µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 D Qualification in Accordance With D D D D D D D D High Output Drive Capability AEC-Q100† Qualified for Automotive Applications Customer-Specific Configuration Control Can Be Supported Along With Major-Change Approval ESD Protection Exceeds 2000 V Per MIL-STD-883, Method 3015; Exceeds 200 V Using Machine Model (C = 200 pF, R = 0) CMOS Rail-To-Rail Input/Output Input Bias Current . . . 2.5 pA Low Supply Current . . . 600 µA/Channel Gain-Bandwidth Product . . . 2.8 MHz − ±10 mA at 180 mV − ±35 mA at 500 mV Input Offset Voltage . . . 250 µV (typ) Supply Voltage Range . . . 2.7 V to 6 V D D TLV2471 D PACKAGE (TOP VIEW) NC IN − IN + GND 1 8 2 7 3 6 4 5 NC VDD OUT NC † Contact Texas Instruments for details. Q100 qualification data available on request. description The TLV247x is a family of CMOS rail-to-rail input/output operational amplifiers that establishes a new performance point for supply current versus ac performance. These devices consume just 600 µA/channel while offering 2.8 MHz of gain-bandwidth product. Along with increased ac performance, the amplifier provides high output drive capability, solving a major shortcoming of older micropower operational amplifiers. The TLV247x can swing to within 180 mV of each supply rail while driving a 10-mA load. For non-RRO applications, the TLV247x can supply ±35 mA at 500 mV off the rail. Both the inputs and outputs swing rail-to-rail for increased dynamic range in low-voltage applications. This performance makes the TLV247x family ideal for sensor interface, portable medical equipment, and other data acquisition circuits. The family is fully specified at 3 V and 5 V across the automotive temperature range (− 40°C to 125°C). FAMILY TABLE DEVICE NUMBER OF CHANNELS UNIVERSAL EVM BOARD TLV2471 1 TLV2472 2 TLV2474 4 See the EVM selection guide (SLOU060) A SELECTION OF SINGLE-SUPPLY OPERATIONAL AMPLIFIER PRODUCTS‡ DEVICE VDD (V) VIO (µV) BW (MHz) SLEW RATE (V/µs) IDD (per channel) (µA) OUTPUT DRIVE RAIL-TO-RAIL TLV247X 2.7 − 6 250 2.8 1.5 600 ±35 mA I/O TLV245X 2.7 − 6 20 0.22 0.11 23 ±10 mA I/O TLV246X 2.7 − 6 150 6.4 1.6 550 ±90 mA I/O TLV277X 2.5 − 6 360 5.1 10.5 1000 ±10 mA O ‡ All specifications measured at 5 V. Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet. Copyright 2004 Texas Instruments Incorporated ! ! $%&'()*+$'% $, -.((/%+ *, '& 0.12$-*+$'% 3*+/ ('3.-+, -'%&'() +' ,0/-$&$-*+$'%, 0/( +/ +/(), '& /*, %,+(.)/%+, ,+*%3*(3 4*((*%+5 ('3.-+$'% 0('-/,,$%6 3'/, %'+ %/-/,,*($25 $%-2.3/ +/,+$%6 '& *22 0*(*)/+/(, POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 1 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 ORDERING INFORMATION† ORDERABLE PART NUMBER PACKAGE TA −40°C −40 C to 125 125°C C −40°C −40 C to 125 125°C C −40°C to 125°C TOP-SIDE MARKING SOP − D Tape and reel TLV2471QDRQ1 2471Q1 SOP − D Tape and reel TLV2471AQDRQ1 2471AQ SOT23 − DBV Tape and reel TLV2471QDBVRQ1 471Q SOP − D Tape and reel TLV2472QDRQ1 2472Q1 SOP − D Tape and reel TLV2472AQDRQ1 2472AQ MSOP − DGN Tape and reel TLV2472QDGNRQ1‡ SOP − D Tape and reel TLV2474QDRQ1 2474Q1 SOP − D Tape and reel TLV2474AQDRQ1 2474AQ1 TSSOP − PWP Tape and reel TLV2474QPWPRQ1 2474Q1 TSSOP − PWP Tape and reel TLV2474APWPRQ1 2474AQ1 † Package drawings, standard packing quantities, thermal data, symbolization, and PCB design guidelines are available at www.ti.com/sc/package. ‡ Product Preview. TLV247x PACKAGE PINOUTS TLV2471 DBV PACKAGE (TOP VIEW) OUT GND IN+ 1 5 VDD 2 3 4 TLV2474 D OR PWP PACKAGE TLV2472 D OR DGN PACKAGE (TOP VIEW) IN− 1OUT 1IN − 1IN + GND 1 8 2 7 3 6 4 5 (TOP VIEW) VDD 2OUT 2IN − 2IN+ NC − No internal connection 2 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 1OUT 1IN − 1IN+ VDD 2IN+ 2IN − 2OUT 1 14 2 13 3 12 4 11 5 10 6 9 7 8 4OUT 4IN − 4IN+ GND 3IN+ 3IN − 3OUT µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 absolute maximum ratings over operating free-air temperature range (unless otherwise noted)† Supply voltage, VDD (see Note 1) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7 V Differential input voltage, VID . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ± VDD Continuous total power dissipation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . See Dissipation Rating Table Operating free-air temperature range, . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −40°C to 125°C Maximum junction temperature, TJ . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 150°C Storage temperature range, Tstg . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −65°C to 150°C Lead temperature 1,6 mm (1/16 inch) from case for 10 seconds . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 260°C † Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability. NOTE: All voltage values, except differential voltages, are with respect to GND. DISSIPATION RATING TABLE PACKAGE θJC (°C/W) θJA (°C/W) TA ≤ 25°C POWER RATING D (8) 38.3 176 710 mW D (14) 26.9 122.3 1022 mW DBV (3) 55 324.1 385 mW DGN (8) 4.7 52.7 2370 mW PWP (14) 2.07 30.7 4070 mW recommended operating conditions Single supply Supply voltage, VDD Split supply Common-mode input voltage range, VICR Operating free-air temperature, TA † Relative to GND MIN MAX 2.7 6 ±1.35 ±3 0 VDD 125 −40 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 UNIT V V °C 3 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 electrical characteristics at specified free-air temperature, VDD = 3 V (unless otherwise noted) PARAMETER VIO Input offset voltage αVIO Temperature coefficient of input offset voltage IIO Input offset current IIB Input bias current TEST CONDITIONS TLV247x VIC = VDD/2, VO = VDD/2, RS = 50 Ω High-level output voltage MIN VIC = VDD/2, VO = VDD/2, RS = 50 Ω VIC = VDD/2, VO = VDD/2, RS = 50 Ω VIC = VDD/2, VO = VDD/2, RS = 50 Ω Full range 1.5 2 Full range VIC = VDD/2 VIC = VDD/2 Sinking VO = 0.5 V from rail AVD Large-signal differential voltage amplification ri(d) Differential input resistance CIC Common-mode input capacitance f = 10 kHz zo Closed-loop output impedance f = 10 kHz, Common-mode rejection ratio VIC = 0 to 3 V, RS = 50 Ω CMRR kSVR IDD Supply voltage rejection ratio ((∆V VDD //∆V VIO) Supply current (per channel) VO(PP) = 1 V, 25°C 2.85 Full range 2.8 25°C 2.6 Full range 2.5 RL = 10 kΩ AV = 10 VIC = VDD /2, VDD = 3 V to 5 V, No load VIC = VDD /2, No load † Full range is −40°C to 125°C. If not specified, full range is − 40°C to 125°C. 4 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 50 50 pA 2.94 V 2.74 0.07 0.15 0.2 0.35 Full range 0.2 Full range V 0.5 25°C 30 Full range 20 25°C 30 Full range 20 mA ±22 25°C VDD = 2.7 V to 6 V, No load VO = 1.5 V, µV/°C V/°C 300 25°C Short-circuit output current µV V 300 25°C Sourcing Output current 1600 UNIT 1800 Full range IOL = 10 mA IO 2200 250 25°C IOL = 2.5 mA IOS 250 2400 25°C Low-level output voltage MAX 0.4 IOH = − 10 mA VOL TYP Full range 25°C TLV247xA IOH = − 2.5 mA VOH TA† 25°C 25°C 90 Full range 88 mA 116 dB 25°C 1012 Ω 25°C 19.3 pF 2 Ω 25°C 25°C 58 Full range 56 25°C 68 Full range 60 25°C 70 Full range 60 25°C Full range 78 dB 90 dB 92 550 750 800 µA µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 operating characteristics at specified free-air temperature, VDD = 3 V (unless otherwise noted) PARAMETER SR Slew rate at unity gain Vn Equivalent input noise voltage In Equivalent input noise current TEST CONDITIONS VO(PP) = 0.8 V, RL = 10 kΩ CL = 150 pF, TA† 25°C MIN TYP 1.1 1.4 Full range 0.6 f = 100 Hz 25°C 28 25°C 15 25°C 0.405 Total harmonic distortion plus noise VO(PP) = 2 V, RL = 10 kΩ, f = 1 kHz AV = 1 AV = 10 Gain-bandwidth product f = 10 kHz, RL = 600 Ω V(STEP)PP = 2 V, AV = −1, CL = 10 pF, RL = 10 kΩ 0.1% V(STEP)PP = 2 V, AV = −1, CL = 56 pF, RL = 10 kΩ 0.1% RL = 10 kΩ, CL = 1000 pF 25°C 61° Gain margin RL = 10 kΩ, CL = 1000 pF † Full range is −40°C to 125°C. If not specified, full range is − 40°C to 125°C. ‡ Depending on package dissipation rating 25°C 15 THD + N ts φm Settling time Phase margin POST OFFICE BOX 655303 nV/√Hz pA /√Hz 0.02% 25°C 25 C AV = 100 0.1% 0.5% 25°C 2.8 MHz 1.5 0.01% 3.9 µss 25°C 1.6 0.01% • DALLAS, TEXAS 75265 UNIT V/ s V/µs f = 1 kHz f = 1 kHz MAX 4 dB 5 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 electrical characteristics at specified free-air temperature, VDD = 5 V (unless otherwise noted) PARAMETER VIO Input offset voltage αVIO Temperature coefficient of input offset voltage IIO Input offset current IIB Input bias current TEST CONDITIONS TLV247x VIC = VDD/2, VO = VDD/2, RS = 50 Ω High-level output voltage MIN VIC = VDD/2, VO = VDD/2, RS = 50 Ω VIC = VDD/2, VO = VDD/2, RS = 50 Ω VIC = VDD/2, VO = VDD/2, RS = 50 Ω Full range 1.7 2.5 Full range VIC = VDD/2 VIC = VDD/2 Sinking VO = 0.5 V from rail AVD Large-signal differential voltage amplification ri(d) Differential input resistance CIC Common-mode input capacitance f = 10 kHz zo Closed-loop output impedance f = 10 kHz, Common-mode rejection ratio VIC = 0 to 5 V, RS = 50 Ω CMRR kSVR IDD Supply voltage rejection ratio ((∆V VDD //∆V VIO) Supply current (per channel) VO(PP) = 3 V, 25°C 4.85 Full range 4.8 25°C 4.72 Full range 4.65 RL = 10 kΩ AV = 10 VIC = VDD /2, VDD = 3 V to 5 V, No load VIC = VDD /2, No load † Full range is −40°C to 125°C. If not specified, full range is − 40°C to 125°C. 6 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 50 50 pA 4.96 V 4.82 0.07 0.15 0.178 0.28 Full range 0.2 Full range V 0.35 25°C 110 Full range 60 25°C 90 Full range 60 mA ±35 25°C VDD = 2.7 V to 6 V, No load VO = 2.5 V, µV/°C V/°C 300 25°C Short-circuit output current µV