TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 2.5-W MONO FILTER-FREE CLASS-D AUDIO POWER AMPLIFIER FEATURES APPLICATIONS • Pin-to-Pin Compatibility with TPA2010D1 • 32 ms Start-up Time Eliminates CODEC Click/Pop noise • Maximum Battery Life and Minimum Heat – Efficiency With an 8-Ω Speaker: – 88% at 400 mW – 2.8-mA Quiescent Current – 0.5-µA Shutdown Current • Only Three External Components – Optimized PWM Output Stage Eliminates LC Output Filter – Improved PSRR (–75 dB) and Wide Supply Voltage (2.5 V to 5.5 V) Eliminates Need for a Voltage Regulator – Fully Differential Design Reduces RF Rectification and Eliminates Bypass Capacitor – Improved CMRR Eliminates Two Input Coupling Capacitors • Wafer Chip Scale Packaging (WCSP) – NanoFree™ (YZF) • 1 2 Ideal for Wireless or Cellular Handsets and PDAs DESCRIPTION The TPA2031D1 is a 2.5-W high efficiency filter-free class-D audio power amplifier in a 1,45 mm × 1,45 mm wafer chip scale package (WCSP) that requires only three external components. Features like 88% efficiency, –75-dB PSRR, improved RF-rectification immunity, and 8 mm2 total PCB area make the TPA2031D1 class-D amp ideal for cellular handsets. 32 ms start-up time allows the TPA2031D1 to share the same GPIO enable/shutdown control as the CODEC without passing through the CODEC turn-on pop. In cellular handsets, the earpiece, speaker phone, and melody ringer can each be driven by the TPA2031D1. The TPA2031D1 allows independent gain while summing signals from separate sources, and has a low 36 µV noise floor, A-weighted. APPLICATION CIRCUIT To Battery Internal Oscillator + RI Differential Input - RI VDD CS IN_ PWM 9-BALL WAFER CHIP SCALE YZF PACKAGE TPA2031D1 DIMENSIONS (TOP VIEW OF PCB) VO+ HBridge VO- + 1,55 mm 1,40 mm IN+ IN+ GND VO- A1 A2 A3 VDD PVDD GND B1 B2 B3 GND SHUTDOWN Bias Circuitry INTPA2031D1 C1 SHUTDOWN VO+ C2 C3 1,55 mm 1,40 mm Note: Pin A1 is marked with a “0” for Pb-free (YZF). 1 2 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. NanoFree is a trademark of Texas Instruments. PRODUCTION DATA information is current as of publication date. Products conform to specifications per the terms of the Texas Instruments standard warranty. Production processing does not necessarily include testing of all parameters. Copyright © 2008, Texas Instruments Incorporated TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com These devices have limited built-in ESD protection. The leads should be shorted together or the device placed in conductive foam during storage or handling to prevent electrostatic damage to the MOS gates. ORDERING INFORMATION (1) TA PACKAGE –40°C to 85°C Wafer chip scale packaging – Lead free (YZF) PART NUMBER TPA2031D1YZF SYMBOL (1) CEI The YZF package is only available taped and reeled. Add the suffix R to the end of the part number for a reel of 3000 (e.g., TPA2031D1YZFR); or, add the suffix T for a reel of 250 (e.g., TPA2031D1YZFT). ABSOLUTE MAXIMUM RATINGS over operating free-air temperature range unless otherwise noted (1) TPA2031D1 VDD Supply voltage VI Input voltage In active mode –0.3 V to 6 V In SHUTDOWN mode –0.3 V to 7 V –0.3 V to VDD + 0.3 V Continuous total power dissipation See Dissipation Rating Table TA Operating free-air temperature –40°C to 85°C TJ Operating junction temperature –40°C to 150°C Tstg Storage temperature –65°C to 150°C (1) 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 are 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. RECOMMENDED OPERATING CONDITIONS MIN NOM MAX UNIT VDD Supply voltage 2.5 5.5 VIH High-level input voltage SHUTDOWN V 1.3 VDD V VIL Low-level input voltage SHUTDOWN RI Input resistor Gain ≤ 20 V/V (26 dB) 0 0.35 VIC Common mode input voltage range VDD = 2.5 V, 5.5 V, CMRR ≤ –49 dB 0.5 VDD–0.8 V TA Operating free-air temperature –40 85 °C 15 V kΩ PACKAGE DISSIPATION RATINGS (1) 2 PACKAGE DERATING FACTOR (1) TA ≤ 25°C POWER RATING TA = 70°C POWER RATING TA = 85°C POWER RATING YZF 7.8 mW/°C 975 mW 624 mW 507 mW Derating factor measured with High-K board. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 ELECTRICAL CHARACTERISTICS TA = 25°C (unless otherwise noted) PARAMETER TEST CONDITIONS TYP MAX 1 25 mV VDD = 2.5 V to 5.5 V –75 –55 dB Common mode rejection ratio VDD = 2.5 V to 5.5 V, VIC = VDD/2 to 0.5 V, VIC = VDD/2 to VDD –0.8 V –68 –49 dB |IIH| High-level input current VDD = 5.5 V, VI = 5.8 V 100 µA |IIL| Low-level input current VDD = 5.5 V, VI = –0.3 V 5 µA |VOS| Output offset voltage (measured differentially) VI = 0 V, AV = 2 V/V, VDD = 2.5 V to 5.5 V PSRR Power supply rejection ratio CMRR I(Q) Quiescent current I(SD) Shutdown current rDS(on) f(sw) Static drain-source on-state resistance MIN VDD = 5.5 V, no load 3.4 VDD = 3.6 V, no load 2.8 VDD = 2.5 V, no load 2.2 3.2 V(SHUTDOWN)= 0.35 V, VDD = 2.5 V to 5.5 V 0.5 2 VDD = 2.5 V 700 VDD = 3.6 V 500 VDD = 5.5 V 400 4.9 mA µA mΩ Output impedance in SHUTDOWN V(SHUTDOWN) = 0.4 V >1 Switching frequency VDD = 2.5 V to 5.5 V 200 250 300 Gain VDD = 2.5 V to 5.5 V 285 kW RI 300 kW RI 315 kW RI Resistance from shutdown to GND UNIT kΩ 300 kHz V V kΩ OPERATING CHARACTERISTICS TA = 25°C, Gain = 2 V/V, RL = 8 Ω (unless otherwise noted) PARAMETER TEST CONDITIONS MIN VDD = 5 V THD + N = 10%, f = 1 kHz, RL = 4 Ω THD + N = 1%, f = 1 kHz, RL = 4 Ω PO Output power THD + N = 10%, f = 1 kHz, RL = 8 Ω THD + N = 1%, f = 1 kHz, RL = 8 Ω Total harmonic distortion plus