bluetooth wireless
Device1
TPS791xx TPS792xx TPS793xx
(mA)
Peak Current (mA)
1.8/3.3/4.7/adj. 1.8/2.5/2.8/3.0/adj. 1.8/2.5/2.8/2.85/ 3.0/3.3/4.75/adj. TPS794xx 1.8/2.5/2.8/3.0/3.3/adj. TPS795xx 1.6/1.8/2.5/3.0/3.3/adj. 2400 represents digits output voltage; represents adjustable version.
Dual Output LDOs Selection Guide
Output Options (mA) VDO1 VDO2 (mA) (mV) (mV) (µA) 1000 1000 2500 2800 1000 1000 Voltage 3.3/2.5 3.3/1.8 3.3/1.8 3.3/1.5 Accuracy Package Features Noise
Device
Adj.
TPS767D3xx 1000 1000 TPPM0110 1500 TPPM0111 1500 Tantalum
Dual Output FAST with Integrated Outputs Track within Outputs Track within
Description
Dropout Regulators (LDOs) Selection Guide
SOT223 DDPAK MSOP SOT23 TO263 TO220
(mA) (mV) 1000 1000 1500 2000 Negative (µA)
Accuracy SC70
Output Options
Packages
Device TPS769xx TPS791xx TPS765xx TPS793xx TPS775xx TPS776xx TPS767xx TPS768xx TPS753xx TPS752xx TPS763xx TPS71Hxx
Voltage 1.2, 1.5, 1.8, 2.5, 2.7, 2.8, 3.3, 1.8, 3.3, 1.5, 1.8, 2.5, 2.7, 2.8, 3.3, 1.8, 2.5, 2.8, 2.85, 3.3, 4.75 1.5, 1.6, 1.8, 2.5, 1.5, 1.8, 2.5, 2.8, 1.5, 1.8, 2.5, 2.7, 2.8, 3.3, 1.5, 1.8, 2.5, 2.7, 2.8, 3.3, 1.5, 1.8, 2.5, 1.5, 1.8, 2.5, 1.6, 1.8, 2.7, 2.8, 3.3, 3.8, 1.5, 1.8, 2.5,
Adj.
Features1
/EN, /EN, /EN,
Comments Cost Noise; High PSRR Noise, High PSRR Fast Transient Response Fast Transient Response Fast Transient Response Fast Transient Response Fast Transient Response Fast Transient Response Cost Fast Transient Response, High Temp
PowerGood, Active High Enable, Active Enable, Supply Voltage Supervisor Depends VOUT
Ceramic, Tantalum, Capacitor Free
Automotive Selection Guide
2003-2004 Texas Instruments
Standard Linear Voltage Regulators Selection Guide
VOUT/Vref Tolerance VOUT (nom) Over Temp. Device LM317 Adj. (1.2 LM317M Adj. (1.2 UA78Mxx 3.3, LM1117* ADJ, 1.5, 1.8, 2.5, 2.85, 3.3, Scheduled release 1Q04
Accuracy SC70
IOUT (max) (mA) 1500 1000
IOUT Regulation (mA)
(max) (mA)
(typ)
(max)
(max)
VOUT (max)
SOT223
References Shunt Regulators
Things Consider Primary
Topology Shunt (two-terminal) series (three-terminal). Shunt references very similar Zener diodes operation both require external resistor biasing. external resistor determines maximum current that supplied load. Shunt references should considered when load nearly constant power supply variations minimal. Series references require external components they should considered when load variable lower voltage overhead important. They also more immune power supply changes than shunt references. Temperature Drift Temperature drift change output voltage temperature change, expressed ppm/°C. Temperature drift specified several ways (slope, butterfly box) most common method calculated
Technical Information
Both fixed adjustable outputs available. Adjustable output resistor divider connected reference pin. Shunt references regulators require minimum biasing current maintain regulation.