V 300 25°C Sourcing Output current 1600 UNIT 2000 Full range IOL = 10 mA IO 2200 250 25°C IOL = 2.5 mA IOS 250 2400 25°C Low-level output voltage MAX 0.4 IOH = − 10 mA VOL TYP Full range 25°C TLV247xA IOH = − 2.5 mA VOH TA† 25°C 25°C 92 Full range 91 mA 120 dB 25°C 1012 Ω 25°C 18.9 pF 1.8 Ω 25°C 25°C 62 Full range 58 25°C 68 Full range 60 25°C 70 Full range 60 25°C Full range 84 dB 90 dB 92 600 900 1000 µA µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 operating characteristics at specified free-air temperature, VDD = 5 V (unless otherwise noted) PARAMETER SR Slew rate at unity gain Vn Equivalent input noise voltage In Equivalent input noise current THD + N ts φm TEST CONDITIONS VO(PP) = 2 V, RL = 10 kΩ CL = 150 pF, TYP 1.1 1.5 Full range 0.7 25°C 28 25°C 15 f = 1 kHz 25°C VO(PP) = 4 V, RL = 10 kΩ, f = 1 kHz Gain-bandwidth product f = 10 kHz, RL = 600 Ω V(STEP)PP = 2 V, AV = −1, CL = 10 pF, RL = 10 kΩ 0.1% V(STEP)PP = 2 V, AV = −1, CL = 56 pF, RL = 10 kΩ 0.1% RL = 10 kΩ, CL = 1000 pF POST OFFICE BOX 655303 25°C 25 C 0.39 nV/√Hz pA /√Hz 0.05% 0.3% 25°C 2.8 MHz 1.8 0.01% 3.3 µss 25°C 1.7 0.01% • DALLAS, TEXAS 75265 UNIT 0.01% AV = 100 Gain margin RL = 10 kΩ, CL = 1000 pF † Full range is −40°C to 125°C for Q suffix. If not specified, full range is − 40°C to 125°C. MAX V/ s V/µs f = 100 Hz Total harmonic distortion plus noise Phase margin MIN f = 1 kHz AV = 1 AV = 10 Settling time TA† 25°C 3 25°C 68° 25°C 23 dB 7 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 TYPICAL CHARACTERISTICS Table of Graphs FIGURE VIO IIB Input offset voltage vs Common-mode input voltage 1, 2 IIO VOH Input offset current vs Free-air temperature 3, 4 VOL Zo High-level output voltage vs High-level output current 5, 7 Low-level output voltage vs Low-level output current 6, 8 IDD PSRR Output impedance vs Frequency 9 Supply current vs Supply voltage 10 Power supply rejection ratio vs Frequency 11 CMRR Common-mode rejection ratio vs Frequency 12 Vn VO(PP) Equivalent input noise voltage vs Frequency 13 Maximum peak-to-peak output voltage vs Frequency 14, 15 AVD φm Differential voltage gain and phase vs Frequency 16, 17 Phase margin vs Load capacitance 18, 19 Gain margin vs Load capacitance 20, 21 Gain-bandwidth product vs Supply voltage 22 vs Supply voltage 23 SR Input bias current Slew rate vs Free-air temperature 24, 25 Crosstalk vs Frequency THD+N Total harmonic distortion + noise vs Frequency 27, 28 VO Large and small signal follower vs Time 29 − 32 8 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 26 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 TYPICAL CHARACTERISTICS 600 TA=25° C 200 0 −200 −400 −600 −800 −0.5 0.0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 VICR − Common-Mode Input Voltage − V 400 TA=25 °C 200 0 −200 −400 −600 −800 −0.5 0.5 1.5 2.5 3.5 4.5 5.5 VICR − Common-Mode Input Voltage − V INPUT BIAS AND INPUT OFFSET CURRENTS vs FREE-AIR TEMPERATURE IIB 10 0 IIO −10 −55 −35 −15 5 25 45 65 85 105 125 TA − Free-Air Temperature − °C VDD=3 V 3.0 2.5 2.0 TA=125°C 1.5 TA=85°C 1.0 TA=25°C 0.5 TA=−40°C 0 3.5 3.0 1.5 TA=25°C 0.5 TA=−40°C 0.0 TA=−40°C 1.0 0.5 10 20 30 40 50 IOL − Low-Level Output Current − mA Figure 6 20 40 60 80 100 120 140 160 IOH − High-Level Output Current − mA OUTPUT IMPEDANCE vs FREQUENCY 1000 4.5 TA=125°C 4.0 TA=85°C 3.5 VDD=3 & 5 V TA=25°C TA=25°C 3.0 TA=−40°C 2.5 2.0 1.5 1.0 100 AV=100 10 AV=10 1 AV=1 0.1 0.5 VDD=5 V 0.0 Figure 7 TA=25°C 1.5 0 Z o − Output Impedance − Ω 4.0 1.0 TA=85°C LOW-LEVEL OUTPUT VOLTAGE vs LOW-LEVEL OUTPUT CURRENT VOL − Low-Level Output Voltage − V 4.5 TA=85°C TA=125°C 2.0 10 20 30 40 50 60 IOH − High-Level Output Current − mA 5.0 VDD=5 V TA=125°C VDD=3 V 2.5 Figure 5 5.5 2.0 IIO 0.0 0.0 HIGH-LEVEL OUTPUT VOLTAGE vs HIGH-LEVEL OUTPUT CURRENT 2.5 0 3.0 Figure 4 5.0 10 LOW-LEVEL OUTPUT VOLTAGE vs LOW-LEVEL OUTPUT CURRENT VOL − Low-Level Output Voltage − V 20 V OH − High-Level Output Voltage − V I IB − Input Bias Current − pA I IO − Input Offset Current − pA 30 IIB 20 Figure 3 3.5 40 30 HIGH-LEVEL OUTPUT VOLTAGE vs HIGH-LEVEL OUTPUT CURRENT 50 VDD=5 V 40 −10 −55 −35 −15 5 25 45 65 85 105 125 TA − Free-Air Temperature − °C Figure 2 Figure 1 0 VDD=3 V I IB − Input Bias Current − pA 400 50 VDD=5 V I IO − Input Offset Current − pA VDD=3 V VIO − Input Offset Voltage − µ V VIO − Input Offset Voltage − µ V 600 V OH − High-Level Output Voltage − V INPUT BIAS AND INPUT OFFSET CURRENTS vs FREE-AIR TEMPERATURE INPUT OFFSET VOLTAGE vs COMMON-MODE INPUT VOLTAGE INPUT OFFSET VOLTAGE vs COMMON-MODE INPUT VOLTAGE 0 20 40 60 80 100 120 140 IOL − Low-Level Output Current − mA Figure 8 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 0.01 100 1k 10k 100k f − Frequency − Hz 1M 10M Figure 9 9 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 TYPICAL