noise VDD = 3.6 V 1.3 VDD = 2.5 V 0.52 VDD = 5 V 2.08 VDD = 3.6 V 1.06 VDD = 2.5 V 0.42 VDD = 5 V 1.45 VDD = 3.6 V 0.73 VDD = 2.5 V 0.33 VDD = 5 V 1.19 VDD = 3.6 V 0.59 0.18% VDD = 3.6 V, PO = 0.5 W, RL = 8 Ω, f = 1 kHz 0.19% VDD = 2.5 V, PO = 200 mW, RL = 8 Ω, f = 1 kHz 0.20% f = 217 Hz, V(RIPPLE) = 200 mVpp kSVR Supply ripple rejection ratio SNR Signal-to-noise ratio VDD = 5 V, PO = 1 W, RL = 8 Ω Vn Output voltage noise VDD = 3.6 V, f = 20 Hz to 20 kHz, Inputs ac-grounded with CI = 2 µF No weighting 48 A weighting 36 CMRR Common mode rejection ratio VDD = 3.6 V, VIC = 1 Vpp f = 217 Hz –63 ZI Input impedance 142 VDD = 3.6 V W W W W 0.26 VDD = 5 V, PO = 1 W, RL = 8 Ω, f = 1 kHz VDD = 3.6 V, Inputs ac-grounded with CI = 2 µF Start-up time from shutdown –67 dB 97 dB 150 µVRMS dB 158 32 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 UNIT 2.5 VDD = 2.5 V THD+N TYP MAX kΩ ms 3 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com Terminal Functions TERMINAL NAME I/O YZF DESCRIPTION IN– C1 I Negative differential input IN+ A1 I Positive differential input VDD B1 I Power supply VO+ C3 O Positive BTL output GND A2, B3 I High-current ground VO- A3 O Negative BTL output SHUTDOWN C2 I Shutdown terminal (active low logic) PVDD B2 I Power supply FUNCTIONAL BLOCK DIAGRAM *Gain = 150 kΩ RI *Gain = 2 V/V B1, B2 VDD 150 kΩ IN- C1 _ + VDD + _ Deglitch Logic Gate Drive + _ Deglitch Logic Gate Drive A3 VO- _ + _ + + _ IN+ A1 150 kΩ C2 SHUTDOWN TTL SD Input Buffer 300 kΩ Notes: * Total gain = 4 2x Biases and References Ramp Generator Startup Protection Logic C3 VO+ OC Detect A2, B3 GND 150 kΩ RI Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 TYPICAL CHARACTERISTICS TABLE OF GRAPHS FIGURE Efficiency vs Output power 1, 2 Power dissipation vs Output power 3, 4 Supply current vs Output power 5, 6 I(Q) Quiescent current vs Supply voltage 7 I(SD) Shutdown current vs Shutdown voltage 8 PD PO Output power THD+N Total harmonic distortion plus noise vs Supply voltage 9 vs Load resistance 10, 11 vs Output power 12, 13 vs Frequency 14, 15, 16, 17 vs Common-mode input voltage KSVR Supply voltage rejection ratio vs Frequency GSM power supply rejection KSVR Supply voltage rejection ratio CMRR Common-mode rejection ratio 18 Voltage 19, 20, 21 vs Time 22 vs Frequency 23 vs Common-mode input voltage 24 vs Frequency 25 vs Common-mode input voltage 26 vs Start-up time 27 TEST SET-UP FOR GRAPHS CI TPA2031D1 RI + Measurement Output - IN+ CI OUT+ Load RI INVDD + OUT- 30 kHz Low Pass Filter + Measurement Input - GND 1 µF VDD - Notes: (1) C I was Shorted for any Common-Mode input voltage measurement (2) A 33- µH inductor was placed in series with the load resistor to emulate a small speaker for efficiency measurements. . An RC low pass filter (100 Ω, 47 nF) is used on each output for the data sheet graphs. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 5 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com EFFICIENCY vs OUTPUT POWER 90 90 80 VDD = 5 V, RL = 8 Ω, 33 µH 70 60 50 40 Class AB. VDD = 5 V, RL = 8 Ω 30 20 1.4 70 Efficiency − % VDD = 2.5 V, RL = 8 Ω, 33 µH VDD = 3.6 V, RL = 4 Ω, 33 µH VDD = 2.5 V, RL = 4 Ω, 33 µH 50 40 Class AB. VDD = 5 V, RL = 4 Ω 20 10 0 0.2 0.4 0.6 1 0.8 0 1.2 0.2 VDD = 5 V, RL = 8 Ω 0 1.2 1.4 1.6 1.8 2 0 0.5 1 1.5 2 Figure 2. Figure 3. POWER DISSIPATION vs OUTPUT POWER SUPPLY CURRENT vs OUTPUT POWER SUPPLY CURRENT vs OUTPUT POWER Class-AB 3.6 V, 8 Ω 0.4 0.3 VDD = 3.6 V, RL = 4 Ω 0.2 0.1 VDD = 3.6 V, RL = 8 Ω, 33 µH 0.2 0.4 0.6 0.8 1 400 VDD = 2.5 V 300 200 100 VDD = 5 V, VDD = 3.6 V 200 150 100 VDD = 2.5 V 50 VDD = 5 V 0 0.5 1 1.5 2 0 2.5 0.2 0.4 0.6 0.8 1.2 1 PO − Output Power − W PO − Output Power − W PO − Output Power − W Figure 4. Figure 5. Figure 6. SUPPLY CURRENT vs SUPPLY VOLTAGE SUPPLY CURRENT vs SHUTDOWN VOLTAGE OUTPUT POWER vs LOAD RESISTANCE I (SD) − Shutdown Current − µ A 4.5 RL = 8 Ω, (resistive) RL = 8 Ω, 33 µH 3.5 3 2.5 1.5 VDD = 5 V 1 VDD = 3.6 V VDD = 2.5 V 0.5 4.5 5 5.5 VDD − Supply Voltage − V Figure 7. VDD = 5 V 2 VDD = 3.6 V 1.5 VDD = 2.5 V 1 0.5 0 0 4 PO at 10% THD Gain = 2 V/V f = 1 kHz 2.5 No Load 3.5 1.4 3 2 5 3 RL = 8 Ω, 33 µH 0 0 1.2 2.5 250 VDD = 3.6 V I DD − Supply Current − mA 0.5 300 RL = 4 Ω, 33 µH 500 Class-AB 3.6 V, 4 Ω I DD − Supply Current − mA P D − Power Dissipation − W VDD = 5 V, RL = 4 Ω, 0.4 Figure 1. 0 I DD − Supply Current − mA 0.6 PO − Output Power − W 0.6 2 2.5 Class-AB 5 V, 8 Ω 0.8 PO − Output Power − W 600 4 1 PO − Output Power − W 0.7 0 0.2 0.4 0.6 0.8 1 PO − Output Power − W 0 0 Class-AB 5 V, 4 Ω 1.2 VDD = 5 V, RL = 4 Ω, 33 µH 60 30 10 6 POWER DISSIPATION vs OUTPUT POWER P D − Power Dissipation − W 100 80 Efficiency − % EFFICIENCY vs OUTPUT POWER 0 0.1 0.2 0.3 0.4 Shutdown Voltage − V Figure 8. Submit Documentation Feedback 0.5 4 8 12 16 20 24 28 32 RL − Load Resistance − Ω Figure 9. Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 3 2.5 VDD = 5 V PO at 1% THD Gain = 2 V/V f = 1 kHz 1.5 VDD = 3.6 V 1 Gain = 2 V/V f = 1 kHz 2.5 PO − Output Power − W VDD = 2.5 V 0.5 RL = 4 Ω, 10% THD 2 RL = 4 Ω, 1% THD 1.5 1 RL = 8 Ω,10% THD 0.5 0 2.5 0 4 8 12 16 20 24 RL − Load Resistance − Ω 28 32 RL = 8 Ω,1% THD 3 3.5 4 4.5 VCC − Supply Voltage − V 5 20 RL = 4 Ω, f = 1 kHz, Gain = 2 V/V 10 5 2.5 V 3V 2 3.6 V 1 5V 0.5 0.2 0.1 20m 50m 100m 200m 500m 1 PO − Output Power − W 2 3 Figure 11. Figure 12. TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT POWER TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY 20 RL = 8 Ω, f = 1 kHz, Gain = 2 V/V 10 5 2.5 V 3V 3.6 V 2 5V 1 0.5 0.2 0.1 5m 10m 20m 50m 100m 200m 500m 1 2 THD+N − Total Harmonic Distortion + Noise − % Figure 10. 