LMV232TLX/NOPB - NATIONAL SEMICONDUCTOR

LMV232

LMV232 Dual-Channel Integrated Mean Square Power Detector for CDMA & WCDMA

Literature Number: SNWS017B

LMV232

Dual-Channel Integrated Mean Square Power Detector

for CDMA & WCDMA

General Description

The LMV232 dual RF detector is designed for RF transmit

power measurement in mobile phones. This dual mean

square IC is especially suited for accurate power measure-

ment of RF signals exhibiting high peak-to-average ratios

used in 3G and UMTS/CDMA applications. The LMV232

saves calibration steps and system certification and is highly

accurate. The circuit operates with a single supply from 2.5

to 3.3V.

The LMV232 contains a mean square detector with two

sequentially selectable RF inputs. The RF input power range

of the device has been optimized for use with a 20 dB

directional coupler, without the need for additional external

components. A single external RC combination between FB

and OUT provides an externally configurable gain and LF

filter bandwidth of the device.

The device has two digital interfaces. A shutdown function is

available to set the device in a low-power shutdown mode. In

case SD = HIGH, the device is in shutdown, if SD = LOW the

device is active. The Band-Select function controls the se-

lection of the active RF input channel. In case BS = HIGH,

1 is active. In case BS = LOW, RF

2 is active.

The dual mean square detector is offered in an 8-bump

micro SMD 1.5 x 1.5 x 0.6 mm package. This micro SMD

package has the smallest footprint and height.

Features

n>20 dB square-law detection range

n2 sequentially selectable RF inputs

nLow power consumption shutdown mode

nExternally configurable gain and LF filter bandwidth.

nInternal 50ΩRF termination impedance

nOptimized for use with 20 dB directional coupler

nLead free 8-bump micro SMD package 1.5 x 1.5 x 0.6

Applications

n3G mobile communications

nUMTS

nWCDMA

nCDMA2000

nTD-SCDMA

nRF control

nWireless LAN

nPC Card and GPS modules

Typical Application

20127801

April 2005

LMV232 Dual-Channel Integrated Mean Square Power Detector for CDMA & WCDMA

Absolute Maximum Ratings (Note 1)

If Military/Aerospace specified devices are required,

please contact the National Semiconductor Sales Office/

Distributors for availability and specifications.

Supply Voltage

- GND 3.6V Max

ESD Tolerance (Note 2)

Human Body Model 2000V

Machine Model 200V

Storage Temperature Range -65˚C to 150˚C

Junction Temperature (Note 3) 150˚C Max

Mounting Temperature

Infrared or Convection (20 sec) 235˚C

Operating Ratings (Note 1)

Supply Voltage 2.5V to 3.3V

Operating Temperature Range -40˚C to +85˚C

RF Frequency Range 50 MHz to 2 GHz

2.7 DC and AC Electrical Characteristics

Unless otherwise specified, all limits are guaranteed to V

= 2.7V; T

= 25˚C. Boldface limits apply at temperature extremes.

(Note 4)

Symbol Parameter Condition Min Typ Max Units

Supply Current Active Mode: SD = LOW, No RF Input

Power Present

9.8 11

13 mA

Shutdown: SD = 1.8V, No RF Input

Power Present

0.09 5

µA

LOW

BS and SD Logic Low Level

(Note 6)

0.8 V

HIGH

BS and SD Logic High Level

(Note 6)

1.8 V

Current into BS and SD pins 5µA

OUT

Output Voltage Swing From Positive Rail, Sourcing,

FB = 0V, I

OUT

=1mA

20 80

90 mV

From Negative Rail, Sinking,

FB = 2.7V, I

OUT

=−1mA

20 60

70 mV

OUT

Output Short Circuit Sourcing, FB = 0V, V

OUT

= 2.6V 3.7

2.7

5.1

Sinking, FB = 2.7V, V

OUT

= 0.1V 3.7

2.7

5.5

OUT

Output Voltage (Pedestal) No RF Input Power 235

230

254 275

280 mV

PED

Pedestal Variation Over

Temperature (Note 10)