CHARACTERISTICS POWER SUPPLY REJECTION RATIO vs FREQUENCY TA=125°C 0.7 0.6 TA=25°C 0.5 TA=−40°C 0.4 0.3 0.2 AV= 1 SHDN= VDD Per Channel 0.1 0.0 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD − Supply Voltage − V PSRR+ 90 80 PSRR− 70 60 50 40 30 10 6.0 100 80 VDD=3 & 5 V AV= 10 VIN= VDD/2 TA=25°C 50 40 30 20 10 0 10 100 1k 10k f − Frequency − Hz 100k V O(PP) − Maximum Peak-To-Peak Output Voltage − V V n − Equivalent Input Noise Voltage − nV/ Hz EQUIVALENT NOISE VOLTAGE vs FREQUENCY 60 1k 10k 100k f − Frequency − Hz 5.0 4.5 VO(PP)=5 V 4.0 3.5 3.0 2.5 VO(PP)=3 V 2.0 1.5 1.0 0.5 0.0 10k 100k f − Frequency − Hz 1M VDD=5 V 90 VIC=2.5 V 80 70 60 50 100 VDD=3 V VIC=1.5 V 1k 10k 100k f − Frequency − Hz 0 −45 40 −90 20 −135 0 −180 −20 −225 1M 10k 100k Frequency − Hz 10M −270 100M 10M MAXIMUM PEAK-TO-PEAK OUTPUT VOLTAGE vs FREQUENCY 5.5 THD+N ≤ 2.0% RL=600 Ω TA=25°C 5.0 4.5 4.0 VO(PP)=5 V 3.5 3.0 2.5 2.0 VO(PP)=3 V 1.5 1.0 0.5 0.0 10k 100k f − Frequency − Hz 1M DIFFERENTIAL VOLTAGE GAIN AND PHASE vs FREQUENCY 45 VDD=±5 RL=600 Ω CL=0 TA=25°C 80 60 0 −45 40 −90 20 −135 0 −180 −20 −225 −40 100 1k 10k 100k 1M Frequency − Hz Figure 17 POST OFFICE BOX 655303 1M Figure 15 Figure 16 10 100 100 Phase − ° AVD − Differential Voltage Gain − dB THD+N ≤ 2.0% RL=10 kΩ TA=25°C 45 VDD=±3 RL=600 Ω CL=0 TA=25°C 1k 110 Figure 14 100 60 120 Figure 12 5.5 DIFFERENTIAL VOLTAGE GAIN AND PHASE vs FREQUENCY 80 10M MAXIMUM PEAK-TO-PEAK OUTPUT VOLTAGE vs FREQUENCY Figure 13 −40 100 1M 130 Figure 11 Figure 10 70 VDD=3 & 5 V RF=5 kΩ RI=50 Ω TA=25°C V O(PP) − Maximum Peak-To-Peak Output Voltage − V TA=85°C 0.8 100 AVD − Differential Voltage Gain − dB I DD − Supply Current − mA 0.9 • DALLAS, TEXAS 75265 10M −270 100M Phase − ° 1.0 COMMON-MODE REJECTION RATIO vs FREQUENCY CMRR − Common-Mode Rejection Ratio − dB PSRR − Power Supply Rejection Ratio − dB SUPPLY CURRENT vs SUPPLY VOLTAGE µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 TYPICAL CHARACTERISTICS PHASE MARGIN vs LOAD CAPACITANCE PHASE MARGIN vs LOAD CAPACITANCE 90 60 Rnull=100 80 50 Rnull=20 40 30 20 10 Rnull=0 Rnull=100 50 40 15 Rnull=20 25 1k 10k CL − Load Capacitance − pF Figure 18 Rnull=50 30 100 100k 1k 10k CL − Load Capacitance − pF Figure 19 GAIN MARGIN vs LOAD CAPACITANCE 4.0 5 3.5 SLEW RATE vs SUPPLY VOLTAGE 2.0 15 Rnull=20 20 Rnull=50 Rnull=100 VDD=5V RL=10 kΩ TA=25°C 30 3.0 RL=600 Ω 2.5 2.0 1.5 CL=11 pF f=10 kHz TA=25°C 1.0 1k 10k CL − Load Capacitance − pF 100k 3.0 3.5 4.0 4.5 5.0 5.5 VDD − Supply Voltage − V 0.6 VO(PP)=1.5 V AV=−1 RL=10 kΩ CL=150 pF 2.5 3.0 3.5 4.0 4.5 5.0 5.5 VDD − Supply Voltage − V 6.0 Figure 23 SLEW RATE vs FREE-AIR TEMPERATURE 2.00 1.75 1.75 SR+ SR− 1.00 0.75 0.25 0.8 Figure 22 2.00 0.50 1.0 6.0 SLEW RATE vs FREE-AIR TEMPERATURE 1.25 1.2 0.0 2.5 Figure 21 1.50 SR+ 1.4 0.2 0.5 0.0 35 100 SR− 1.6 0.4 SR − Slew Rate − V/µs 25 SR − Slew Rate − V/µs Gain Margin − dB 10 RL=10 kΩ SR − Slew Rate − V/µs Gain-Bandwidth Product − MHz 1.8 Rnull=0 100k Figure 20 GAIN-BANDWIDTH PRODUCT vs SUPPLY VOLTAGE 0 Rnull=100 20 Rnull=0 0 100 100k 10 Rnull=20 20 10 1k 10k CL − Load Capacitance − pF 5 60 30 VDD=3V RL=10 kΩ TA=25°C Rnull=50 70 Rnull=0 0 100 0 VDD=5V RL=10 kΩ TA=25°C See Figure 42 90 Gain Margin − dB 70 Rnull=50 φ m − Phase Margin − ° φ m − Phase Margin − ° 100 VDD=3 V RL=10 kΩ TA=25°C See Figure 42 80 GAIN MARGIN vs LOAD CAPACITANCE VDD=3 V RL=10 kΩ CL=150 pF AV=−1 SR+ 1.25 1.00 0.75 0.50 0.25 0.00 −55 −35 −15 5 25 45 65 85 105 125 TA − Free-Air Temperature − °C SR− 1.50 VDD=5 V RL=10 kΩ CL=150 pF AV=−1 0.00 −55 −35 −15 5 25 45 65 85 105 125 TA − Free-Air Temperature − °C Figure 24 Figure 25 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 11 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 TYPICAL CHARACTERISTICS VDD = 3V & 5V AV = 1 RL= 600Ω VI(PP)=2V All Channels −20 Crosstalk − dB −40 −60 −80 −100 −120 −140 −160 1k 100 10 k f − Frequency − Hz 10 100 k TOTAL HARMONIC DISTORTION PLUS NOISE vs FREQUENCY 1 AV = 100 AV = 10 0.1 AV = 1 0.01 VDD = 3 V RL = 10 kΩ V0 = 2 VPP TA = 25°C 0.001 10 100 1k TOTAL HARMONIC DISTORTION PLUS NOISE vs FREQUENCY THD+N−Total Harmonic Distortion + Noise 0 THD+N−Total Harmonic Distortion + Noise CROSSTALK vs FREQUENCY AV = 100 AV = 10 0.1 AV = 1 0.01 VDD = 5 V RL = 10 kΩ V0 = 4 VPP TA = 25°C 0.001 10 100k 10k 1 100 f − Frequency − Hz Figure 26 Figure 27 LARGE SIGNAL FOLLOWER PULSE RESPONSE vs TIME LARGE SIGNAL FOLLOWER PULSE RESPONSE vs TIME VI (50 mV/DIV) VDD = 3 V RL = 10 kΩ CL = 8 pF f = 85 kHz TA = 25°C 3 4 5 6 t − Time − µs 7 8 9 10 VO (1 V/DIV) VDD = 5 V RL = 10 kΩ CL = 8 pF f = 85 kHz TA = 25°C 0 1 2 Figure 29 3 4 5 6 t − Time − µs VO (50 mV/DIV) 7 8 9 10 Figure 30 VI (50 mV/DIV) V O − Output Voltage VDD = 5 V RL = 10 kΩ CL = 8 pF f = 1 MHz TA = 25°C VO (50 mV/DIV) 100 200 300 t − Time − µs 400 