10 VDD = 5 V CI = 2 µF RL = 8 Ω Gain = 2 V/V 5 2 PO = 50 mW PO = 250 mW 1 0.5 PO = 1W 0.2 0.1 0.05 0.02 VDD = 3.6 V CI = 2 µF RL = 8 Ω Gain = 2 V/V 5 2 PO = 25 mW PO = 125 mW 1 0.5 PO = 500 mW 0.2 0.1 0.05 0.02 0.01 0.005 0.01 20 PO − Output Power − W 10 THD+N − Total Harmonic Distortion + Noise − % PO − Output Power − W 2 THD+N − Total Harmonic Distortion + Noise − % TOTAL HARMONIC DISTORTION + NOISE vs OUTPUT POWER OUTPUT POWER vs SUPPLY VOLTAGE THD+N − Total Harmonic Distortion + Noise − % OUTPUT POWER vs LOAD RESISTANCE 50 100 200 500 1k 2k 5k 10k 20k 20 50 100 200 500 1k 2k f − Frequency − Hz 5k 10k 20k Figure 15. TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY TOTAL HARMONIC DISTORTION + NOISE vs FREQUENCY TOTAL HARMONIC DISTORTION + NOISE vs COMMON MODE INPUT VOLTAGE 10 VDD = 2.5 V CI = 2 µF RL = 8 Ω Gain = 2 V/V 5 2 PO = 15 mW PO = 75 mW 1 0.5 PO = 200 mW 0.2 0.1 0.05 0.02 0.01 20 50 100 200 500 1k 2k 5k 10k 20k f − Frequency − Hz Figure 16. 10 PO = 250 mW CI = 2 µF RL = 4 Ω Gain = 2 V/V 5 2 1 VDD = 3.6 V VDD = 3 V 0.5 0.2 VDD = 2.5 V 0.1 0.05 0.02 0.01 VDD = 4 V 20 50 100 200 VDD = 5 V 500 1k 2k 5k 10k 20k f − Frequency − Hz Figure 17. THD+N − Total Harmonic Distortion + Noise − % Figure 14. THD+N − Total Harmonic Distortion + Noise − % THD+N − Total Harmonic Distortion + Noise − % f − Frequency − Hz Figure 13. 10 f = 1 kHz PO = 200 mW VDD = 2.5 V 1 VDD = 5 V VDD = 3.6 V 0.1 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 Figure 18. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 5 VIC − Common Mode Input Voltage − V 7 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com SUPPLY RIPPLE REJECTION RATIO vs FREQUENCY −30 Inputs ac-grounded CI = 2 µF RL = 8 Ω Gain = 2 V/V −50 VDD = 2. 5 V VDD = 3.6 V −60 −70 −80 −30 Inputs ac-grounded CI = 2 µF RL = 4 Ω Gain = 2 V/V −40 VDD = 2.5 V −50 −60 VDD = 3.6 V −70 −80 100 1k VDD = 5 V −60 −70 VDD = 3.6 V −80 VDD = 2.5 V −90 20 −50 VDD = 5 V VDD = 5 V −90 Inputs floating RL = 8 Ω −40 −90 20 10 k 20 k 100 1k 20 10 k 20 k 100 Figure 19. 1k 10 k 20 k f − Frequency − Hz f − Frequency − Hz f − Frequency − Hz Figure 20. GSM POWER SUPPLY REJECTION vs TIME GSM POWER SUPPLY REJECTION vs FREQUENCY 0 C1 − High 3.6 V −50 C1 − Amp 512 mV −100 VO − Output Voltage − dBV VDD 200 mV/div C1 − Duty 12% VOUT 20 mV/div 0 VDD Shown in Figure 22 CI = 2 µF, Inputs ac-grounded Gain = 2V/V −50 −100 −150 0 400 t − Time − 2 ms/div 800 −40 VDD = 3.6 V VDD = 2. 5 V −50 VDD = 5 V −60 −70 −80 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 DC Common Mode Voltage − V Figure 24. 8 2000 −50 VIC = 200 mVPP RL = 8 Ω Gain = 2 V/V −55 −60 VDD = 3.6 V −65 −70 −75 20 100 1k f − Frequency − Hz 10 k 20 k Figure 25. Submit Documentation Feedback COMMON-MODE REJECTION RATIO vs COMMON-MODE INPUT VOLTAGE CMRR − Common Mode Rejection Ratio − dB −30 COMMON-MODE REJECTION RATIO vs FREQUENCY CMRR − Common Mode Rejection Ratio − dB Sopply Ripple Rejection Ratio − dB −20 1600 Figure 23. SUPPLY RIPPLE REJECTION RATIO vs DC COMMON MODE VOLTAGE 0 1200 f − Frequency − Hz Figure 22. −10 −150 V DD − Supply Voltage − dBV −40 Sopply Ripple Rejection Ratio − dB Sopply Ripple Rejection Ratio − dB −30 SUPPLY RIPPLE REJECTION RATIO vs FREQUENCY Sopply Ripple Rejection Ratio − dB SUPPLY RIPPLE REJECTION RATIO vs FREQUENCY 0 −10 −20 −30 −40 VDD = 3.6 V VDD = 2.5 V −50 −60 −70 −80 VDD = 5 V, Gain = 2 −90 −100 0 1 2 3 4 5 VIC − Common Mode Input Voltage − V Figure 26. Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 VOLTAGE vs START-UP TIME 4 SHUTDOWN 3 V − Voltage − V 2 1 0 Output −1 −2 −3 −4 0.00 VDD = 3.6 V RL = 8 Ω + 33 µH PO = 500 mW f = 200 Hz 0.02 0.04 0.06 0.08 0.10 t − Time − s Figure 27. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 9 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com APPLICATION INFORMATION FULLY DIFFERENTIAL AMPLIFIER The TPA2031D1 is a fully differential amplifier with differential inputs and outputs. The fully differential amplifier consists of a differential amplifier and a common-mode amplifier. The differential amplifier ensures that the amplifier outputs a differential voltage on the output that is equal to the differential input times the gain. The common-mode feedback ensures that the common-mode voltage at the output is biased around VDD/2 regardless of the common-mode voltage at the input. The fully differential TPA2031D1 can still be used with a single-ended input; however, the TPA2031D1 should be used with differential inputs when in a noisy environment, like a wireless handset, to ensure maximum noise rejection. Advantages of Fully Differential Amplifiers • Input-coupling capacitors not required: – The fully differential amplifier allows the inputs to be biased at voltage other than mid-supply voltage. For example, if a codec has a mid-supply voltage lower than the mid-supply voltage of the TPA2031D1, the common-mode feedback circuit adjusts, and the TPA2031D1 outputs are still biased at mid-supply voltage of the TPA2031D1. The inputs of the TPA2031D1 can be biased from 0.5 V to VDD –0.8 V. If the inputs are biased outside of that range, input-coupling capacitors are required. • Mid-supply bypass capacitor, C(BYPASS), not