LMX2470SLEX/NOPB - Texas Instruments

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

LMX2470 2.6 GHz Delta-Sigma Fractional-N PLL with 800 MHz Integer-N PLL

Check for Samples: LMX2470

1FEATURES DESCRIPTION

The LMX2470 is a low power, high performance

2• Low In-Band Phase Noise and Low Fractional delta-sigma fractional-N PLL with an auxiliary integer-

Spurs N PLL. The device is fabricated using TI’s advanced

• 12 Bit or 22 Bit Selectable Fractional Modulus BiCMOS process.

• Up to 4th Order Programmable Delta-Sigma With delta-sigma architecture, fractional spur

Modulator compensation is achieved with noise shaping

• Enhanced Anti-Cycle Slip Fastlock Circuitry capability of the delta-sigma modulator and the

inherent low pass filtering of the PLL loop filter.

– Fastlock Fractional spurs at lower frequencies are pushed to

– Cycle Slip Reduction higher frequencies outside the loop bandwidth. Unlike

– Integrated Timeout Counters analog compensation, the digital feedback techniques

used in the LMX2470 are highly resistant to changes

• Digital Lock Detect Output in temperature and variations in wafer processing.

• Prescalers Allow Wide Range of N Values With delta-sigma architecture, the ability to push

– RF PLL: 16/17/20/21 close in spur and phase noise energy to higher

– IF PLL: 8/9 or 16/17 frequencies is a direct function of the modulator

order. The higher the order, the more this energy can

• Crystal Reference Frequency up to 110 MHz be spread to higher frequencies. The LMX2470 has a

• On-chip Crystal Reference Frequency Doubler. programmable modulator up to order four, which

• Phase Comparison Frequency up to 30 MHz allows the designer to select the optimum modulator

order to fit the phase noise, spur, and lock time

• Hardware and Software Power-down Control requirements of the system.

• Ultra Low Consumption: ICC = 4.1 mA (Typical) Programming is fast and simple. Serial data is

transferred into the LMX2470 via a three line

APPLICATIONS MICROWIRE interface (Data, Clock, Load Enable).

• Cellular Phones and Base Stations Nominal supply voltage is 2.5 V. The LMX2470

– CDMA, WCDMA, GSM/GPRS, TDMA, EDGE, features a typical current consumption of 4.1 mA at

2.5 V. The LMX2470 is available in a 24 lead 3.5 X

PDC 4.5 X 0.6 mm package.

• Applications Requiring Fine Frequency

Resolution

• Satellite and Cable TV Tuners

• WLAN Standards

1Please 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.

2All trademarks are the property of their respective owners.

Products conform to specifications per the terms of the Texas

Instruments standard warranty. Production processing does not

necessarily include testing of all parameters.

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Functional Block Diagram

Connection Diagram

Figure 1. 24-Pin ULGA (NPF) Package

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

PIN DESCRIPTIONS

Pin # Pin Name I/O Pin Description

1 CPoutRF O RF charge pump output.

2 GND - Ground

3 GND - RF Ground

4 GND - Ground for RF PLL digital circuitry.

5 FinRF I RF prescaler input. Small signal input from the VCO.

6 FinRF* I RF prescaler complimentary input. For single-ended operation, a bypass capacitor should be placed

as close as possible to this pin and be connected directly to the ground plane.

7 VccRF RF PLL power supply voltage input. Must be equal to VccIF . May range from 2.25V to 2.75V.

Bypass capacitors should be placed as close as possible to this pin and be connected directly to the

ground plane.

8 EN I Chip enable input. High impedance CMOS input. When EN is high, the chip is powered up, otherwise

it is powered down.

9 ENOSC I This pin should be grounded for normal operation.

10 CLK I MICROWIRE Clock. High impedance CMOS Clock input. Data for the various counters is clocked

into the 24 bit shift register on the rising edge.

11 DATA I MICROWIRE Data. High impedance binary serial data input.

12 LE MICROWIRE Load Enable. High impedance CMOS input. Data stored in the shift registers is loaded

into the internal latches when LE goes HIGH

13 Ftest/LD O Test frequency output / Lock Detect

14 VddIF - Digital power supply for IF PLL

15 VccIF - IF power supply voltage input. Must be equal to VccRF. Input may range from 2.25 V to 2.75 V.

Bypass capacitors should be placed as close as possible to this pin and be connected directly to the

ground plane.

16 GND - Ground for RF PLL digital circuitry.

17 FinIF I IF prescaler input. Small signal input from the VCO.

18 GND - Digital ground for IF PLL

19 CPoutIF O IF PLL charge pump output

20 FLoutIF O IF Fastlock Output. Also functions as Programmable TRI-STATE CMOS output.

21 OSCout* I/O Complementary reference input or oscillator output.

22 OSCin I Reference input

23 VddRF - Digital power supply for RF PLL

24 FLoutRF O RF Fastlock Output. Also functions as Programmable TRI-STATE CMOS output.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

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.

Absolute Maximum Ratings (1) (2)

Value

Parameter Symbol Units

Min Typ Max

Power Supply Voltage VCC -0.3 3.0 V

VDD VCC VCC V

Voltage on any pin with GND =VSS = 0V Vi-0.3 VCC + 0.3 V

Storage Temperature Range Ts-65 +150 °C

Lead Temperature (Solder 4 sec.) TL+260 °C

(1) “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. "Recommended Operating Conditions"

indicate conditions for which the device is intended to be functional, but do not ensure specific performance limits. For ensured

specifications and test conditions, see the Electrical Characteristics. The ensured specifications apply only for the test conditions listed.

Note also that these maximum ratings imply that the voltage at all the power supply pins of VccRF, VccIF, VddRF, and VddIF are the

same. VCCwill be used to refer to the voltage at these pins.

(2) This Device is a high performance RF integrated circuit with an ESD rating < 2 kV and is ESD sensitive. Handling and assembly of this

device should only be done at ESD-free workstations.

Recommended Operating Conditions Value

Parameter Symbol Units

Min Typ Max

Power Supply Voltage (1) VCC 2.25 2.75 V

VDD VCC VCC V

Operating Temperature TA-40 +85 °C

(1) “Absolute Maximum Ratings” indicate limits beyond which damage to the device may occur. "Recommended Operating Conditions"

indicate conditions for which the device is intended to be functional, but do not ensure specific performance limits. For ensured

specifications and test conditions, see the Electrical Characteristics. The ensured specifications apply only for the test conditions listed.

Note also that these maximum ratings imply that the voltage at all the power supply pins of VccRF, VccIF, VddRF, and VddIF are the

same. VCCwill be used to refer to the voltage at these pins.