5.4 mV

Offset Current Variation Over

Temperature (Note 10)

1.17 µA

Turn-on-Time (Note 9) No RF Input Power Present, Output

Loaded with 10 pF

2.0 6.0 µs

Rise Time (Note 7) Step from No Power to 0 dBm

Applied, Output Loaded with 10 pF

4.5 µs

Output Referred Voltage Noise RF Input = 1800 MHz, -10 dBm,

Measured at 10 kHz

400 nV/

GBW Gain Bandwidth Product 3.7 MHz

SR Slew Rate 1.8

1.0

3.0 V/µs

DC Resistance (Note 7) 50.8 Ω

RF Input Power Range RF Input Frequency = 900 MHz -11

+13

dBm

-24

dBV

LMV232

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2.7 DC and AC Electrical Characteristics (Continued)

Unless otherwise specified, all limits are guaranteed to V

= 2.7V; T

= 25˚C. Boldface limits apply at temperature extremes.

(Note 4)

Symbol Parameter Condition Min Typ Max Units

DET

Detection Slope 900 MHz 21

µA/mW

1800 MHz 10

1900 MHz 10

2000 MHz 10

LOW

LF Input Corner Frequency Lower −3 dB Point of Detection Slope 60 MHz

HIGH

HF Input Corner Frequency Upper −3 dB Point of Detection Slope 1.0 GHz

ISO

Channel Isolation 900 MHz 58

1800 MHz 62

1900 MHz 58

2000 MHz 55

Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the device may occur. Operating Ratings indicate conditions for which the device is

intended to be functional, but specific performance is not guaranteed. For guaranteed specifications and the test conditions, see the Electrical Characteristics.

Note 2: Human body model: 1.5 kΩin series with 100 pF. Machine model, 0Ωin series with 100 pF.

Note 3: The maximum power dissipation is a function of TJ(MAX) ,θJA and TA. The maximum allowable power dissipation at any ambient temperature is PD=

(TJ(MAX) -T

A)/θJA. All numbers apply for packages soldered directly into a PC board.

Note 4: Electrical Table values apply only for factory testing conditions at the temperature indicated. Factory testing conditions result in very limited self-heating of

the device such that TJ=T

A. No guarantee of parametric performance is indicated in the electrical tables under conditions of internal self-heating where TJ>TA.

Note 5: Power in dBV = dBm + 13 when the impedance is 50Ω.

Note 6: All limits are guaranteed by design or statistical analysis.

Note 7: Typical values represent the most likely parametric norm.

Note 8: Device is set in active mode with a 10 kΩresistor from VDD to RFIN/EN. RF signal is applied using a 50ΩRF signal generator AC coupled to the RFIN/EN

pin using a 100 pF coupling capacitor.

Note 9: Turn-on time is measured by connecting a 10 kΩresistor to the RFIN/ENpin. Be aware that in the actual application on the front page, the RC-time constant

of resistor R2 and capacitor C adds an additional delay.

Note 10: Typical numbers represent the 3-sigma value of 10k units. 3-sigma value of variation between −40˚C / 25˚C and variation between 25˚C / 85˚C.

LMV232

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Connection Diagram

8-Bump micro SMD

20127802

Top View

Pin Description

Pin Name Description

Power Supply B3 V

Positive Supply Voltage

B1 GND Power Ground

Digital Inputs C3 SD Schmitt-triggered Shutdown. The device is active for SD = LOW. For SD = HIGH, it is

brought into a low-power shutdown mode.

C2 BS Schmitt-triggered Band Select pin. When BS = HIGH, RF

1 is selected, when BS =

LOW, RF

2 is selected.

Analog Inputs A1 RF

1 RF Input connected to the coupler output with optional attenuation to measure the

Power Amplifier (PA) / Antenna RF power levels. Both RF inputs of the device are

internally terminated with a 50Ωresistance.

C1 RF

Feedback A2 FB Connected to inverting input of output amplifier. Enables user-configurable gain and

bandwidth through external feedback network.