required: – The fully differential amplifier does not require a bypass capacitor. This is because any shift in the midsupply affects both positive and negative channels equally and cancels at the differential output. • Better RF-immunity: – GSM handsets save power by turning on and shutting off the RF transmitter at a rate of 217 Hz. The transmitted signal is picked-up on input and output traces. The fully differential amplifier cancels the signal much better than the typical audio amplifier. COMPONENT SELECTION Figure 28 shows the TPA2031D1 typical schematic with differential inputs and Figure 29 shows the TPA2031D1 with differential inputs and input capacitors, and Figure 30 shows the TPA2031D1 with single-ended inputs. Differential inputs should be used whenever possible because the single-ended inputs are much more susceptible to noise. Table 1. Typical Component Values (1) REF DES VALUE EIA SIZE MANUFACTURER RI 150 kΩ (±0.5%) 0402 Panasonic PART NUMBER ERJ2RHD154V CS 1 µF (+22%, –80%) 0402 Murata GRP155F50J105Z CI (1) 3.3 nF (±10%) 0201 Murata GRP033B10J332K CI is only needed for single-ended input, or if VICM is not between 0.5 V and VDD–0.8 V. CI = 3.3 nF (with RI= 150 kΩ) gives a high-pass corner frequency of 321 Hz. Input Resistors (RI) The input resistors (RI) set the gain of the amplifier according to Equation 1. Gain = 2 × 150 kW æ V ö ç ÷ RI èVø (1) Resistor matching is very important in fully differential amplifiers. The balance of the output on the reference voltage depends on matched ratios of the resistors. CMRR, PSRR, and cancellation of the second harmonic distortion diminish if resistor mismatch occurs. Therefore, it is recommended to use 1% tolerance resistors or better to keep the performance optimized. Matching is more important than overall tolerance. Resistor arrays with 1% matching can be used with a tolerance greater than 1%. Place the input resistors very close to the TPA2031D1 to limit noise injection on the high-impedance nodes. 10 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 For optimal performance the gain should be set to 2 V/V or lower. Lower gain allows the TPA2031D1 to operate at its best, and keeps a high voltage at the input making the inputs less susceptible to noise. Decoupling Capacitor (CS) The TPA2031D1 is a high-performance class-D audio amplifier that requires adequate power supply decoupling to ensure the efficiency is high and total harmonic distortion (THD) is low. For higher frequency transients, spikes, or digital hash on the line, a good low equivalent-series-resistance (ESR) ceramic capacitor, typically 1 µF, placed as close as possible to the device VDD lead works best. Placing this decoupling capacitor close to the TPA2031D1 is very important for the efficiency of the class-D amplifier, because any resistance or inductance in the trace between the device and the capacitor can cause a loss in efficiency. For filtering lower-frequency noise signals, a 10 µF or greater capacitor placed near the audio power amplifier would also help, but it is not required in most applications because of the high PSRR of this device. Input Capacitors (CI) The TPA2031D1 does not require input coupling capacitors if the design uses a differential source that is biased from 0.5 V to VDD –0.8 V (shown in Figure 28). If the input signal is not biased within the recommended common-mode input range, if needing to use the input as a high pass filter (shown in Figure 29), or if using a single-ended source (shown in Figure 30), input coupling capacitors are required. The input capacitors and input resistors form a high-pass filter with the corner frequency, fc, determined in Equation 2. fC = 1 (2p ´ RI ´ CI ) (2) The value of the input capacitor is important to consider as it directly affects the bass (low frequency) performance of the circuit. Speakers in wireless phones cannot usually respond well to low frequencies, so the corner frequency can be set to block low frequencies in this application. Equation 3 is reconfigured to solve for the input coupling capacitance. CI = 1 (2p ´ RI ´ fC ) (3) If the corner frequency is within the audio band, the capacitors should have a tolerance of ±10% or better, because any mismatch in capacitance causes an impedance mismatch at the corner frequency and below. For a flat low-frequency response, use large input coupling capacitors (1 µF). However, in a GSM phone the ground signal is fluctuating at 217 Hz, but the signal from the codec does not have the same 217 Hz fluctuation. The difference between the two signals is amplified, sent to the speaker, and heard as a 217 Hz hum. To Battery Internal Oscillator + RI IN_ Differential Input - SHUTDOWN RI VDD PWM HBridge CS VO+ VO- + IN+ GND Bias Circuitry TPA2031D1 Filter-Free Class D Figure 28. Typical TPA2031D1 Application Schematic With Differential Input for a Wireless Phone Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 11 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com CI Differential Input To Battery Internal Oscillator RI IN_ CI VDD PWM VO+ HBridge VO- + RI CS IN+ GND Bias Circuitry SHUTDOWN TPA2031D1 Filter-Free Class D Figure 29. TPA2031D1 Application Schematic With Differential Input and Input Capacitors TPA2031D1 Figure 30. TPA2031D1 Application Schematic With Single-Ended Input SUMMING INPUT SIGNALS WITH THE TPA2031D1 Most wireless phones or PDAs need to sum signals