Electrical Characteristics

(VCC = 2.5V; -40°C ≤TA≤+85°C unless otherwise specified) Value

Symbol Parameter Conditions Units

Min Typ Max

Icc PARAMETERS

ICCRF Power Supply Current, RF IF PLL OFF

Synthesizer RF PLL ON 2.7 3.9 mA

Charge Pump TRI-STATE

OSC=0

ICCIF Power Supply Current, IF IF PLL ON

Synthesizer RF PLL OFF 1.4 2.3 mA

Charge Pump TRI-STATE

OSC=0

ICCTOTAL Power Supply Current, Entire IF PLL ON

Synthesizer RF PLL ON 4.1 6.0 mA

Charge Pump TRI-STATE

OSC=0

ICCPD Power Down Current EN = ENOSC = 0V 1 10 µA

CLK, DATA, LE = 0V

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Electrical Characteristics (continued)

(VCC = 2.5V; -40°C ≤TA≤+85°C unless otherwise specified) Value

Symbol Parameter Conditions Units

Min Typ Max

RF SYNTHESIZER PARAMETERS

fFinRF Operating Frequency 500 2600 MHz

pFinRF Input Sensitivity -15 0 dBm

fCOMP Phase Detector Frequency 30 MHz

ICPoutRFSRCE RF Charge Pump Source RF_CPG = 0 100 µA

Current VCPoutRF=VCC /2

RF_CPG = 1 200 µA

VCPoutRF=VCC/2

... ... µA

RF_CPG = 15 1600 µA

VCPoutRF=VCC/2

ICPoutRFSINK RF Charge Pump Sink Current RF_CPG = 0 -100 µA

VCPoutRF=VCC/2

RF_CPG = 1 -200 µA

VCPoutRF=VCC/2

... ... µA

RF_CPG = 15 -1600 µA

VCPoutRF=VCC/2

ICPoutRFTRI RF Charge Pump TRI-STATE 0.4 ≤VCPoutRF ≤VCC -0.4 2 10 nA

Current Magnitude

ICPoutRF%MIS RF CP Sink vs. CP Source VCPoutRF = VCC/2 3 10 %

Mismatch TA= 25°C

ICPoutRF%V RF CP Current vs. CP Voltage 0.4 ≤VCPoutRF ≤VCC -0.4 5 15 %

TA= 25°C

ICPoutRF%TEMP RF CP Current vs. Temperature VCPoutRF = VCC/2 8 %

IF SYNTHESIZER PARAMETERS

fFinIF Operating Frequency 75 800 MHz

pFinIF IF Input Sensitivity -15 0 dBm

fCOMP Phase Detector Frequency 10 MHz

ICPoutIFSRCE IF Charge Pump Source Current IF_CPG = 0 1 mA

VCPoutIF = VCC /2

IF_CPG = 1 4 mA

VCPoutIF = VCC/2

ICPoutIFSINK IF Charge Pump Sink Current IF_CPG = 0 -1 mA

VCPoutIF = VCC/2

IF_CPG = 1 -4 mA

VCPoutIF = VCC/2

ICPoutIFTRI IF Charge Pump TRI-STATE 0.4 ≤VCPoutIF ≤VCC RF -0.4 2 10 nA

Current Magnitude

ICPoutIF%MIS IF CP Sink vs. CP Source VCPoutIF = VCC/2 3 %

Mismatch TA= 25°C

ICPoutIF%V IF CP Current vs. CP Voltage 0.4 ≤VCPoutIF ≤VCC -0.4 8 15 %

TA= 25°C

ICPoutIF%TEMP IF CP Current vs. Temperature VCPoutIF = VCC/2 8 %

OSCILLATOR PARAMETERS

fOSCin Oscillator Operating Frequency OSC2X = 0 5 110 MHz

OSC2X = 1 5 20 MHz

vOSCin Oscillator Input Sensitivity 0.5 VCC V

IOSCin Oscillator Input Current -100 100 µA

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Electrical Characteristics (continued)

(VCC = 2.5V; -40°C ≤TA≤+85°C unless otherwise specified) Value

Symbol Parameter Conditions Units

Min Typ Max

DIGITAL INTERFACE (DATA, CLK, LE, EN, ENRF, Ftest/LD, FLoutRF, FLoutIF)

VIH High-Level Input Voltage 1.6 VCC V

VIL Low-Level Input Voltage 0.4 V

IIH High-Level Input Current VIH = VCC -1.0 1.0 µA

IIL Low-Level Input Current VIL = 0 V -1.0 1.0 µA

VOH High-Level Output Voltage IOH = -500 µA VCC-0.4 V

VOL Low-Level Output Voltage IOL = 500 µA 0.4 V

MICROWIRE INTERFACE TIMING

TCS Data to Clock Set Up Time See MICROWIRE INPUT TIMING 50 ns

DIAGRAM

TCH Data to Clock Hold Time See MICROWIRE INPUT TIMING 10 ns

DIAGRAM

TCWH Clock Pulse Width High See MICROWIRE INPUT TIMING 50 ns

DIAGRAM

TCWL Clock Pulse Width Low See MICROWIRE INPUT TIMING 50 ns

DIAGRAM

TES Clock to Load Enable Set Up See MICROWIRE INPUT TIMING 50 ns

Time DIAGRAM

TEW Load Enable Pulse Width See MICROWIRE INPUT TIMING 50 ns

DIAGRAM

PHASE NOISE

LF1HzRF RF Synthesizer Normalized RF_CPG = 0 -200 dBc/Hz

Phase Noise Contribution (1) RF_CPG = 3 -206 dBc/Hz

RF_CPG = 7 -208 dBc/Hz

RF_CPG = 15 -210 dBc/Hz

LF1HzIF IF Synthesizer Normalized Applies to both low and high current -209 dBc/Hz

Phase Noise Contribution (1) modes

(1) Normalized Phase Noise Contribution is defined as: LN(f) = L(f) – 20log(N) – 10log(fCOMP) where L(f) is defined as the single side band

phase noise measured at an offset frequency, f, in a 1 Hz Bandwidth. The offset frequency, f, must be chosen sufficiently smaller than

the PLL loop bandwidth, yet large enough to avoid substantial phase noise contribution from the reference source. The offset chosen

was 4 KHz.

MICROWIRE INPUT TIMING DIAGRAM

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Typical Performance Characteristics: Sensitivity

RF N Counter Sensitivity RF N Counter Sensitivity

TA= 25°C VCC = 2.5 V

Figure 2. Figure 3.

IF N Counter Sensitivity IF N Counter Sensitivity

TA= 25°C VCC = 2.5 V

Figure 4. Figure 5.

OSCin Counter Sensitivity OSCin Counter Sensitivity

OSC=0 OSC=0

TA= 25°C VCC= 2.5 V

Figure 6. Figure 7.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Typical Performance Characteristics: FinRF Input Impedance

Figure 8.

FinRF Input Impedance

Frequency (MHz) Real (Ohms) Imaginary (Ohms)

500 214 -255

600 175 -245

700 144 -230

800 118 -216

900 98 -203

1000 80 -189

1100 69 -177

1200 57 -165

1300 48 -153

1400 39 -141

1500 34 -130

1600 28 -119

1700 24 -110

1800 20 -101

1900 17 -94

2000 14 -87

2100 13 -82

2200 11 -77

2300 10 -72

2400 8 -67

2500 7 -62

2600 7 -56

2700 7 -53

2800 7 -46

2900 7 -41

3000 7 -39

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Typical Performance Characteristics: FinIF Input Impedance

Figure 9.

FinIF Input Impedance

Freqeuncy (MHz) Real (Ohms) Imaginary (Ohms)

50 580 -313

100 500 -273

150 445 -250

200 410 -256

250 378 -259

300 349 -264

350 322 -267

400 297 -270

450 274 -271

500 253 -272

550 232 -272

600 214 -269

650 198 -265

700 184 -262

750 170 -259

800 157 -256

900 151 -253

1000 143 -250

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Typical Performance Characteristics: OSCin Input Impedance

Figure 10.

OSCin Input Impedance

Frequency (MHz) Real (Ohms) Imaginary (Ohms) Magnitude (Ohms)

50 2200 -4700 5189

10 710 -2700 2792

20 229 -1500 1517

30 133 -988 997

40 93 -752 758

50 74 -606 611

60 62 -505 509

70 53 -435 438

80 49 -382 385

90 45 -341 344

100 42 -309 312

110 40 -282 285

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Typical Performance Characteristics: Currents

Total Current Consumption Powerdown Current

OSC=0 EN = LOW

Figure 11. Figure 12.