Output A3 Out Amplifier output

Ordering Information

Package Part Number Package Marking Transport Media NSC Drawing

8-Bump micro SMD LMV232TL A

I02

250 Units Tape and Reel TLA08AAA

LMV232TLX 3k Units Tape and Reel

Note: This product is only offered with lead free bumps.

LMV232

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Block Diagrams

20127864

LMV232

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Typical Performance Characteristics Unless otherwise specified, V

= 2.7V, T

= 25˚C,

R1 = 6.2 kΩand C1 = 1.5 nF (See typical application on the frontpage).

Supply Current vs. Supply Voltage V

OUT

-V

PEDESTAL

vs. RF Input Power

20127877 20127867

OUT

-V

PEDESTAL

vs. RF Input Power @900 MHz Input Referred Error vs. RF Input Power @900 MHz

20127868 20127869

OUT

-V

PEDESTAL

vs. RF Input Power @1800 MHz Input Referred Error vs. RF Input Power @1800 MHz

20127870 20127871

LMV232

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Typical Performance Characteristics Unless otherwise specified, V

= 2.7V, T

= 25˚C,

R1 = 6.2 kΩand C1 = 1.5 nF (See typical application on the frontpage). (Continued)

OUT

-V

PEDESTAL

vs. RF Input Power @1900 MHz Input Referred Error vs. RF Input Power @1900 MHz

20127872 20127873

OUT

-V

PEDESTAL

vs. RF Input Power @2000 MHz Input Referred Error vs. RF Input Power @2000 MHz

20127874 20127875

OUT

-V

PEDESTAL

vs. RF Input Power @1900 MHz Input Referred Error vs. RF Input Power @1900 MHz

20127882 20127883

LMV232

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Typical Performance Characteristics Unless otherwise specified, V

= 2.7V, T

= 25˚C,

R1 = 6.2 kΩand C1 = 1.5 nF (See typical application on the frontpage). (Continued)

RF Input Impedance vs. Frequency

@Resistance and Reactance Gain and Phase vs. Frequency

20127876 20127804

Sourcing Current vs. Output Voltage Sinking Current vs. Output Voltage

20127878 20127879

Output Voltage vs. Sourcing Current Output Voltage vs. Sinking Current

20127880 20127881

LMV232

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Application Notes

The LMV232 mean square power detector is particularly

suited for accurate power measurement of RF modulated

signals that exhibit large peak to average ratios, i.e. large

variations of the signal envelope. Such noise-like signals are

encountered e.g. in CDMA and Wide-band CDMA cell-

phones. Many power detection circuits, particularly those

devised for constant-envelope modulated signals as in

GSM, are based on peak detection and provide accurate

power measurements for constant envelope or low-crest

factor (ratio of peak to RMS) signals only. Such detectors are

therefore not particularly suited for CDMA and WCDMA ap-

plications.

TYPICAL APPLICATION

The LMV232 is especially suited for CDMA and WCDMA

applications with 2 Power Amplifiers (PA’s). A typical setup is

given in Figure 1. The output power of one PA is measured at

a time, depending on the bandselect pin (BS). If the BS =

High RF

1 is used for measurements, if BS = Low RF

2is

used. The measured output voltage of the LMV232 is read

by the ADC of the baseband chip and the gain of the PA gain

is adjusted if necessary. With an input impedance of 50Ω,

the LMV232 can be directly connected to a 20 dB directional

coupler without the need for an additional external attenua-

tor. The setup can be adjusted to various PA output ranges

by selection of a directional coupler or insertion of an addi-

tional (resistive) attenuator between the coupler outputs and

the LMV232 RF inputs.

The LMV232 conversion gain and bandwidth are configured

by a resistor and a capacitor. Resistor R1 sets the conver-

sion gain from RF

to the output voltage. A higher resistor

value will result in a higher conversion gain. The maximum

dynamic range is achieved when the resistor value is as high

as possible, i.e. the output signal just doesn’t clip and the

voltage stays within the baseband ADC input range. The

filter bandwidth is adjusted by capacitor C1. The capacitor

value should be chosen such that the response time of the

device is fast enough and modulation on the RF input signal

is not visible at the output (ripple suppression). The −3 dB

filter bandwidth of the output filter is determined by the time

constant R1*C1. Generally a capacitor value of 1.5 nF is a

good choice.