at the audio power amplifier or just have two signal sources that need separate gain. The TPA2031D1 makes it easy to sum signals or use separate signal sources with different gains. Many phones now use the same speaker for the earpiece and ringer, where the wireless phone would require a much lower gain for the phone earpiece than for the ringer. PDAs and phones that have stereo headphones require summing of the right and left channels to output the stereo signal to the mono speaker. Summing Two Differential Input Signals Two extra resistors are needed for summing differential signals (a total of 5 components). The gain for each input source can be set independently (see Equation 4 and Equation 5, and Figure 31). V V Gain 1 + O + 2 x 150 kW V R V I1 I1 (4) V V Gain 2 + O + 2 x 150 kW V R V I2 I2 (5) ǒǓ ǒǓ If summing left and right inputs with a gain of 1 V/V, use RI1 = RI2 = 300 kΩ. 12 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 If summing a ring tone and a phone signal, set the ring-tone gain to Gain 2 = 2 V/V, and the phone gain to gain 1 = 0.1 V/V. The resistor values would be. . . RI1 = 3 MΩ, and = RI2 = 150 kΩ. Differential Input 1 + RI1 - RI1 + RI2 To Battery Internal Oscillator Differential Input 2 RI2 CS IN_ - VDD PWM HBridge VO+ VO- + IN+ GND SHUTDOWN Bias Circuitry Filter-Free Class D Figure 31. Application Schematic With TPA2031D1 Summing Two Differential Inputs Summing a Differential Input Signal and a Single-Ended Input Signal Figure 32 shows how to sum a differential input signal and a single-ended input signal. Ground noise can couple in through IN+ with this method. It is better to use differential inputs. The corner frequency of the single-ended input is set by CI2, shown in Equation 8. To assure that each input is balanced, the single-ended input must be driven by a low-impedance source even if the input is not in use V V Gain 1 + O + 2 x 150 kW V R V I1 I1 (6) V V Gain 2 + O + 2 x 150 kW V R V I2 I2 (7) ǒǓ ǒǓ CI2 = 1 (2p RI2 fc2 ) (8) If summing a ring tone and a phone signal, the phone signal should use a differential input signal while the ring tone might be limited to a single-ended signal. Phone gain is set at gain 1 = 0.1 V/V, and the ring-tone gain is set to gain 2 = 2 V/V, the resistor values would be… RI1 = 3 MΩ, and = RI2 = 150 kΩ. The high pass corner frequency of the single-ended input is set by CI2. If the desired corner frequency is less than 20 Hz... Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 13 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com C I2 C I2 u 1 ǒ2p 150kW 20HzǓ (9) u 53 nF (10) RI1 Differential Input 1 Single-Ended Input 2 RI1 CI2 R I2 To Battery Internal Oscillator CS IN_ RI2 VDD PWM HBridge VO+ VO- + IN+ CI2 GND Bias Circuitry SHUTDOWN Filter-Free Class D Figure 32. Application Schematic With TPA2031D1 Summing Differential Input and Single-Ended Input Signals Summing Two Single-Ended Input Signals Four resistors and three capacitors are needed for summing single-ended input signals. The gain and corner frequencies (fc1 and fc2) for each input source can be set independently (see Equation 11 through Equation 14, and Figure 33). Resistor, RP, and capacitor, CP, are needed on the IN+ terminal to match the impedance on the IN– terminal. The single-ended inputs must be driven by low impedance sources even if one of the inputs is not outputting an ac signal. V V Gain 1 + O + 2 x 150 kW V R V I1 I1 (11) V V Gain 2 + O + 2 x 150 kW V R V I2 I2 (12) 1 C + I1 ǒ2p RI1 f c1Ǔ (13) 1 C + I2 ǒ2p RI2 f c2Ǔ (14) C +C ) C P I1 I2 (15) R R I2 R + I1 P R ) R I1 I2 (16) ǒǓ ǒǓ ǒ 14 Ǔ Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 Single-Ended Input 1 Single-Ended Input 2 CI1 R I1 To Battery CI2 R I2 Internal Oscillator CS IN_ RP VDD PWM VO+ HBridge VO- + IN+ CP GND SHUTDOWN Bias Circuitry Filter-Free Class D Figure 33. Application Schematic With TPA2031D1 Summing Two Single-Ended Inputs BOARD LAYOUT In making the pad size for the WCSP balls, it is recommended that the layout use non-solder-mask-defined (NSMD) land. With this method, the solder mask opening is made larger than the desired land area, and the opening size is defined by the copper pad width. Figure 34 and Table 2 show the appropriate diameters for a WCSP layout. The TPA2031D1 evaluation module (EVM) layout is shown in the next section as a layout example. Copper Trace Width Solder Pad Width Solder Mask Opening Copper Trace Thickness Solder Mask Thickness Figure 34. Land Pattern Dimensions Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 15 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com Table 2. Land Pattern Dimensions SOLDER PAD DEFINITIONS COPPER PAD SOLDER MASK OPENING COPPER THICKNESS STENCIL OPENING STENCIL THICKNESS Non-solder-mask defined (NSMD) 275 µm (+0.0, –25 µm) 375 µm (+0.0, –25 µm) 1 oz max (32 µm) 275 µm x 275 µm Sq. (rounded corners) 125 µm thick NOTES: 1. Circuit traces from NSMD defined PWB lands should be 75 µm to 100 µm wide in the exposed area inside the solder mask opening. Wider trace widths reduce device stand off and impact reliability. 2. Recommend solder paste is Type 3 or Type 4. 3. Best reliability results are achieved when the PWB laminate glass transition temperature is above the operating the range of the intended application. 4. For a PWB using a Ni/Au surface finish, the gold thickness should be less 0.5 µm to avoid a reduction in thermal fatigue performance. 