500 Figure 32 12 POST OFFICE BOX 655303 0 100 200 300 t − Time − µs Figure 31 SMALL SIGNAL FOLLOWER PULSE RESPONSE vs TIME 0 VDD = 3 V RL = 10 kΩ CL = 8 pF f = 1 MHz TA = 25°C V O − Output Voltage V O − Output Voltage V O − Output Voltage VO (1 V/DIV) 2 100k SMALL SIGNAL FOLLOWER PULSE RESPONSE vs TIME VI (2 V/DIV) 1 10k Figure 28 VI (2 V/DIV) 0 1k f − Frequency − Hz • DALLAS, TEXAS 75265 400 500 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 PARAMETER MEASUREMENT INFORMATION Rnull _ + RL CL Figure 33 APPLICATION INFORMATION driving a capacitive load When the amplifier is configured in this manner, capacitive loading directly on the output decreases the device’s phase margin leading to high frequency ringing or oscillations. Therefore, for capacitive loads of greater than 10 pF, it is recommended that a resistor be placed in series (RNULL) with the output of the amplifier, as shown in Figure 34. A minimum value of 20 Ω should work well for most applications. RF RG RNULL _ Input Output + CLOAD Figure 34. Driving a Capacitive Load offset voltage The output offset voltage, (VOO) is the sum of the input offset voltage (VIO) and both input bias currents (IIB) times the corresponding gains. The following schematic and formula can be used to calculate the output offset voltage. RF IIB− RG + − VI IIB+ V OO +V IO ǒ ǒ ǓǓ 1) R R F G VO + RS "I IB) R S ǒ ǒ ǓǓ 1) R R F G "I IB– R F Figure 35. Output Offset Voltage Model POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 13 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general configurations When receiving low-level signals, limiting the bandwidth of the incoming signals into the system is often required. The simplest way to accomplish this is to place an RC filter at the noninverting terminal of the amplifier (see Figure 36). RG RF − VO + VI R1 C1 f V O + V I ǒ 1) R R F G –3dB Ǔǒ + 1 2pR1C1 Ǔ 1 1 ) sR1C1 Figure 36. Single-Pole Low-Pass Filter If even more attenuation is needed, a multiple pole filter is required. The Sallen-Key filter can be used for this task. For best results, the amplifier should have a bandwidth that is 8 to 10 times the filter frequency bandwidth. Failure to do this can result in phase shift of the amplifier. C1 + _ VI R1 R1 = R2 = R C1 = C2 = C Q = Peaking Factor (Butterworth Q = 0.707) R2 f C2 RG RF RG = Figure 37. 2-Pole Low-Pass Sallen-Key Filter 14 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 –3dB + ( 1 2pRC RF 1 2− Q ) µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION circuit layout considerations To achieve the levels of high performance of the TLV247x, follow proper printed-circuit board design techniques. A general set of guidelines is given in the following. D Ground planes − It is highly recommended that a ground plane be used on the board to provide all components with a low inductive ground connection. However, in the areas of the amplifier inputs and output, the ground plane can be removed to minimize the stray capacitance. D Proper power supply decoupling − Use a 6.8-µF tantalum capacitor in parallel with a 0.1-µF ceramic capacitor on each supply terminal. It may be possible to share the tantalum among several amplifiers depending on the application, but a 0.1-µF ceramic capacitor should always be used on the supply terminal of every amplifier. In addition, the 0.1-µF capacitor should be placed as close as possible to the supply terminal. As this distance increases, the inductance in the connecting trace makes the capacitor less effective. The designer should strive for distances of less than 0.1 inches between the device power terminals and the ceramic capacitors. D Sockets − Sockets can be used but are not recommended. The additional lead inductance in the socket pins often leads to stability problems. Surface-mount packages soldered directly to the printed-circuit board is the best implementation. D Short trace runs/compact part placements − Optimum high performance is achieved when stray series inductance has been minimized. To realize this, the circuit layout should be made as compact as possible, thereby minimizing the length of all trace runs. Particular attention should be paid to the inverting input of the amplifier. Its length should be kept as short as possible. This helps to minimize stray capacitance at the input of the amplifier. D Surface-mount passive components − Using surface-mount passive components is recommended for high performance amplifier circuits for several reasons. First, because of the extremely low lead inductance of surface-mount components, the problem with stray series inductance is greatly reduced. Second, the small size of surface-mount components naturally leads to a more compact layout thereby minimizing both stray inductance and capacitance. If leaded components are used, it is recommended that the lead lengths be kept as short as possible. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 15 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general PowerPAD design considerations The TLV247x is available in a thermally-enhanced PowerPAD family of packages. These packages are constructed using a downset leadframe upon which the die is mounted [see Figure 38(a) and Figure 38(b)]. This arrangement results in the lead frame being exposed as a thermal pad on the underside of the package [see Figure 38(c)]. Because this thermal pad has direct thermal contact with the die, excellent thermal performance can be achieved by providing a good thermal path away from the thermal pad. The PowerPAD package allows for both assembly and thermal management in one manufacturing operation. During the surface-mount solder operation (when the leads are being soldered), the thermal pad can also be soldered to a copper area underneath the package. Through the use of thermal paths within this copper area, heat can be conducted away from the package into either a ground plane or other heat dissipating device. The PowerPAD package represents a breakthrough in combining the small area and ease of assembly of surface mount with the, heretofore, awkward mechanical methods of heatsinking. DIE Side View (a) Thermal Pad DIE End View (b) Bottom View (c) NOTE A: The thermal pad is electrically isolated from all terminals in the package. Figure 38. Views of Thermally Enhanced DGN Package Although there are many ways to properly heatsink the PowerPAD package, the following steps illustrate the recommended approach. Thermal Pad Area Quad Single or Dual 68 mils x 70 mils) with 5 vias (Via diameter = 13 mils Figure 39. PowerPAD PCB Etch and Via Pattern PowerPAD is a trademark of Texas Instruments Incorporated. 16 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 78 mils x 94 mils) with 9 vias (Via diameter = 13 mils) µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general PowerPAD design considerations (continued) 1. Prepare the PCB with a top side etch pattern as shown in Figure 39. There should be etch for the leads as well as etch for the thermal pad. 2. Place five holes (dual) or nine holes (quad) in the area of the thermal pad. These holes should be 13 mils in diameter. Keep them small so that solder wicking through the holes is not a problem during reflow. 3. Additional vias may be placed anywhere along the thermal plane outside of the thermal pad area. This helps dissipate the heat generated by the TLV247x IC. These additional vias may be larger than the 13-mil diameter vias directly under the thermal pad. They can be larger because they are not in the thermal pad area to be soldered so that wicking is not a problem. 4. Connect all holes to the internal ground plane. 5. When connecting these holes to the ground plane, do not use the typical web or spoke via connection methodology. Web connections have a high thermal resistance connection that is useful for slowing the heat transfer during soldering operations. This makes the soldering of vias that have plane connections easier. In this application, however, low thermal resistance is desired for the most efficient heat transfer. Therefore, the holes under the TLV247x PowerPAD package should make their connection to the internal ground plane with a complete connection around the entire circumference of the plated-through hole. 6. The top-side solder mask should leave the terminals of the package and the thermal pad area with its five holes (dual) or nine holes (quad) exposed. The bottom-side solder mask should cover the five or nine holes of the thermal pad area. This prevents solder from being pulled away from the thermal pad area during the reflow process. 7. Apply solder paste to the exposed thermal pad area and all of the IC terminals. 8. With these preparatory steps in place, the TLV247x IC is simply placed in position and run through the solder reflow operation as any standard surface-mount component. This results in a part that is properly installed. For a given θJA, the maximum power dissipation is shown in Figure 40 and is calculated by the following formula: P Where: D + ǒ T Ǔ –T MAX A q JA PD = Maximum power dissipation of TLV247x IC (watts) TMAX = Absolute maximum junction temperature (150°C) TA = Free-ambient air temperature (°C) θJA = θJC + θCA θJC = Thermal coefficient from junction to case θCA = Thermal coefficient from case to ambient air (°C/W) POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 17 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general PowerPAD design considerations (continued) MAXIMUM POWER DISSIPATION vs FREE-AIR TEMPERATURE Maximum Power Dissipation − W 7 