RF Charge Pump Current IF Charge Pump Current

VCC = 2.5 Volts VCC = 2.5 Volts

Figure 13. Figure 14.

Charge Pump Leakage Charge Pump Leakage

RF PLL IF PLL

Typical performance characteristics do not imply any sort of ensured

specification. Ensured specifications are in the Electrical

Characteristics.

Figure 15. Figure 16.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

BENCH TEST SETUPS

Charge Pump Current Measurement Procedure

The above block diagram shows the test procedure for testing the RF and IF charge pumps. These tests include

absolute current level, mismatch, and leakage. In order to measure the charge pump currents, a signal is applied

to the high frequency input pins. The reason for this is to ensure that the phase detector gets enough transitions

in order to be able to change states. If no signal is applied, it is possible that the charge pump current reading

will be low due to the fact that the duty cycle is not 100%. The OSCin Pin is tied to the supply. The charge pump

currents can be measured by simply programming the phase detector to the necessary polarity. For instance, in

order to measure the RF charge pump current, a 10 MHz signal is applied to the FinRF pin. The source current

can be measured by setting the RF PLL phase detector to a positive polarity, and the sink current can be

measured by setting the phase detector to a negative polarity. The IF PLL currents can be measured in a similar

way. Note that the magnitude of the RF and IF PLL charge pump currents are also controlled by the RF_CPG

and IF_CPG bits. Once the charge pump currents are known, the mismatch can be calculated as well. In order to

measure leakage currents, the charge pump current is set to a TRI-STATE mode by enabling the counter reset

bits. This is RF_RST for the RF PLL and IF_RST for the IF PLL. The table below shows a summary of the

various charge pump tests.

Current Test RF_CPG RF_CPP RF_CPT IF_CPG IF_CPP IF_CPT

RF Source 0 to 15 0 0 X X X

RF Sink 0 to 15 1 0 X X X

RF TRI-STATE X X 1 X X X

IF Source X X X 0 to 1 0 0

IF Sink X X X 0 to 1 1 0

IF TRI-STATE X X X X X 1

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Frequency Input Pin DC Blocking Corresponding Default Counter MUX Value OSC

Capacitor Counter Value

OSCin 1000 pF RF_R / 2 50 14 0

FinRF 100 pF RF_N / 2 500 15 X

FinIF 100 pF IF_N / 2 500 13 X

Sensitivity Measurement Procedure

Sensitivity is defined as the power level limits beyond which the output of the counter being tested is off by 1 Hz

or more of its expected value. It is typically measured over frequency, voltage, and temperature. In order to test

sensitivity, the MUX[3:0] word is programmed to the appropriate value. The counter value is then programmed to

a fixed value and a frequency counter is set to monitor the frequency of this pin. The expected frequency at the

Ftest/LD pin should be the signal generator frequency divided by twice the corresponding counter value. The

factor of two comes in because the LMX2470 has a flip-flop which divides this frequency by two to make the duty

cycle 50% in order to make it easier to read with the frequency counter. The frequency counter input impedance

should be set to high impedance. In order to perform the measurement, the temperature, frequency, and voltage

is set to a fixed value and the power level of the signal is varied. Note that the power level at the part is assumed

to be 4 dB less than the signal generator power level. This accounts for 1 dB for cable losses and 3 dB for the

pad. The power level range where the frequency is correct at the Ftest/LD pin to within 1 Hz accuracy is

recorded for the sensitivity limits. The temperature, frequency, and voltage can be varied in order to produce a

family of sensitivity curves. Since this is an open-loop test, the charge pump is set to TRI-STATE and the unused

side of the PLL (RF or IF) is powered down when not being tested. For this part, there are actually four frequency

input pins, although there is only one frequency test pin (Ftest/LD). The conditions specific to each pin are show

above.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Input Impedance Measurement Procedure

The above block diagram shows the test procedure measuring the input impedance for the LMX2470. This

applies to the FinRF, FinIF, and OSCin pins. The basic test procedure is to calibrate the network analyzer,

ensure that the part is powered up, and then measure the input impedance. The network analyzer can be

calibrated by using either calibration standards or by soldering resistors directly to the evaluation board. An open

can be implemented by putting no resistor, a short can be implemented by using a 0 ohm resistor, and a short

can be implemented by using two 100 ohm resistors in parallel. Note that no DC blocking capacitor is used for

this test procedure. This is done with the PLL removed from the PCB. This requires the use of a clamp down

fixture that may not always be generally available. If no clamp down fixture is available, then this procedure can

be done by calibrating up to the point where the DC blocking capacitor usually is, and then adding a 0 ohm

resistor back for the actual measurement. Once that the network analyzer is calibrated, it is necessary to ensure

that the PLL is powered up. This can be done by toggling the power down bits (RF_PD and IF_PD) and

observing that the current consumption indeed increases when the bit is disabled. Sometimes it may be

necessary to apply a signal to the OSCin pin in order to program the part. If this is necessary, disconnect the

signal once it is established that the part is powered up. It is useful to know the input impedance of the PLL for

the purposes of debugging RF problems and designing matching networks. Another use of knowing this

parameter is make the trace width on the PCB such that the input impedance of this trace matches the real part

of the input impedance of the PLL frequency of operation. In general, it is good practice to keep trace lengths

short and make designs that are relatively resistant to variations in the input impedance of the PLL.

Functional Description

GENERAL

The basic phase-lock-loop (PLL) configuration consists of a high-stability crystal reference oscillator, a frequency

synthesizer such as the TI LMX2470, a voltage controlled oscillator (VCO), and a passive loop filter. The

frequency synthesizer includes a phase detector, current mode charge pump, as well as programmable

reference [R] and feedback [N] frequency dividers. The VCO frequency is established by dividing the crystal

reference signal down via the R counter to obtain a frequency that sets the comparison frequency. This

comparison frequency, fCOMP, is input of a phase/frequency detector and compared with another signal, fN, the

feedback signal, which was obtained by dividing the VCO frequency down by way of the N counter and fractional

circuitry. The phase/frequency detector's current source outputs a charge into the loop filter, which is then

converted into the VCO's control voltage. The function of the phase/frequency comparator is to adjust the voltage

presented to the VCO until the frequency and phase of the feedback signal match that of the reference signal.

When this ‘phase-locked’ condition exists, the VCO frequency will be N+F times that of the comparison

frequency, where N is the integer component of the divide ratio and F is the fractional component. Fractional

synthesis allows the phase detector frequency to be increased while maintaining the same frequency step size

for channel selection. The division value N is thereby reduced giving a lower phase noise referred to the phase

detector input, and the comparison frequency is increased allowing faster switching times.

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

PHASE DETECTOR OPERATING FREQUENCY

The maximum phase detector operating frequency for the LMX2470 is 30 MHz. However, this is not possible in

all circumstances due to illegal divide ratios of the N counter. The crystal reference frequency also limits the

phase detector frequency. There are trade-offs in choosing what phase detector frequency to operate at. If this

frequency is run higher, then phase noise will be lower, but lock time may be increased due to cycle slipping.

After this phase detector frequency gets sufficiently high, then there are diminishing returns for phase noise, and

raising the charge pump current has a greater impact on phase noise. This phase detector frequency also has an

impact on fractional spurs. In general, the spur performance is better at higher phase detector frequencies,

although this is application specific. The current consumption may also slightly increase with higher phase

detector frequencies.