5. Solder mask thickness should be less than 20 µm on top of the copper circuit pattern. 6. Best solder stencil performance is achieved using laser cut stencils with electro polishing. Use of chemically etched stencils results in inferior solder paste volume control. 7. Trace routing away from WCSP device should be balanced in X and Y directions to avoid unintentional component movement due to solder wetting forces. Component Location Place all the external components very close to the TPA2031D1. The input resistors need to be very close to the TPA2031D1 input pins so noise does not couple on the high impedance nodes between the input resistors and the input amplifier of the TPA2031D1. Placing the decoupling capacitor, CS, close to the TPA2031D1 is important for the efficiency of the class-D amplifier. Any resistance or inductance in the trace between the device and the capacitor can cause a loss in efficiency. Trace Width Recommended trace width at the solder balls is 75 µm to 100 µm to prevent solder wicking onto wider PCB traces. Figure 35 shows the layout of the TPA2031D1 evaluation module (EVM). For high current pins (VDD, GND VO+, and VO–) of the TPA2031D1, use 100-µm trace widths at the solder balls and at least 500-µm PCB traces to ensure proper performance and output power for the device. For input pins (IN–, IN+, and SHUTDOWN) of the TPA2031D1, use 75-µm to 100-µm trace widths at the solder balls. IN– and IN+ pins need to run side-by-side to maximize common-mode noise cancellation. Placing input resistors, RIN, as close to the TPA2031D1 as possible is recommended. 16 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 75 mm 100 mm 100 mm 100 mm 375 mm (+0, -25 mm) 275 mm (+0, -25 mm) 100 mm Circular Solder Mask Opening Paste Mask (Stencil) = Copper Pad Size 75 mm 100 mm 75 mm Figure 35. Close Up of TPA2031D1 Land Pattern From TPA2031D1 EVM EFFICIENCY AND THERMAL INFORMATION The maximum ambient temperature depends on the heat-sinking ability of the PCB system. The derating factor for the YZF package is shown in the dissipation rating table. Converting this to θJA: 1 1 q + + + 128.2°CńW JA 0.0078 Derating Factor (17) Given θJA of 128.2°C/W, the maximum allowable junction temperature of 150°C, and the maximum internal dissipation of 0.4 W (2.25 W, 4-Ω load, 5-V supply, from Figure 3), the maximum ambient temperature can be calculated with the following equation. T Max + T Max * q P + 150 * 128.2 (0.4) + 98.72°C A J JA Dmax (18) Equation 18 shows that the calculated maximum ambient temperature is 98.7°C at maximum power dissipation with a 5-V supply and 4-Ω a load, see Figure 3. The TPA2031D1 is designed with thermal protection that turns the device off when the junction temperature surpasses 150°C to prevent damage to the IC. Also, using speakers more resistive than 4-Ω dramatically increases the thermal performance by reducing the output current and increasing the efficiency of the amplifier. ELIMINATING THE OUTPUT FILTER WITH THE TPA2031D1 This section focuses on why the user can eliminate the output filter with the TPA2031D1. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 17 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com Effect on Audio The class-D amplifier outputs a pulse-width modulated (PWM) square wave that is the sum of the switching waveform and the amplified input audio signal. The human ear acts as a band-pass filter such that only the frequencies between approximately 20 Hz and 20 kHz are passed. The switching frequency components are much greater than 20 kHz, so the only signal heard is the amplified input audio signal. Traditional Class-D Modulation Scheme The traditional class-D modulation scheme, which is used in the TPA005Dxx family, has a differential output where each output is 180 degrees out of phase and changes from ground to the supply voltage, VDD. Therefore, the differential pre-filtered output varies between positive and negative VDD, where filtered 50% duty cycle yields 0 volts across the load. The traditional class-D modulation scheme with voltage and current waveforms is shown in Figure 36. Note that even at an average of 0 volts across the load (50% duty cycle), the current to the load is high causing a high loss and thus causing a high supply current. OUT+ OUT+5 V Differential Voltage Across Load 0V -5 V Current Figure 36. Traditional Class-D Modulation Scheme's Output Voltage and Current Waveforms Into an Inductive Load With no Input TPA2031D1 Modulation Scheme The TPA2031D1 uses a modulation scheme that still has each output switching from 0 to the supply voltage. However, OUT+ and OUT– are now in phase with each other with no input. The duty cycle of OUT+ is greater than 50% and OUT– is less than 50% for positive voltages. The duty cycle of OUT+ is less than 50% and OUT– is greater than 50% for negative voltages. The voltage across the load sits at 0 volts throughout most of the switching period greatly reducing the switching current, which reduces any I2R losses in the load. 18 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 TPA2031D1 www.ti.com........................................................................................................................................................................................................ SLOS546 – MAY 2008 OUT+ OUTDifferential Voltage Across Load Output = 0 V +5 V 0V -5 V Current OUT+ OUTDifferential Voltage Output > 0 V +5 V 0V Across Load -5 V Current Figure 37. The TPA2031D1 Output Voltage and Current Waveforms Into an Inductive Load Efficiency: Why You Must Use a Filter With the Traditional Class-D Modulation Scheme The main reason that the traditional class-D amplifier needs an output filter is that the switching waveform results in maximum current flow. This causes more loss in the load, which causes lower efficiency. The ripple current is large for the traditional modulation scheme because the ripple current is proportional to voltage multiplied by the time at that voltage. The differential voltage swing is 2 × VDD and the time at each voltage is half the period for the traditional modulation scheme. An ideal LC filter is needed to store the ripple current from each half cycle for the next half cycle, while any resistance causes power dissipation. The speaker is both resistive and reactive, whereas an LC filter is almost purely reactive. The TPA2031D1 modulation scheme has very little loss in the load without a filter because the pulses are very short and the change in voltage is VDD instead of 2 × VDD. As the output power increases, the pulses widen making the ripple current larger. Ripple current could be filtered with an LC filter for increased efficiency, but for most applications the filter is not needed. An LC filter with a cutoff frequency less than the class-D switching frequency allows the switching current to flow through the filter instead of the load. The filter has less resistance than the speaker that results in less power dissipated, which increases efficiency. Effects of Applying a Square Wave Into a Speaker If the amplitude of a square wave is high enough and the frequency of the square wave is within the bandwidth of the speaker, a square wave could cause the voice coil to jump out of the air gap and/or scar the voice coil. A 250-kHz switching frequency, however, is not significant because the speaker cone movement is proportional to 1/f2 for frequencies beyond the audio band. Therefore, the amount of cone movement at the switching frequency is very small. However, damage could occur to the speaker if the voice coil is not designed to handle the additional power. To size the speaker for added power, the ripple current dissipated in the load needs to be calculated by subtracting the theoretical supplied power, PSUP THEORETICAL, from the actual supply power, PSUP, at maximum output power, POUT. The switching power dissipated in the speaker is the inverse of the measured efficiency, ηMEASURED, minus the theoretical efficiency, ηTHEORETICAL. Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 19 TPA2031D1 SLOS546 – MAY 2008........................................................................................................................................................................................................ www.ti.com P –P (at max output power) SUP SUP THEORETICAL P P P + SUP – SUP THEORETICAL (at max output power) SPKR P P OUT OUT P SPKR SPKR +P +P ǒ (19) (20) Ǔ 1 1 * (at max output power) OUT h MEASURED h THEORETICAL (21) R hTHEORETICAL + R L (at max output power) ) 2r L DS(on) (22) The maximum efficiency of the TPA2031D1 with a 3.6 V supply and an 8-Ω load is 86% from Equation 22. Using equation Equation 21 with the efficiency at maximum power (84%), we see that there is an additional 17 mW dissipated in the speaker. The added power dissipated in the speaker is not an issue as long as it is taken into account when choosing the speaker. When to Use an Output Filter Design the TPA2031D1 without an output filter if the traces from amplifier to speaker are short. The TPA2031D1 passed FCC and CE radiated emissions with no shielding with speaker trace wires 100 mm long or less. Wireless handsets and PDAs are great applications for class-D without a filter. A ferrite bead filter can often be used if the design is failing radiated emissions without an LC filter, and the frequency sensitive circuit is greater than 1 MHz. This is good for circuits that just have to pass FCC and CE because FCC and CE only test radiated emissions greater than 30 MHz. If choosing a ferrite bead, choose one with high impedance at high frequencies, but very low impedance at low frequencies. Use an LC output filter if there are low frequency (< 1 MHz) EMI sensitive circuits and/or there are long leads from amplifier to speaker. Figure 38 and Figure 39 show typical ferrite bead and LC output filters. Ferrite Chip Bead OUTP 1 nF Ferrite Chip Bead OUTN 1 nF Figure 38. Typical Ferrite Chip Bead Filter (Chip bead example: NEC/Tokin: N2012ZPS121) 33 µH OUTP 1 µF 33 µH OUTN 1 µF Figure 39. Typical LC Output Filter, Cutoff Frequency of 27 kHz 20 Submit Documentation Feedback Copyright © 2008, Texas Instruments Incorporated Product Folder Link(s): TPA2031D1 PACKAGE MATERIALS INFORMATION www.ti.com 20-Jun-2008 TAPE AND REEL INFORMATION *All dimensions are nominal Device Package Package Pins Type Drawing SPQ Reel Reel Diameter Width (mm) W1 (mm) TPA2031D1YZFR DSBGA YZF 9 3000 180.0 TPA2031D1YZFT DSBGA YZF 9 250 180.0 A0 (mm) B0 (mm) K0 (mm) P1 (mm) 8.4 1.65 1.65 0.81 4.0 8.0 Q1 8.4 1.65 1.65 0.81 4.0 8.0 Q1 Pack Materials-Page 1 W Pin1 (mm) Quadrant PACKAGE MATERIALS INFORMATION www.ti.com 20-Jun-2008 *All dimensions are nominal Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm) TPA2031D1YZFR