6 5 4 PWP Package Low-K Test PCB θJA = 29.7°C/W TJ = 150°C SOT-23 Package Low-K Test PCB θJA = 324°C/W DGN Package Low-K Test PCB θJA = 52.3°C/W SOIC Package Low-K Test PCB θJA = 176°C/W 3 2 1 0 −55 −40 −25 −10 5 20 35 50 65 80 95 110 125 TA − Free-Air Temperature − °C NOTE A: Results are with no air flow and using JEDEC Standard Low-K test PCB. Figure 40. The next consideration is the package constraints. The two sources of heat within an amplifier are quiescent power and output power. The designer should never forget about the quiescent heat generated within the device, especially multi-amplifier devices. Because these devices have linear output stages (Class A-B), most of the heat dissipation is at low output voltages with high output currents. Figure 41 to Figure 46 show this effect, along with the quiescent heat, with an ambient air temperature of 70°C and 125°C. When using VDD = 3 V, there is generally not a heat problem with an ambient air temperature of 70°C. But, when using VDD = 5 V, the packages are severely limited in the amount of heat it can dissipate. The other key factor when looking at these graphs is how the devices are mounted on the PCB. The PowerPAD devices are extremely useful for heat dissipation. But, the device should always be soldered to a copper plane to fully use the heat dissipation properties of the PowerPAD. The SOIC package, on the other hand, is highly dependent on how it is mounted on the PCB. As more trace and copper area is placed around the device, θJA decreases and the heat dissipation capability increases. The currents and voltages shown in these graphs are for the total package. For the dual or quad amplifier packages, the sum of the RMS output currents and voltages should be used to choose the proper package. 18 POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general PowerPAD design considerations (continued) TLV2471† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS 180 Maximum Output Current Limit Line 160 140 B Packages With θJA ≤ 110°C/W at TA = 125°C or θJA ≤ 355°C/W at TA = 70°C 120 100 A 80 60 | IO | − Maximum RMS Output Current − mA | IO | − Maximum RMS Output Current − mA 180 Safe Operating Area 40 VDD = ± 3 V TJ = 150°C TA = 125°C 20 0 0 0.25 TLV2471† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS Maximum Output Current Limit Line 160 140 B 120 100 A 80 Packages With θJA ≤ 210°C/W at TA = 70°C 60 40 VDD = ± 5 V TJ = 150°C TA = 125°C 20 0 0.5 0.75 1 1.5 1.25 0 0.5 | VO | − RMS Output Voltage − V B Packages With θJA ≤ 55°C/W at TA = 125°C or θJA ≤ 178°C/W at TA = 70°C 80 60 40 VDD = ± 3 V TJ = 150°C TA = 125°C 20 0 0 0.25 Safe Operating Area 180 0.75 2.5 Maximum Output Current Limit Line 160 140 120 100 C 80 B 60 1 1.25 1.5 Packages With θJA ≤ 105°C/W at TA = 70°C 40 20 0 0.5 2 TLV2472† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS | IO | − Maximum RMS Output Current − mA | IO | − Maximum RMS Output Current − mA 140 100 1.5 Figure 42 TLV2472† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS 180 Maximum Output Current Limit Line 160 C 1 | VO | − RMS Output Voltage − V Figure 41 120 Safe Operating Area 0 VDD = ± 5 V TJ = 150°C TA = 125°C 0.5 Safe Operating Area 1 1.5 2 2.5 | VO | − RMS Output Voltage − V | VO | − RMS Output Voltage − V Figure 44 Figure 43 † A − SOT23(5); B − SOIC (8); C − SOIC (14); D − TSSOP PP (14) POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 19 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION general PowerPAD design considerations (continued) TLV2474† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS 180 Maximum Output Current Limit Line 160 140 | IO | − Maximum RMS Output Current − mA | IO | − Maximum RMS Output Current − mA 180 D 120 100 Packages With θJA ≤ 88°C/W C at TA = 70°C 80 60 40 VDD = ±3 V TJ = 150°C TA = 125°C 20 0 0 0.25 TLV2474† MAXIMUM RMS OUTPUT CURRENT vs RMS OUTPUT VOLTAGE DUE TO THERMAL LIMITS Safe Operating Area Maximum Output Current Limit Line 160 140 D 120 100 80 VDD = ± 5 V TJ = 150°C TA = 125°C 60 40 0.75 1 1.25 1.5 Safe Operating Area 0 | VO | − RMS Output Voltage − V 0.5 1 Figure 45 Figure 46 POST OFFICE BOX 655303 1.5 2 | VO | − RMS Output Voltage − V † A − SOT23(5); B − SOIC (8); C − SOIC (14); D − TSSOP PP (14) 20 Packages With θJA ≤ 52°C/W at TA = 70°C 20 0 0.5 C • DALLAS, TEXAS 75265 2.5 µ !" " "# SGLS180A − AUGUST 2003 − REVISED OCTOBER 2004 APPLICATION INFORMATION macromodel information Macromodel information provided was derived using Microsim Parts, the model generation software used with Microsim PSpice. The Boyle macromodel (see Note 1) and subcircuit in Figure 47 are generated using the TLV247x typical electrical and operating characteristics at TA = 25°C. Using this information, output simulations of the following key parameters can be generated to a tolerance of 20% (in most cases): D D D D D D D D D D D D Maximum positive output voltage swing Maximum negative output voltage swing Slew rate Quiescent power dissipation Input bias current Open-loop voltage amplification Unity-gain frequency Common-mode rejection ratio Phase margin DC output resistance AC output resistance Short-circuit output current limit NOTE 1: G. R. Boyle, B. M. Cohn, D. O. Pederson, and J. E. Solomon, “Macromodeling of Integrated Circuit Operational Amplifiers,” IEEE Journal of Solid-State Circuits, SC-9, 353 (1974). 