OSCILLATOR

The LMX2470 provides maximum flexibility for choosing an oscillator reference. One possible method is to use a

single-ended TCXO to drive the OSCin pin. The part can also be configured to be driven differentially using the

OSCin and OSCout* pins. Note that the OSCin and OSCout* pins can not be used as an inverter for a crystal.

Selection between these two modes does have a noticeable impact on phase noise and sub-fractional spurs.

Regardless of which mode is used, the performance is generally best for higher oscillator power levels.

POWER DOWN AND POWER UP MODES

The power down state of the LMX2470 is controlled by many factors. The one factor that overrides all other

factors is the EN pin. If this pin is low, this ensures the part will be powered down. Asserting a high logic level on

EN is necessary to power up the chip, however, there are other bits in the programming registers that can

override this and put the PLL back in a power down state. Provided that the voltage on the EN pin is high,

programming the RF_PD and IF_PD bits to zero ensures that the part will be powered up. Programming either

one of these bits to one will power down the appropriate section of the synthesizer, provided that the ATPU[1:0]

(Auto Power Up) bits do not override this.

There are many different ways to power down this chip and many different things that can be powered down.

This section discusses how to power down the PLLs on the chip. There are two terms that need to be defined

first: synchronous power down and asynchronous power down. In the case of synchronous power down, the PLL

chip powers down after the charge pump turns off. This is best to prevent unwanted frequency glitches upon

power up. However, in certain cases where the charge pump is stuck on, such as the case when there is no

VCO signal applied, this type of power down will not reliably work and asynchronous power down is necessary.

In the case of asynchronous power down, the PLL powers down regardless of the status of the charge pump.

There are 4 factors that affect the power down state of the chip: the EN pin, the power down bit, the TRI-STATE

bit, and writing to the RF N counter with the RF_ATPU[1:0] bits enabled

EN Pin ATPU[1:0] Bits Enabled RF_PD Bit RF_CPT Bit PLL State

RF N Counter Written To

Low X X X Asynchronous Power

Down

High Yes X X PLL is active with charge

pump in the active state.

High No 0 0 PLL is active with charge

pump in the active state.

High No 0 1 PLL is active, but charge

pump is TRI-STATE.

High No 1 0 Synchronous Power Down

High No 1 1 Asynchronous Power

Down

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

DIGITAL LOCK DETECT OPERATION

The RF PLL digital lock detect circuitry compares the difference between the phase of the inputs of the phase

detector to a RC generated delay of 10 nS. To enter the locked state (Lock = HIGH) the phase error must be

less than the 10nS RC delay for 5 consecutive reference cycles. Once in lock (Lock = HIGH), the RC delay is

changed to approximately 20nS. To exit the locked state (Lock = LOW), the phase error must become greater

than the 20nS RC delay. When the PLL is in the power down mode, Lock is forced LOW. For the RF PLL, the

digital lock detect circuitry does not function reliably for comparison frequencies above 20 MHz.

The IF PLL digital lock detect circuitry works in a very similar way as the RF PLL digitial lock circuitry, except that

it uses a delay of less than 15 nS for 5 reference cycles to determine a locked condition and a delay of greater

than 30 nS to determine the IF PLL is unlocked. Note that if the MUX[3:0] word is set such as to view lock detect

for both PLLs, an unlocked (LOW) condition is shown whenever either one of the PLLs is determined to be out of

lock. A flow chart of the IF digital lock detect circuitry is shown below.

PCB LAYOUT CONSIDERATIONS

Power Supply Pins For these pins, it is recommended that these be filtered by taking a series 18 ohm resistor

and then placing two capacitors shunt to ground, thus creating a low pass filter. Although it makes sense to use

large capacitor values in theory, the ESR (Equivalent Series Resistance) is greater for larger capacitors. For

optimal filtering minimize the sum of the ESR and theoretical impedance of the capacitor. It is therefore

recommended to provide two capacitors of very different sizes for the best filtering. 0.1 µF and 100 pF are typical

values. The charge pump supply pins in particular are vuvulnerablenerable to power supply noise.

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

High Frequency Input Pins, FinRF and FinIF The signal path from the VCO to the PLL is the most sensitive

and challenging for board layout. It is generally recommended that the VCO output go through a resistive pad

and then through a DC blocking capacitor before it gets to these high frequency input pins. If the trace length is

sufficiently short (< 1/10th of a wavelength), then the pad may not be necessary, but a series resistor of about 39

ohms is still recommended to isolate the PLL from the VCO. The DC blocking capacitor should be chosen at

least to be 100 pF. It may turn out that the frequency in this trace is above the self-resonant frequency of the

capacitor, but since the input impedance of the PLL tends to be capacitive, it actually be a benefit to exceed the

self-resonant frequency. The pad and the DC blocking capacitor should be placed as close to the PLL as

possible

Complimentary High Frequency Pin, FinRF* These inputs may be used to drive the PLL differentially, but it is

very common to drive the PLL in a single ended fashion. A shunt capacitor should be placed at the FinRF* pin.

The value of this capacitor should be chosen such that the impedance, including the ESR of the capacitor, is as

close to an AC short as possible at the operating frequency of the PLL. 100 pF is a typical value.

FASTLOCK AND CYCLE SLIP REDUCTION

The LMX2470 has enhanced features for Fastlock and cycle slip operation. The next several sections discuss

the the benefits of using both of these features. There are four possible combinations that are possible, and

these are shown in the table below:

Decrease Comparison

Keep Comparison

Charge Pump Current Frequency (CSR)

Frequency the Same (RF Side Only)

Increase Charge Pump Current Classical Fastlock CSR/Fastlock Combination

Allows the loop bandwidth to be increased. Engaging the CSR does decrease the loop

This has a frequency glitch caused by bandwidth during frequency acquisition, but

switching the charge pump currents, but may be necessary to reduce cycle slipping.

there is no frequency glitch caused by By also increasing the charge pump current,

switching from fractional to integer mode this can compensate for the reduce loop

bandwidth due to the CSR

Keep Charge Pump Current the Same Operation with No Fastlock CSR Only

This mode represents using no Fastlock This mode is not generally recommended,

but may reduce cycle slipping in some

applications. Although the theoretical lock

time is decreased, due to the decreased loop

bandwidth during Fastlock, cycle slips can be

reduced or eliminated.

Decrease Charge Pump Current It never makes sense to use a lower charge

pump current during Fastlock than in the

steady state.

Note that if the charge pump current and cycle slip reduction circuitry are engaged in the same proportion, then it

is not necessary to switch in a Fastlock resistor and the loop filter will be optimized for both normal mode and

Fastlock mode. For third and fourth order filters which have problems with cycle slipping, this may prove to be

the optimal choice of settings.

Determining the Loop Gain Multiplier, K

The loop bandwidth multiplier, K, is needed in order to determine the theoretical impact of fastlock/CSR on the

loop bandwidth and also which resistor should be switched in parallel with the loop filter resistor R2. K = K_K ·

K_Fcomp where K is the loop gain multiplier K_K is the ratio of the Fastlock charge pump current to the steady

state charge pump current. Note that this should always be greater than or equal to one. K_Fcomp is the ratio of

the Fastlock comparison frequency to the steady state comparison frequency. If this ratio is less than one, this

implies that the CSR is being used.