References Shunt Regulators Selection Guide
VOUT /VREF Initial VOUT Tolerance Device Voltage References Shunt Regulators LT1009 REF29xx 1.25, 2.048, 2.5, 3.3, 4.096 REF30xx 1.25, 2.048, 2.5, 3.3, 4.096 TL1431 TL431/A Regulation (µA) 1000 600, 1000 (max) (mA) 0.05 0.05 IOUT (max) (mA) (min) (max) 2.495 Adj. VOUT Range 2.495 Temp (typ) (ppm/°C) Temp (max) (ppm/°C)
Type Shunt Series Series Shunt Shunt
Texas Instruments 2003-2004
DDPAK
MSOP
SOT23
TO263
TO220
Automotive Selection Guide
Switching DC/DC Controllers (non-isolated application) (General Purpose Processor Power)
Things Consider Primary
Input Voltage More than voltage available circuit board. voltage operate controller while another voltage used power conversion section. Choose most suitable voltage that handle amount current needed system. Output Voltage output voltage adjusted down reference voltage controller using voltage divider. Output Current Output current often external power MOSFETs. Paralleling multiple power MOSFETs control higher currents, long MOSFET drivers adequately drive external FETs. Efficiency Higher efficiency will help with thermal issues, since wasted power converted into heat. Higher currents quickly generate more heat, airflow board space must considered.
Secondary
Accuracy Today's advanced processors need better accuracy support lower core voltages. There cost trade-off when more accurate controller needed. System Costs fast transient response time reduces output capacitance. higher currents, this save considerable cost. Also, reducing number external passive components power section save cost. Protection Features Applications that require many expensive processors peripheral single board benefit from long-term reliability ensured implementing controller's protection features.
Technical Information
Voltage current controllers offer fixed frequency operation. Hysteretic control mode features fast transient response time changing load conditions. operating frequency determined mainly output filter characteristics. However, fixed frequency achieved adding small resistor capacitor inputs controller's comparator. On-chip MOSFET drivers enable higher output currents paralleling inexpensive n-channel MOSFETs. implements BiCMOS process where bipolar gate drivers parallel, achieving fast turn-on times higher peak-current capability. PowerPAD packaging, exposed bottom side allows high currents controlled small TSSOP package, eliminating bulky heat sinks. TPS40KSeries Designer oftware able Avail software available. Tool
Switching DC/DC Controllers Selection Guide
(max) Device Power Supply Controllers TPS40050 TPS40051 TPS40053 TPS40060 TPS40061 TPS5120 TPS5130 TL1451A TL5001A (min) Vref Driver Current 0.02 0.02 Output Current (A)1 (each) Varies Depends driver Depends driver Adaptive Multiple Voltage Outputs Positioning Protection2 OCP, UVLO OCP, UVLO OCP, UVLO OCP, UVLO OCP, UVLO OCP, UVLO, OCP, UVLO, UVLO, UVLO, Comments Wide input range sync buck, source only Wide input range sync buck, source/sink except Wide input range sync buck, source/sink Wide input range sync buck, source only Wide input range sync buck, source/sink Dual degree out-of-phase operation buck/1 controllers Dual Buck/Boost Buck/Boost
1Current levels this magnitude beyond supported. 2OCP Over-current protection; UVLO under-voltage lockout; short-circuit protection; power good; over-voltage protection; POR-power-on reset.
Automotive Selection Guide
2003-2004 Texas Instruments
Power Supply Controllers (single output topologies)
Things Consider Control Method
Voltage Mode Simple, noise-free control method wide input output range requirements. Peak Current Mode Fast transient response with built-in current limiting. controllers have on-board high output current drive capability without external MOSFET drivers. Lower start-up current off-line applications (for BiCMOS products with prefix). operating current (for BiCMOS products with prefix) light-load efficiency. Additional programmable minimum duty cycle clamp light load efficiency.
Level Integration
Integrated soft-start (programmable) provides predictable start-up after fault. Internal leading edge blanking suppress switching spike from MOSFET turn-on.
Technical Information
off-line DC/DC power supplies. Single-ended topology power supplies.
Performance
voltage mode controllers have input voltage feedforward instantaneous response input line changes.