PEAK TO AVERAGE RATIO SENSITIVITY

The LMV232 power detector provides an accurate power

measurement for arbitrary input signals, low and high peak-

to-average ratios and crest factors. This is because its op-

eration is not based on peak detection, but on direct deter-

mination of the mean square value. This is the most accurate

power measurement, since it exactly implements the defini-

tion of power. A mean-square detector measures V

RMS2

for

all waveforms. Peak detection is less accurate because the

relation between peak detection and mean square detection

depends on the waveform. A peak detector measures P =

PEAK2

for all waveforms, while it should measures P =

PEAK2

/2(forR=1Ω) for a sine wave and P = V

PEAK2

/3 for

a triangle wave for instance. For a CDMA signal, the mea-

surement error can be in the order of 5 to 6 dB. For many

wave forms, specially those with high peak-to-average ra-

tios, peak detection is not accurate enough and therefore a

mean square detector is recommended.

MEAN SQUARE CONFORMANCE ERROR

The LMV232 is a mean square detector and therefore

should have an output voltage (in Volts) that linearly relates

to the RF input power (in mW). The input referred error, with

respect to an ideal linear mean square detector, is deter-

mined as a measure for the accuracy of the detector.

20127801

FIGURE 1. Typical Application

LMV232

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Application Notes (Continued)

The detection curves of Figure 2 show the detector response

to RF input power. To show the complete dynamic range on

a logarithmic scale, the pedestal voltage (V

PEDESTAL

) is sub-

tracted from the output. The pedestal voltage is defined as

the output voltage in the absence of an RF input signal (at

25˚C). The best-fit ideal mean square response is repre-

sented by the fitted curve in Figure 2. The input referred error

of the detection curves with respect to this best-fit mean

square response is determined as follows:

•Determine the best-fit mean square response.

•Determine the output referred error between the actual

detector response and the ideal mean square response.

•Translate the output referred error to an input referred

error.

The best-fit linear curve is obtained from the detector re-

sponse by means of linear regression. The output referred

error is calculated with the formula:

Error

dBV

= 20*log[ (V

OUT

-V

PEDESTAL

)/(K

DET

)]

Where,

Conversion gain of the ideal fitted curve K

DET

is in V/mW

and the RF input power P

in mW.

To translate this output referred error (in dB) to an input

referred error, it has to be divided by a factor of 2. This is due

to the mean square characteristic of the device. The re-

sponse of a mean square detector changes by 2 dB for every

dB change of the input power. Figure 3 depicts the resulting

curve.

Analyzing Figure 3 shows that three sections can be distin-

guished:

•At higher power levels the error increases.

•A middle section where the error is constant and rela-

tively small.

•At lower power levels the error increases again.

These three sections are leading back to three error mecha-

nisms. At higher power levels the detectors output starts to

saturate because the output voltage approaches the maxi-

mum signal swing that the detector can handle. The maxi-

mum output voltage of the device thus limits the upper end of

the detection range. Also the maximum allowed ADC voltage

of the baseband chip can limit the detection range at higher

power levels. By adjusting the feedback resistor R

Figure 1 the upper end of the range can be shifted. This is

valid until the detector cell inside the LMV232 is the limiting

factor.

The middle section of the error curve shows a small error

variation. This is the section where the detector is used and

is called the detection range of the detector. This range is

limited on both sides by a maximum allowed error.

For low input power levels, the variation of output voltage is

very small. Therefore the measurement resolution ADC is

important in order to measure those small variations. Offsets

and temperature variation impact the accuracy at low power

levels as well.

DETECTION ERROR OVER TEMPERATURE

Like any power detector device, the output signal of the

LMV232 mean square power detector shows some residual

variation over temperature that limits it’s dynamic range. The

variation determines the accuracy and range of input power

levels for which the detector produces an accurate output

signal.