Determining the Theoretical Lock Time Improvement and Fastlock Resistor, R2’

When using fastlock, it is necessary to switch in a resistor R2’, in parallel with R2 in order to keep the loop filter

optimized and maintain the same phase margin. After the PLL has achieved a frequency that is sufficiently close

to the desired frequency, the resistor R2’ is disengaged and the charge pump current is and comparison

frequency are returned to normal. Of special concern is the glitch that is caused when the resistor R2’ is

disengaged. This glitch can take up a significant portion of the lock time. The LMX2470 has enhanced switching

circuitry to minimize this glitch and therefore improve the lock time.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

The change in loop bandwidth is dependent upon the loop gain multiplier, K, as determined in Determining the

Loop Gain Multiplier, K. The theoretical improvement in lock time is given below, but the actual improvement will

be less than this due to the glitch that is caused by disengaging Fastlock. The theoretical improvement is given

to show an upper bound on what improvement is possible with Fastlock. In the case that K < 1, this implies the

CSR is being engaged and that the theoretical lock time will be degraded. However, since this mode reduces or

eliminates cycle slipping, the actual lock time may be better in cases where the loop bandwidth is small relative

to the comparison frequency. Realize that the theoretical lock time multiplier does not account for the

fastlock/CSR disengagement glitch, which is most severe for larger values of K.

Loop Gain Loop Bandwidth Lock Time

R2’ Value

Multiplier, K Multiplier Multiplier

1:8(1) 0.35 open × 2.828

1:4(1) 0.50 open × 2.000

1:2(1) 0.71 open × 1.414

4:1 2.00 R2/1.00 × 0.500

8:1 2.83 R2/1.83 × 0.354

16:1 4.00 R2/3.00 × 0.250

32:1 5.66 R2/4.65 × 0.177

(1) These modes of operation are generally not recommended.

Using Fastlock and Cycle Slip Reduction (CSR) to Avoid Cycle Slipping

In the case that the comparison frequency is very large (i.e. 100 X) of the loop bandwidth, cycle slipping may

occur when an instantaneous phase error is presented to the phase detector. This can be reduced by increasing

the loop bandwidth during frequency acquisition, decreasing the comparison frequency during frequency

acquisition, or some combination of the these. If increasing the loop bandwidth during frequency acquisition is

not sufficient to reduce cycle slipping, the LMX2470 also has a routine to decrease the comparison frequency.

RF PLL Fastlock Reference Table and Example

The table below shows most of the trade-offs involved in choosing a steady-state charge pump current

(RF_CPG), the Fastlock charge pump current (RF_CPF), and the Cycle Slip Reduction Factor (CSR).

Parameter Advantages to Choosing Smaller Advantages to Choosing Larger

RF_CPG 1. Allows capacitors in loop filter to be smaller values Phase noise, especially within the loop bandwidth of the

making it easier to find physically smaller components and system

components with better dielectric properties. will be slightly worse for lower charge pump currents.

2. Allows a larger loop bandwidth multiplier for fastlock, or

a higher cycle slip reduction factor.

RF_CPF The only reason not to always choose this to 1600 µA is to This allows the maximum possible benefit for fastlock.

make it such that no resistor is required for fastlock. For

3rd and 4th order filters, it is not possible to keep the filter

perfectly optimized by simply switching in a resistor for

fastlock.

CSR Do not choose this any larger than necessary to eliminate This will eliminate cycle slips better.

cycle slipping. Keeping this small allows a larger loop

bandwidth multiplier for fastlock.

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

The above table shows various combinations for using RF_CPG, RF_CPF, and CSR. Although this table does

not show all possible combinations, it does show all the modes that give the best possible performance. To use

this table, choose a CSR factor on the horizontal axis, then a fastlock loop bandwidth multiplier on the vertical

axis, and the table will show all possible combinations of steady state current, Fastlock current, and what resistor

value (R2’) to use during Fastlock. In order to better illustrate the cycle slipping and Fastlock circuitry, consider

the following example:

Crystal Reference 10 MHz

Comparison Frequency 10 MHz × 2 = 20 MHz (OSC2X = 1)

Output Frequency 1930 – 1990 MHz

PLL Loop Bandwidth 10 KHz

Loop Filter Order 4th (i.e. 7 components)

The comparison frequency is 20 MHz and the loop bandwidth is 10 KHz. 20 MHz is a good comparison

frequency to use because it yields the best phase noise performance. This ratio of the comparison frequency to

the loop bandwidth is 2000, so cycle slipping will occur and degrade the lock time, unless something is done to

prevent it. Because the filter is fourth order, it would be difficult to keep the loop filter optimized if the loop gain

multiplier, K was not one. For this reason, choosing a loop gain multiplier of one makes sense. One solution is to

set the steady state current to be 100 µA, and the fastlock current to be 1600 µA. The CSR factor could be set to

1/16 and reduce this ratio to 2000/16 = 125. However, using 100 µA charge pump current has phase noise that

is significantly worse than the higher charge pump current modes. A better solution would be to use 200 µA

current and 1600 µA X2 (using PDCP = X2 Fastlock), since the 200 µA mode will have better phase noise.

Depending on how important phase noise is, it could make sense to use a higher steady state current. Using 800

µA steady state current provides much better phase noise than 200 uA (about 5 dB), but then the cycle slip

reduction factor would need to be reduced to 4. In general, it is good practice to use the PDCP = X2 fastlock

mode whenever cycle slip reduction is used, so that the best phase noise can be achieved. If the ¼ CSR factor

is used, then the ratio of comparison frequency to loop bandwidth in fastlock is reduced to 250. There may be

some cycle slipping, but the phase noise benefit of using the higher charge pump current may be worth it. If

phase noise is even more important, it might even make sense to have a steady state current of 1600 µA and

use a CSR factor of ½ and the PDCP mode of X2 Fastlock. Another consideration is that the comparison

frequency could be lowered in the steady state mode to reduce cycle slipping. This sacrifices phase noise for

lock time. In general, using Fastlock and CSR is not the same for every application. There is a trade-off of lock

time vs. phase noise. It might be tempting to try to achieve the best Fastlock benefit by using a K value of 32.

Even if the loop filter could be kept well optimized in Fastlock, this hypothetical design would probably switch

very fast when the Fastlock was engaged, but then when Fastlock is disengaged, a large frequency glitch would

appear, and the majority of the lock time would consist of waiting for this glitch to settle out. Although this would

definitely improve the lock time, even accounting for the glitch, the same result could probably be obtained by

using a lower K value, like 8, and having better phase noise instead.

Capacitor Dielectric Considerations for Lock Time

The LMX2470 has a high fractional modulus and high charge pump gain for the lowest possible phase noise.

One consideration is that the reduced N value and higher charge pump may cause the capacitors in the loop

filter to become larger in value. For larger capacitor values, it is common to have a trade-off between capacitor

dielectric quality and physical size. Using film capacitors or NP0/CG0 capacitors yields the best possible lock

times, where as using X7R or Z5R capacitors can increase lock time by 0 – 500%. However, it is a general

tendency that designs that use a higher compare frequency tend to be less sensitive to the effects of capacitor

dielectrics. Although the use of lesser quality dielectric capacitors may be unavoidable in many circumstances,

allowing a larger footprint for the loop filter capacitors, using a lower charge pump current, and reducing the

fractional modulus are all ways to reduce capacitor values. Capacitor dielectrics have very little impact on phase

noise and spurs.

FRACTIONAL SPUR AND PHASE NOISE CONTROLS FOR THE LMX2470

The LMX2470 has several bits that have a large impact on fractional spurs. These bits also have a lesser effect

on phase noise. The control words in question are CPUD[2:0], FM[1:0], and DITH[1:0]. It is difficult to predict

which settings will be optimal for a particular application without testing them, but the general recipe for using

these bits can be seen.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

A good algorithm is to start with a 3rd order fractional modulator (FM=3) and dithering disabled. Then depending

on whether phase noise, fractional spurs, or sub-fractional spurs are most important, optimize the settings.