DSBGA YZF 9 3000 220.0 220.0 34.0 TPA2031D1YZFT DSBGA YZF 9 250 220.0 220.0 34.0 Pack Materials-Page 2 IMPORTANT NOTICE Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, modifications, enhancements, improvements, and other changes to its products and services at any time and to discontinue any product or service without notice. Customers should obtain the latest relevant information before placing orders and should verify that such information is current and complete. All products are sold subject to TI’s terms and conditions of sale supplied at the time of order acknowledgment. TI warrants performance of its hardware products to the specifications applicable at the time of sale in accordance with TI’s standard warranty. Testing and other quality control techniques are used to the extent TI deems necessary to support this warranty. Except where mandated by government requirements, testing of all parameters of each product is not necessarily performed. TI assumes no liability for applications assistance or customer product design. Customers are responsible for their products and applications using TI components. To minimize the risks associated with customer products and applications, customers should provide adequate design and operating safeguards. TI does not warrant or represent that any license, either express or implied, is granted under any TI patent right, copyright, mask work right, or other TI intellectual property right relating to any combination, machine, or process in which TI products or services are used. Information published by TI regarding third-party products or services does not constitute a license from TI to use such products or services or a warranty or endorsement thereof. Use of such information may require a license from a third party under the patents or other intellectual property of the third party, or a license from TI under the patents or other intellectual property of TI. Reproduction of TI information in TI data books or data sheets is permissible only if reproduction is without alteration and is accompanied by all associated warranties, conditions, limitations, and notices. Reproduction of this information with alteration is an unfair and deceptive business practice. TI is not responsible or liable for such altered documentation. Information of third parties may be subject to additional restrictions. Resale of TI products or services with statements different from or beyond the parameters stated by TI for that product or service voids all express and any implied warranties for the associated TI product or service and is an unfair and deceptive business practice. TI is not responsible or liable for any such statements. TI products are not authorized for use in safety-critical applications (such as life support) where a failure of the TI product would reasonably be expected to cause severe personal injury or death, unless officers of the parties have executed an agreement specifically governing such use. Buyers represent that they have all necessary expertise in the safety and regulatory ramifications of their applications, and acknowledge and agree that they are solely responsible for all legal, regulatory and safety-related requirements concerning their products and any use of TI products in such safety-critical applications, notwithstanding any applications-related information or support that may be provided by TI. Further, Buyers must fully indemnify TI and its representatives against any damages arising out of the use of TI products in such safety-critical applications. TI products are neither designed nor intended for use in military/aerospace applications or environments unless the TI products are specifically designated by TI as military-grade or "enhanced plastic." Only products designated by TI as military-grade meet military specifications. Buyers acknowledge and agree that any such use of TI products which TI has not designated as military-grade is solely at the Buyer's risk, and that they are solely responsible for compliance with all legal and regulatory requirements in connection with such use. TI products are neither designed nor intended for use in automotive applications or environments unless the specific TI products are designated by TI as compliant with ISO/TS 16949 requirements. Buyers acknowledge and agree that, if they use any non-designated products in automotive applications, TI will not be responsible for any failure to meet such requirements. Following are URLs where you can obtain information on other Texas Instruments products and application solutions: Products Amplifiers Data Converters DSP Clocks and Timers Interface Logic Power Mgmt Microcontrollers RFID RF/IF and ZigBee® Solutions amplifier.ti.com dataconverter.ti.com dsp.ti.com www.ti.com/clocks interface.ti.com logic.ti.com power.ti.com microcontroller.ti.com www.ti-rfid.com www.ti.com/lprf Applications Audio Automotive Broadband Digital Control Medical Military Optical Networking Security Telephony Video & Imaging Wireless www.ti.com/audio www.ti.com/automotive www.ti.com/broadband www.ti.com/digitalcontrol www.ti.com/medical www.ti.com/military www.ti.com/opticalnetwork www.ti.com/security www.ti.com/telephony www.ti.com/video www.ti.com/wireless Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265 Copyright © 2008, Texas Instruments Incorporated