Power Supply Controllers Selection Guide (single output topologies)
Typical Power Level Practical Frequency Start-Up Operating Current Current Supply Voltage UVLO: On/Off Vref Vref Tol. Duty Cycle Soft Start Output Voltage Feedforward Internal Drive Leading (Sink/Source) Edge Blanking Available Packages SOIC8, PDIP8 SOIC8, PDIP8 SOIC8, PDIP8 SOIC8, PDIP8 SOIC8, PDIP8 SOIC8, PDIP8 SOIC8, SOIC14, PDIP8 SOIC8, SOIC14, PDIP8 SOIC8, SOIC14, PDIP8 SOIC8, SOIC14, PDIP8
Device UCC2800 UCC2801 UCC2802 UCC2803 UCC2804 UCC2805 UC2842A UC2843A UC2844A UC2845A
Shutdown
Peak Current Mode Controllers
7.2/6.9 9.4/7.4 12.5 12.5/8.3 4.1/3.6 12.5 12.5/8.3 4.1/3.6 16.0/10.0 8.5/7.9 16.0/10.0 8.5/7.9
extra means BiCMOS technology; therefore, UC2842 bipolar UCC2800 BiCMOS.
Texas Instruments 2003-2004
Automotive Selection Guide
DC/DC Converters (Integrated Switch) (SWIFT
Things Consider Primary
Output Voltage Lower voltages required today's advanced DSPs, FPGAs ASICs. Both fixed adjustable output voltage DC/DC converters available. Input Voltage voltage requirements performance processors drop, voltage. 3.3-V rail becoming increasingly popular many applications. Output Current When maximum output current device exceeds application's current consumption, efficiency will higher.
Synchronous Buck DC/DC Converters)
Technical Information
PowerPADpackaging, exposed bottom side allows high currents small TSSOP package, eliminating bulky heatsinks. RDS(ON) MOSFETs synchronous buck topology increase efficiency better thermal management.
TPS55461x Reference Diagram
Secondary
Board Space Integrated MOSFETs externally compensated versions allow passive component flexibility reduce board space. Ease Switchers With Integrated Technology Softw able (SWIFT) designer software Tool tool saves development time speeds designer through external component selection process. software tool downloaded from power.ti.com/swift
SWIFT Selection Guide
Device TPS54310/1/2/3/4/5/6 TPS54610/1/2/3/4/5/6 TPS62000/1/2/3/4/5/6/7/8 TPS54680 Output Current VOUT Package Adj., 0.9, 1.2, 1.5, 1.8, 2.5, HTSSOP Adj., 0.9, 1.2, 1.5, 1.8, 2.5, HTSSOP Adj., 0.9, 1.0, 1.2, 1.5, 1.8, 1.9, 2.5, MSOP HTSSOP
Automotive Selection Guide
2003-2004 Texas Instruments
Supervisors
Things Consider Primary
System Voltages version supervisor require dependent voltage rail(s) within system. example, supervisors designed support processor need selected according voltage driving processor. Number Channels Typically number supervisor functions required system dependent processor peripheral(s) voltages. example, split-voltage processors require supervision both rails, while memory system also require supervision operating third (different) voltage rail. Manual Reset (MR) This feature allows user manually reset circuit control supervisory circuit another device application.
Technical Information
Active High Output Allows processors with active high reset input without additional components. Delay Time Allows voltage other components circuit stabilize first before normal operation starts again.
Secondary
Watchdog Input (WDI) situations where system processor functioning properly, on-board watchdog feature fail reset. Supervisors with integrated watchdog functionality increase system reliability being able trigger reset.
Supervisors Selection Guide
Device TPS3809 TPS3820/8-xx TPS3823 TPS3824-xx TPS3825-xx TPS3836/8 TPS3837 TLC77xx Number Supervisors Supervised Voltages 2.5/3.0/3.3/5.0 3.3/5.0 2.5/3.0/3.3/5.0 2.5/3.0/3.3/5.0 3.3/5.0 1.8/2.5/3.0/3.3 1.8/2.5/3.0/3.3 Adj./2.5/3.3/3.0/5.0 Packages SOT-23 SOT-23 SOT-23 SOT-23 SOT-23 SOT-23 SOT-23 SO-8, DIP-8, TSSOP-8 (typ)(µA) 0.25 0.25 Time Delay (ms) 25/200 10/200 10/200 Prog Manual Active-High OverOver- Watchdog Reset Reset Voltage Current Timer Input/MR Output Detection Detection
devices feature Active-Low Reset Output, except TPS3837.