Integer spurs and fractional spurs are nothing new, but sub-fractional spurs are something unique to delta-sigma

PLLs. These are spurs that occur at a fraction of the frequency of where a fractional spur would appear.

First adjust the delta-sigma modulator order. Often increasing from a 2nd to a 3rd order modulator provides a

large benefit in spur levels. Increasing from a 3rd to a 4th order modulator usually provides some benefit, but it is

usually on the order of a few dB. The modulator order by far has the greatest impact on the main fractional

spurs. If the loop bandwidth is very wide, or the loop filter order is not high enough, higher order modulators will

introduce a lot of sub-fractional spurs. The second order modulator usually does not have these sub-fractional

spurs. The third order modulator will introduce them at ½ of the frequency where one would expect to see a

traditional fractional spur, thus the name "sub-fractional spur". The fourth order modulator will introduce these

spurs at ½ and ¼ of where a traditional fractional spur would be. If the benefit of using a higher order modulator

seems significant enough, it may make sense to try to compensate for them using the other two test bits, or

designing a higher order loop filter. Be aware that the impact of the modulator order on the spurs may not be

consistent across tuning voltage. When the charge pump mismatch is not so bad, the lower order modulators

may seem to outperform the higher order modulators, but when the worst case fractional spurs are considered

over the whole range, often the higher order modulator performs better.

Second, adjust with the CPUD[2:0] bits. Setting this bit to maximum tends to reduce the sub-fractional spurs the

most, however, it may degrade phase noise by up to 1 dB.

Third, experiment with the dithering. When dithering is enabled, it may increase phase noise by up to 2 dB.

However, enabling dithering may also reduce the sub-fractional spurs. Also, sometimes both the fractional spurs

and the sub-fractional spurs can be unpredictable with dithering disabled. This is because the delta-sigma

sequence is periodic, but the starting point changes. Dithering takes these problems away. When the fractional

numerator is 0, enabling dithering typically hurts spur performance, because it is trying to correct for spur that are

not there.

Fourth, consider experimenting with the loop filter order and comparison frequency. In general, higher order loop

filters are always better, but they require more components. Often, the best spur performance is at higher

comparison frequencies as well. The reason why this is the last step is not because it has the least impact, but

because it takes more labor to do this than to change the FM[1:0], CPUD[2:0], and DITH[1:0] bits.

Although general trends do exist, the optimal settings for test bits may depend on the comparison frequency and

loop filter. Also the output frequency in important. In particular, the charge pump tuning voltage is relevant. The

recommended way to do this is to test the spur levels at the low, middle, and high range of the VCO, and use the

worst case over these three frequencies as a metric for performance. Also, it is important to be aware that all the

rules stated above have counterexamples and exceptions. However, more often than not, these rules apply.

Programming Description

GENERAL PROGRAMMING INFORMATION

The descriptions below describe the 24-bit data registers loaded through the MICROWIRE Interface. These data

registers are used to program the R counter, the N counter, and the internal mode control latches. The data

format of a typical 24-bit data register is shown below. The control bits CTL [3:0] decode the register address. On

the rising edge of LE, data stored in the shift register is loaded into one of the appropriate latches (selected by

address bits). Data is shifted in MSB first. Note that it is best to program the N counter last, since doing so

initializes the digital lock detector and Fastlock circuitry. Note that initialize means it resets the counters, but it

does NOT program values into these registers. Upon a cold power-up, it is necessary to program all the

registers. The exception is when 22-bit is not being used. In this case, it is not necessary to program the R7

MSB LSB

DATA [21:0] CTL [3:0]

23 4 3 2 1 0

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

The control bits CTL [2:0] decode the internal register address. The table below shows how the control bits are

mapped to the target control register.

C3 C2 C1 C0 DATA Location

x x x 0 R0

0 0 0 1 R1

0 0 1 1 R2

0 1 0 1 R3

0 1 1 1 R4

1 0 0 1 R5

1 0 1 1 R6

1 1 0 1 R7

1 1 1 1 R8

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Control Register Content Map

Because the LMX2470 registers are complicated, they are organized into two groups, basic and advanced. The first four registers are basic registers that

contain critical information necessary for the PLL to achieve lock. The last 5 registers are for features that optimize spur, phase noise, and lock time

performance. The next page shows these registers.

Quick Start Register Map

Although it is highly recommended that the user eventually take advantage of all the modes of the LMX2470, the quick start register map is shown in order for the user to get the part up and

running quickly using only those bits critical for basic functionality. The following default conditions for this programming state are a third order delta-sigma modulator in 22-bit mode with no

dithering and no Fastlock.

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R0 RF_N[10:0] RF_FN[11:0] 0

R1 RF_P 1 RF_R[5:0] RF_FD[11:0] 0 0 0 1

R2 IF_PD IF_P IF_CP IF_N[16:0] 0 0 1 1

R3 0 RF_CPG[3:0] IF_R[14:0] 0 1 0 1

R4 0 0 0 000000000000000000111

R5 0 0 0 100000000000000001001

R6 0 0 0 000000011000100001011

R7 0 0 0 000000000000000001101

R8 0 0 0 011000000100011101111

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

Complete Register Map

The complete register map shows all the functionality of all registers, including the last five.

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R0 RF_N[10:0] RF_FN[11:0] 0

R1 RF_P 1 RF_R[5:0] RF_FD[11:0] 0 0 0 1

R2 IF_PD IF_P IF_CP IF_N[17:0] 0 0 1 1

R3 0 RF_CPG[3:0] IF_R[14:0] 0 1 0 1

R4 CSR[1:0] RF_CPF[3:0] RF_TOC[13:0] 0 1 1 1

R5 0 0 0 1 0 0 0 0 IF_TOC[11:0] 1 0 0 1

R6 0 0 0 0 0 RF_ RF_ IF_C IF_C FDM FM[1:0] ATPU[1:0] OSC OSC MUX[3:0] 1 0 1 1

CPT CPP PT PP 2X

R7 RF_FD2[9:0] RF_FN2[9:0] 1 1 0 1

R8 0 0 0 0 DITH[1:0] 0 0 0 0 0 0 PDCP[1:0] 0 0 CPUD[2:0] 0 1 1 1 1

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

R0 REGISTER

Note that this register has only one control bit. The reason for this is that it enables the N counter value to be

changed with a single write statement to the PLL.

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R0 RF_N[10:0] FN[11:0] 0

RF_FN[11:0] -- Fractional Numerator for RF PLL

Refer to Fractional Numerator Determination { RF_FN2[9:0], RF_FN[11:0], FDM } for a more detailed description

of this control word.

RF_N[10:0] -- RF N Counter Value

The RF N counter contains a 16/17/20/21 prescaler. Because there is only one selection of prescaler, the value

that is programmed is simply the N counter value converted into binary form. However, because this counter

does have a prescaler, there are limitations on the divider values.

RF_N[10:0]

RF_N RF_C RF_B RF_A

≤65 N values less than or equal to 65 are prohibited.

66 Possible only with a second order delta-sigma engine

67 Possible with a second or third order delta-sigma engine.

6800001000100

6900001000101

..............

204011111111000

2041- Possible with a second or third order delta-sigma engine.

2044

2045- Possible only with a second order delta-sigma engine.

2046

>2046 N values above 2046 are prohibited.