3 99 VDD + egnd rd1 rd2 rss ro2 css fb rp − c1 7 11 12 + c2 vlim 1 + r2 9 6 IN+ − vc D D 8 + − vb ga 2 G G − IN− ro1 gcm ioff 53 S S OUT dp 91 10 iss GND 4 ve + 54 90 dln + hlim − + dc − dlp vlp − 5 92 − vln + de * TLV247x operational amplifier ”macromodel” subcircuit * created using Parts release 8.0 on 4/27/99 at 14:31 * Parts is a MicroSim product. * * connections: non−inverting input * | inverting input * | | positive power supply * | | | negative power supply * | | | | output * | | | | | .subckt TLV247x 1 2 3 4 5 * c1 11 12 1.1094E−12 c2 6 7 5.5000E−12 css 10 99 556.53E−15 dc 5 53 dy de 54 5 dy dlp 90 91 dx dln 92 90 dx dp 4 3 dx egnd 99 0 poly(2) (3,0) (4,0) 0 .5 .5 fb 7 99 poly(5) vb vc ve vlp vln 0 + 39.614E6 −1E3 1E3 40E6 −40E6 ga 6 0 11 12 79.828E−6 gcm 0 6 10 99 32.483E−9 iss hlim ioff j1 j2 r2 rd1 rd2 ro1 ro2 rp rss vb vc ve vlim vlp vln .model .model .model .model .ends *$ 10 90 0 11 12 6 3 3 8 7 3 10 9 3 54 7 91 0 dx dy jx1 jx2 4 dc 10.714E−6 0 vlim 1K 6 dc 75E−9 2 10 jx1 1 10 jx2 9 100.00E3 11 12.527E3 12 12.527E3 5 10 99 10 4 3.8023E3 99 18.667E6 0 dc 0 53 dc .842 4 dc .842 8 dc 0 0 dc 110 92 dc 110 D(Is=800.00E−18) D(Is=800.00E−18 Rs=1m Cjo=10p) NJF(Is=1.0825E−12 Beta=594.78E−06 + Vto=−1) NJF(Is=1.0825E−12 Beta=594.78E−06 + Vto=−1) Figure 47. Boyle Macromodel and Subcircuit PSpice and Parts are trademarks of MicroSim Corporation. POST OFFICE BOX 655303 • DALLAS, TEXAS 75265 21 PACKAGE OPTION ADDENDUM www.ti.com 25-Feb-2005 PACKAGING INFORMATION Orderable Device Status (1) Package Type Package Drawing Pins Package Eco Plan (2) Qty Lead/Ball Finish MSL Peak Temp (3) TLV2471AQDRQ1 ACTIVE SOIC D 8 2500 CU NIPDAU Level-2-250C-1 YEAR/ Level-1-235C-UNLIM TLV2471QDBVRQ1 ACTIVE SOT-23 DBV 5 3000 Green (RoHS & no Sb/Br) CU NIPDAU Level-1-260C-UNLIM TLV2472AQDRQ1 ACTIVE SOIC D 8 2500 Pb-Free (RoHS) CU NIPDAU Level-2-250C-1 YEAR/ Level-1-235C-UNLIM TLV2472QDRQ1 ACTIVE SOIC D 8 2500 Pb-Free (RoHS) CU NIPDAU Level-2-250C-1 YEAR/ Level-1-235C-UNLIM TLV2474APWPRQ1 ACTIVE HTSSOP PWP 14 2000 None Call TI TLV2474AQDRQ1 ACTIVE SOIC D 14 2500 Pb-Free (RoHS) CU NIPDAU Level-2-250C-1 YEAR/ Level-1-235C-UNLIM TLV2474QDRQ1 ACTIVE SOIC D 14 2500 Pb-Free (RoHS) CU NIPDAU Level-2-250C-1 YEAR/ Level-1-235C-UNLIM TLV2474QPWPRQ1 ACTIVE HTSSOP PWP 14 2000 None Call TI Pb-Free (RoHS) Level-1-220C-UNLIM Level-1-220C-UNLIM (1) The marketing status values are defined as follows: ACTIVE: Product device recommended for new designs. LIFEBUY: TI has announced that the device will be discontinued, and a lifetime-buy period is in effect. NRND: Not recommended for new designs. Device is in production to support existing customers, but TI does not recommend using this part in a new design. PREVIEW: Device has been announced but is not in production. Samples may or may not be available. OBSOLETE: TI has discontinued the production of the device. (2) Eco Plan - May not be currently available - please check http://www.ti.com/productcontent for the latest availability information and additional product content details. None: Not yet available Lead (Pb-Free). Pb-Free (RoHS): TI's terms "Lead-Free" or "Pb-Free" mean semiconductor products that are compatible with the current RoHS requirements for all 6 substances, including the requirement that lead not exceed 0.1% by weight in homogeneous materials. Where designed to be soldered at high temperatures, TI Pb-Free products are suitable for use in specified lead-free processes. Green (RoHS & no Sb/Br): TI defines "Green" to mean "Pb-Free" and in addition, uses package materials that do not contain halogens, including bromine (Br) or antimony (Sb) above 0.1% of total product weight. (3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDECindustry standard classifications, and peak solder temperature. Important Information and Disclaimer:The information provided on this page represents TI's knowledge and belief as of the date that it is provided. TI bases its knowledge and belief on information provided by third parties, and makes no representation or warranty as to the accuracy of such information. Efforts are underway to better integrate information from third parties. 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