The error over temperature is mainly caused by the variation

of the pedestal voltage. Besides this, a minimal error contri-

bution leads back to the conversion gain variation of the

detector. This conversion gain error is visible in the mid-

power range, where the temperature error curves of Figure 3

run parallel to each other. Since the conversion gain varia-

tion is acceptable, the focus will be on the pedestal voltage

variation over temperature.

20127884

FIGURE 2. Detection Curve

20127869

FIGURE 3. Input referred Error vs. RF Input Power

LMV232

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Application Notes (Continued)

The pedestal voltage at 25˚C is subtracted from the output

voltage of each curve. Variations of the pedestal voltage

over temperature are thus included in the error.

The pedestal voltage variation itself consists of 2 error

sources. One is the variation of the reference voltage V

REF

The other is an offset current I

that is generated inside the

detector. This depicted in Figure 4. Depending on the mea-

surement strategy one or both error sources can be elimi-

nated.

The error sources of the pedestal voltage can be shown in a

formula for V

OUT

REF

+(I

DET

)*R

Where I

DET

represents the intended detector output signal.

In the absence of RF input power I

DET

equals zero. The

formula for the pedestal voltage can therefore be written as:

PEDESTAL

REF

For low input power levels, the pedestal variation V

PEDESTAL

is the dominant cause of error. Besides temperature varia-

tion of the pedestal voltage, which limits the lower end of the

range, the pedestal voltage can also vary from part-to-part.

By applying a suitable measurement strategy, the pedestal

voltage error contribution can be significantly reduced or

eliminated completely.

POWER MEASUREMENT STRATEGIES

This section describes the measurement strategies to re-

duce or eliminate the pedestal voltage variation. Which strat-

egy is chosen depends on the possibilities for a factory trim

and implementation of calibration procedures.

Since the pedestal voltage is the reference level for the

LMV232, it needs to be calibrated/measured at least once to

eliminate part-to-part spread. This is required to determine

the exact detector output signal. Because of process toler-

ances, the absolute part-to-part variation of the output volt-

age in the absence of RF input power will be in the order of

5 - 10%. All measurement strategies discussed eliminate this

part-to-part spread.

Strategy 1: Elimination of Part-to-Part Spread at Room

Temperature Only

In this strategy, the pedestal voltage is determined once

during manufacturing and stored into the memory of the

phone. At each power measurement this stored pedestal

level is digitally subtracted from the measured output signal

of the LMV232 during normal operation. The procedure is

thus:

•Measure the detector output in the absence of RF power

during manufacturing.

•Store the output voltage value in the cell phone memory

(after it is analog-to-digital converted).

•Subtract the stored value from each detector output read-

ing.

The advantage of this strategy is that calibration is required

only once during manufacturing and not during normal op-

eration. The disadvantage is the fact that this method neither

compensates for the residual temperature drift of the refer-

ence voltage V

REF

nor for offset current variations. Only

part-to-part variations at room temperature are eliminated by

this strategy. Especially the residual temperature drift nega-

tively affects the measurement accuracy.

Strategy 2: Elimination of Temperature Spread in V

REF

If software changes need to be reduced to a minimum and

the baseband chip has a differential ADC, strategy 2 can be

used to eliminate temperature variations of the reference

voltage V

REF

. One pin of the ADC is connected to FB and

one is connected to OUT (Figure 6).

The power measurement is independent of the reference

voltage V

REF

, since the ADC reading is:

OUT

-V

=(I

DET

)*R

20127805

FIGURE 4. Pedestal Voltage

20127806

FIGURE 5. Strategy 1: Room Temperature Calibration

20127807

FIGURE 6. Strategy 2: Differential Measurement

LMV232

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Application Notes (Continued)

The reading of the ADC obviously doesn’t contain the refer-

ence voltage source V

REF

anymore, but the contribution of

the offset current remains present. This measurement is

performed during normal operation. Therefore, it eliminates

voltage reference variations over temperatures, as opposed

to strategy 1. Also offset variations in the op amp are elimi-

nated in this strategy.