R1 REGISTER

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R1 RF_ 1 RF_R[5:0] RF_FD[11:0] 0 0 0 1

RF_FD[11:0] -- RF PLL Fractional Denominator

The function of these bits are described in Fractional Denominator Determination { RF_FD2[9:0], RF_FD[11:0],

FDM }.

RF_R [5:0] -- RF R Divider Value

The RF R Counter value is determined by this control word. Note that this counter does allow values down to

one.

R Value RF_R[5:0]

1000001

.........

63111111

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

RF_PD -- RF Power Down Control Bit

When this bit is set to 0, the RF PLL operates normally. When it is set to one, the RF PLL is powered down and

the RF Charge pump is set to a TRI-STATE mode. Because the EN pin and ATPU[1:0] word also controls power

down functions, there may be some conflicts. The order of precedence is as follows. First, if the EN pin is LOW,

then the PLL will be powered down. Provided this is not the case, the PLL will be powered up if the ATPU[1:0]

word says to do so, regardless of the state of the RF_PD bit. After the EN pin and the ATPU[1:0] word are

considered, then the RF_PD bit then takes control of the power down function for the RF PLL.

R2 REGISTER

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R2 IF_P IF_P IF_C IF_N[17:0] 0 0 1 1

D PG

IF_N[16:0] -- IF N Divider Value

The IF N divider is a classical dual modulus prescaler with a selectable 8/9 or 16/17 modulus. The IF_N value is

determined by the IF_A , IF_B, and IF_P values. Note that the IF_P word can assume a value of 8 or 16. The

RF_A and RF_B counter values can be determined in accordance with the following equations.

B=NdivP

A=NmodP

B≥A is required in order to have a legal N divider ratio

Here the div operator is defined as the division of two numbers with the remainder disregarded and the mod

operator is defined as the remainder as a result of this division. For the purposes of programming, it turns out

that the register value is just the binary representation of the N value, with the exception that the 4th LSB is not

used and must be programmed to 0 when the 8/9 prescaler is used.

IF_N Programming with the 8/9 Prescaler

IF_N[16:0]

Value IF_B IF_A

<24 N Values Below 24 are prohibited since IF_B≥3 is required.

24-55 Legal divide ratios in this range are: 24-27, 32-36, 40-45, 48-54

5600000000001110000

................0...

655311111111111110111

RF_N Programming with 16/17 Prescaler

IF_N[16:0]

Value IF_B IF_A

≤47 N values less than or equal to 47 are prohibited because IF_B≥3 is required.

48- Legal divide ratios in this range are: 48-51, 64-68, 80-85, 96-102

239

24000000000001110000

....................

1310 1111111111111111

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

IF_CPG -- IF Charge Pump Gain

This bit determines the magnitude of the IF charge pump current

IF_CPG IF Charge Pump Current (mA)

0 Low (1 mA)

1 High (4 mA)

IF_P -- IF Prescaler Value

This bit selects which prescaler will be used for the IF N counter.

IF_P IF Prescaler Value

0 8 (8/9 Prescaler)

1 16 (16/17 Prescaler)

IF_PD -- IF Power Down Bit

When this bit is set to 0, the IF PLL operates normally. When it is set to 1, the IF PLL powers down and the

output of the IF PLL charge pump is set to a TRI-STATE mode. If the IF_CPT bit is set to 0, then the power

down state is synchronous and will not occur until the charge pump is off. If the IF_CPT bit is set to 1, then the

power down will occur immediately regardless of the state of the IF PLL charge pump.

R3 REGISTER

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R3 0 RF_CPG[3:0] IF_R[14:0] 0 1 0 1

IF_R[14:0] -- IF R Divider Value

For the IF R divider, the R value is determined by the IF_R[14:0] bits in the R3 register. The minimum value for

IF_R is 3.

R IF_R[14:0]

Value

3000000000000011

..................

32767111111111111111

RF_CPG -- RF PLL Charge Pump Gain

This is used to control the magnitude of the RF PLL charge pump in steady state operation

RF_CPG[3:0] RF Charge Pump Current (µA)

0 100

1 200

2 300

3 400

4 500

5 600

6 700

7 800

8 900

9 1000

10 1100

11 1200

12 1300

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

RF_CPG[3:0] RF Charge Pump Current (µA)

13 1400

14 1500

15 1600

R4 REGISTER

This register controls the conditions for the RF PLL in Fastlock.

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R4 CSR[1:0 RF_CPF[3:0] RF_TOC[13:0] 0 1 1 1

]

RF_TOC -- RF Time Out Counter and Control for FLoutRF Pin

The RF_TOC[13:0] word controls the operation of the RF Fastlock circuitry as well as the function of the

FLoutRF output pin. When this word is set to a value between 0 and 3, the RF Fastlock circuitry is disabled and

the FLoutRF pin operates as a general purpose CMOS TRI-STATE I/O. When RF_TOC is set to a value

between 4 and 16383, the RF Fastlock mode is enabled and the FLoutRF pin is utilized as the RF Fastlock

output pin. The value programmed into the RF_TOC[13:0] word represents four times the number of phase

detector comparison cycles the RF synthesizer will spend in the Fastlock state.

RF_TOC[13:0] Fastlock Mode Fastlock Period [CP events] FLoutRF Pin Functionality

0 Disabled N/A High Impedance

1 Manual N/A Logic “0” State.

Forces all fastlock conditions

2 Disabled N/A Logic “0” State

3 Disabled N/A Logic “1” State

4 Enabled 4X2 = 8 Fastlock

5 Enabled 5X2 = 10 Fastlock

… Enabled … Fastlock

16383 Enabled 16383X2=32766 Fastlock

RF_CPF -- RF PLL Fastlock Charge Pump Current

Specify the charge pump current for the Fastlock operation mode for the RF PLL. Note that the Fastlock charge

pump current, steady state current, and CSR control are all interrelated. Refer to section 4.0 for more details.

RF_CPF [3:0] Fastlock Charge Pump Current (µA)

0000 100

0001 200

0010 300

0011 400

0100 500

0101 600

0110 700

0111 800

1000 900

1001 1000

1010 1100

1011 1200

1100 1300

1101 1400

1110 1500

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

1111 1600

RF_CSR[1:0] -- RF Cycle Slip Reduction

CSR controls the operation of the Cycle Slip Reduction Circuit. This circuit can be used to reduce the occurrence

of phase detector cycle slips. Note that the Fastlock charge pump current, steady state current, and CSR control

are all interrelated. The table below gives some rough guidelines. In the table below, fCOMP is the comparison

frequency, and BW is the loop bandwidth of the PLL system. The rough guideline gives an idea of when it makes

sense to use this cycle slip reduction based on the steady-state conditions of the PLL system.

CSR[1:0] CSR State Sample Rate Reduction Factor Rough Guideline

0 Disabled 1 fCOMP < 100 × BW

1 Enabled 1/2 100 × BW < fCOMP < 200 × BW

2 Enabled 1/4 200 × BW < fCOMP < 400 × BW

3 Enabled 1/16 fCOMP > 400 × BW

R5 REGISTER

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C3 C2 C1 C0

R5 0 0 0 0 0 0 0 0 IF_TOC[11:0] 1 0 0 1

IF_TOC[11:0] IF Timeout Counter for Fastlock

The IF_TOC word controls the operation of the IF Fastlock circuitry as well as the function of the FLoutIF output

pin. When IF_TOC is set to a value between 0 and 3, the IF Fastlock circuitry is disabled and the FLoutIF pin

operates as a general purpose CMOS TRI-STATE output. When IF_TOC is set to a value between 4 and 4095,

the IF Fastlock mode is enabled and FLoutIF is utilized as the IF Fastlock output pin. The value programmed into

IF_TOC represents the number of phase comparison cycles that the IF synthesizer will spend in the Fastlock

state.