Texas Instruments 2003-2004
Automotive Selection Guide
Power Management Devices DSPs
TMS320C6000 Platform Non-Portable Applications1
DC/DC Converter (w/FETs) DC/DC Controller Low-Dropout (LDO) Regulator Dual LDO2 TPS62000 TPS40000 TPS76601 TPS70702 TPS62000 TPS40000 REG103 TPS70102 TPS54310 TPS40000 TPS77701 TPS767D301
specific DSP)
Output Current TPS54310 TPS54310 TPS40000 TPS40000 TPS76701 TPS75201 TPS767D301 TPS70302
TPS54610 TPS40000 TPS75601
TPS54610 TPS40000
TPS54910 TPS40000
Supply Voltage Supervisor Dual Supply Voltage Supervisor3
TPS3123J12 TPS3110E12
TPS3801-01 TPS3110K33
Supervised Voltage TPS3123G15 TPS3128E18 TPS3110K33 TPS3305-18
TPS3823-25 TPS3305-25
TPS3823-33
TMS320C5000 Platform Portable Non-Portable Applications1
Step-down Converter (w/FETs) Step-down Controller Dropout (LDO) Regulator Dual LDO2 TPS62200 TPS43000 TPS72201 TPS70702 TPS62200 TPS43000 TPS72101 TPS70702 TPS62100 TPS43000 TPS79401 TPS70702 TPS62000 TPS43000 TPS79501 TPS70102 Output Current TPS54310 TPS43000 TPS77701 TPS767D301 TPS54310 TPS43000 TPS72501 TPS767D301 TPS54310 TPS43000 TPS75201 TPS70302 TPS54610 TPS43000 TPS75601
Supply Voltage Supervisor Dual Supply Voltage Supervisor3
TPS3123G15 TPS3110K33
TPS3106E16 TPS3110K33
Supervised Voltage TPS3128E18 TPS3823-25 TPS3305-18 TPS3305-25
TPS3823-33
TMS320C2000 Platform Non-Portable Applications1
DC/DC Converter (w/FETs) DC/DC Controller Dropout (LDO) Regulator Dual LDO2 TPS62200 TPS40000 TPS72201 TPS70751 TPS62200 TPS40000 TPS72101 TPS70751 TPS62200 TPS40000 TPS79401 TPS70751 TPS62000 TPS40000 TPS79501 TPS70151 Output Current TPS54310 TPS40000 TPS77701 TPS767D318 TPS54310 TPS40000 TPS72501 TPS767D318 TPS54310 TPS40000 TPS75201 TPS70351 TPS54610 TPS40000 TPS75601
Supply Voltage Supervisor Dual Supply Voltage Supervisor3
Supervised Voltage TPS3128E18 TPS3823-33 TPS3305-18
1Adjustable output voltage part numbers shown. Fixed voltages also available. 2Current shown powering core. current capability dual rated approximately core current. 3Other supervised voltage
Automotive Selection Guide
2003-2004 Texas Instruments
Power Control Products
Things Consider
high level integration, Power+ICs maintain significant cost advantage- including reduced component count board space requirements, along with minimized procurement inventory expenses- over discretes per-transistor basis. Power+ devices offer superior alternatives discrete power MOSFETs hybrids many power switching applications including LEDs, lamps, solenoids, valves, relays, fractional horsepower motors.
Technical Information
Integrated DMOS drivers offer costeffective alternatives Drive multiple loads reduce printed circuit board space Reduced component count improve system reliability Input transient protection ESD-
sensitive applications Current-limit capability applications with high inrush stall current Built-in output clamp diodes enhanced inductive switching Onboard diagnostics improved fault isolation shorter down-time Fault protection with hysteresis increased system reliability Power performance standard surfacemount packaging
Power+ LogicTM: 8-Bit Devices
Device1 TPIC6259 TPIC6273 TPIC6595 TPIC6596 TPIC6A2591 TPIC6A5951 TPIC6A2561 TPIC6B2592 TPIC6B2732 TPIC6B5952 TPIC6B5962 TPIC6C5952 TPIC6C5962 TPIC28102 Description Addressable Latch D-Type Latch Sh
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