Strategy 3: Complete Elimination of Temperature

Spread in Pedestal Voltage

The most accurate measurement is strategy 3, which elimi-

nates the temperature variation of both the reference voltage

REF

and the offset current I

. In this strategy, the pedestal

voltage is measured regularly during operation of the phone,

and stored in the phone memory. For each power measure-

ment, the stored value is digitally subtracted from the

(analog-to-digital converted) detector output signal. Since it

measures the pedestal voltage itself for calibration it com-

pensates both for the reference voltage V

REF

as well as for

the offset current variation I

. The frequency of the ‘calibra-

tion measurement’ can be significantly lower than those of

power measurements, depending on how fast the tempera-

ture of the device changes.

The calibration measurement procedure can be explained

with the aid of Figure 1, which depicts a typical power

measurement setup using the LMV232. In normal operation,

the two PA’s in the setup will never be active at the same

time. One PA will produce the required transmit power, while

the other one is off, (disabled) and produces no power. The

pedestal voltage should be measured in the absence of RF

power. This can be achieved by switching the Band Select

(BS) pin such that the LMV232 input is selected where the

disabled PA is connected to. The pedestal voltage at no input

power can be read at the output pin.

Using the Band Select (BS) control pin of the LMV232:

•Select the RF input that is connected to the disabled PA,

by the BS pin.

•Measure the detector output.

•Store the result in the phone memory.

•Subtract the stored value from each detector power read-

ing, until a new update is performed.

Important advantages of this approach are that no factory

trim is required and the temperature drift of the pedestal can

be cancelled almost completely as well as the part-to-part

spread. The remaining error is determined by the resolution

of the ADC. A slight disadvantage is that on average more

than one detector reading is required per power measure-

ment. This overhead though can be made almost negligible

in normal circumstances.

20127808

FIGURE 7. Strategy 3: Calibration during normal

operation

LMV232

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Physical Dimensions inches (millimeters) unless otherwise noted

NOTES: UNLESS OTHERWISE SPECIFIED

1. EPOXY COATING

2. FOR SOLDER BUMP COMPOSITION, SEE “SOLDER INFORMATION” IN THE PACKAGING SECTION OF THE NATIONAL SEMICONDUCTOR WEB

(www.national.com).

3. RECOMMEND NON-SOLDER MASK DEFINED LANDING PAD.

4. PIN A1 IS ESTABLISHED BY LOWER LEFT CORNER WITH RESPECT TO TEXT ORIENTATION.

5. XXX IN DRAWING NUMBER REPRESENTS PACKAGE SIZE VARIATION WHERE X1 IS PACKAGE WIDTH, X2 IS PACKAGE LENGTH AND X3 IS

PACKAGE HEIGHT.

REFERENCE JEDEC REGISTRATION MO-211, VARIATION DD.

8-Bump micro SMD

NS Package Number TLA08AAA

X1 = 1.514 ±0.030 mm X2 = 1.514 ±0.030 mm X3 = 0.600 ±0.075 mm

National does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and National reserves

the right at any time without notice to change said circuitry and specifications.

For the most current product information visit us at www.national.com.

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device or system whose failure to perform can be reasonably

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LMV232 Dual-Channel Integrated Mean Square Power Detector for CDMA & WCDMA

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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 Applications

Audio www.ti.com/audio Communications and Telecom www.ti.com/communications

Amplifiers amplifier.ti.com Computers and Peripherals www.ti.com/computers

Data Converters dataconverter.ti.com Consumer Electronics www.ti.com/consumer-apps

DLP®Products www.dlp.com Energy and Lighting www.ti.com/energy

DSP dsp.ti.com Industrial www.ti.com/industrial

Clocks and Timers www.ti.com/clocks Medical www.ti.com/medical

Interface interface.ti.com Security www.ti.com/security

Logic logic.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense

Power Mgmt power.ti.com Transportation and Automotive www.ti.com/automotive

Microcontrollers microcontroller.ti.com Video and Imaging www.ti.com/video

RFID www.ti-rfid.com

OMAP Mobile Processors www.ti.com/omap

Wireless Connectivity www.ti.com/wirelessconnectivity

TI E2E Community Home Page e2e.ti.com

Mailing Address: Texas Instruments, Post Office Box 655303, Dallas, Texas 75265