IF_TOC[11:0] Fastlock Mode Fastlock Period [Charge Pump FLoutIF Pin Functionality

Cycles]

0 Disabled N/A High Impedance

1 Manual N/A Logic “0” State

Forces IF charge pump current to

4 mA

2 Disabled N/A Logic “0” State

3 Disabled N/A Logic “1” State

4 Enabled 5 Fastlock

… Enabled … Fastlock

4095 Enabled 4095 Fastlock

R6 REGISTER

DATA[19:0] (Except for the RF_N Register, which is [22:0]) C C C C

3 2 1 0

R6 0 0 0 0 0 RF_ RF_ IF_ IF_ FDM FM[1:0] ATPU OSC OSC MUX 1 0 1 1

CPT CPP CPT CPP [1:0] 2X [3:0]

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

1 MUX[3:0] Frequency Out & Lock Detect MUX

These bits determine the output state of the Ftest/LD pin.

MUX[3:0] Output Type Output Description

0 0 0 0 High Impedance Disabled

0 0 0 1 Push-Pull General purpose

output, Logical “High”

State

0 0 1 0 Push-Pull General purpose

output, Logical “Low”

State

0 0 1 1 Push-Pull RF & IF Digital Lock

Detect

0 1 0 0 Push-Pull RF Digital Lock

Detect

0 1 0 1 Push-Pull IF Digital Lock Detect

0 1 1 0 Open Drain RF & IF Analog Lock

Detect

0 1 1 1 Open Drain RF Analog Lock

Detect

1 0 0 0 Open Drain IF Analog Lock

Detect

1 0 0 1 Push-Pull RF & IF Analog Lock

Detect

1 0 1 0 Push-Pull RF Analog Lock

Detect

1 0 1 1 Push-Pull IF Analog Lock

Detect

1 1 0 0 Push-Pull IF R Divider divided

by 2

1 1 0 1 Push-Pull IF N Divider divided

by 2

1 1 1 0 Push-Pull RF R Divider divided

by 2

1 1 1 1 Push-Pull RF N Divider divided

by 2

OSC -- Differential Oscillator Mode Enable

This bit selects between single-ended and differential mode for the OSCin and OSCout* pins. When this bit is set

to 0, the RF R and IF R counters are driven in a single-ended fashion through the OSCin pin. Note that the

OSCin and OSCout* pin can not be used to drive a crystal. When this bit is set to 1, the OSCin and OSCout*

pins are used to drive these R counters differentially. In some cases, spur performance may be better when this

is set to differential mode, even if the R counters are being driven in a single-ended fashion. Current

consumption in differential mode is slightly higher than when in single-ended mode.

OSC2X -- Oscillator Doubler Enable

When this bit is set to 0, the oscillator doubler is disabled TCXO frequency presented to the IF R counter is

unaffected. Phase noise added by the doulber is negligible.

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

ATPU -- PLL Automatic Power Up

This word enables the PLLs to be automatically powered up when their respective registers are written to. Note

that since the IF Powerdown bit is in the IF register, there is no need to have an ATPU function activated by the

R2 word.

ATPU RF PLL IF PLL

0 No auto power up No auto power up

1 Powers up when R0 is written to No auto power up

2 Powers up when R0 is written to Powers up when R0 is written to

3 Reserved

FM[1:0] -- Fractional Mode

Determines the order of the delta-sigma modulator. Higher order delta-sigma modulators reduce the spur levels

closer to the carrier by pushing this noise to higher frequency offsets from the carrier. In general, the order of the

loop filter should be at least one greater than the order of the delta-sigma modulator in order to allow for

sufficient roll-off.

FM Function

0 Fractional PLL mode with a 4th order delta-sigma modulator

1 Disable the delta-sigma modulator. Recommended for test use only.

2 Fractional PLL mode with a 2nd order delta-sigma modulator

3 Fractional PLL mode with a 3rd order delta-sigma modulator

FDM -- Fractional Denominator Mode

When this bit is set to 0, the part operates with a 12- bit fractional denominator. For most applications, 12-bit

mode should be adequate, but for those applications requiring ultra fine tuning resolution, there is 22-bit mode.

Note that the PLL may consume slightly more current when it is in 22-bit mode.

FDM Bits for Fractional Maximum Size of Fractional

Denominator/Numerator Denominator/Numerator

0 12-bit 4095

1 22-bit 4194303

IF_CPP -- IF PLL Charge Pump Polarity

When this bit is set to 1, the phase detector polarity for the IF PLL charge pump is positive. Otherwise set this bit

to 0 for a negative phase detector polarity

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

IF_CPT -- IF PLL Charge Pump TRI-STATE Mode

This bit enables the user to put the charge pump in a TRI-STATE (high impedance) condition. Note that if there

is a conflict, the ATPU bit overrides this bit.

RF_CPT Charge Pump State

0 ACTIVE

1 TRI-STATE

RF_CPP -- RF PLL Charge Pump Polarity

For a positive phase detector polarity, which is normally the case, set this bit to 1. Otherwise set this bit to 0 for a

negative phase detector polarity.

RF_CPT -- RF PLL Charge Pump TRI-STATE Mode

This bit enables the user to put the charge pump in a TRI-STATE (high impedance) condition. Note that if there

is a conflict, the ATPU bit overrides this bit.

RF_CPT Charge Pump State

0 Active

1 TRI-STATE

R7 REGISTER

DATA[19:0] C3 C2 C1 C0

R7 RF_FD2[9:0] RF_FN2[9:0] 1 1 0 1

Fractional Numerator Determination { RF_FN2[9:0], RF_FN[11:0], FDM }

In the case that the FDM bit is 0, then the part operates in 12-bit fractional mode, and the RF_FN2 bits become

don’t care bits. When the FDM is set to 1, the part operates in 22-bit mode and the fractional numerator is

expanded from 12 to 22-bits.

Fractional RF_FN2[9:0] RF_FN[11:0]

Numerator (These bits only apply in 22- bit mode)

0 000000000000

In 12- bit mode, these are don’t care.

1 000000000001

In 22- bit mode, for N <4096,

... . . . . . . . . . . . .

these bits should be all set to 0.

4095 1 1 1 1 1 1 1 1 1 1 1 1

4096 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0

... ......................

4194303 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

Fractional Denominator Determination { RF_FD2[9:0], RF_FD[11:0], FDM }

In the case that the FDM bit is 0, then the part is operates in the 12-bit fractional mode, and the RF_FD2 bits

become don’t care bits. When the FDM is set to 1, the part operates in 22-bit mode and the fractional

denominator is expanded from 12 to 22-bits.

Fractional RF_FD2[9:0] RF_FD[11:0]

Denominator (These bits only apply in 22- bit mode)

0 In 12- bit mode, these are don’t care. 0 0 0 0 0 0 0 0 0 0 0 0

In 22- bit mode, for N <4096,

1 000000000001

these bits should be all set to 0.

... . . . . . . . . . . . .

4095 1 1 1 1 1 1 1 1 1 1 1 1

4096 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0

... ......................

4194303 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1 1

R8 REGISTER

23 22 21 20 19 18 17 16 15 14 13 12 11 10 9 8 7 6 5 4 3 2 1 0

DATA[19:0] C3 C2 C1 C0

R8 0 0 0 0 DITH 0 0 0 0 0 0 PDCP 0 0 CPUD 0 1 1 1 1

[1:0] [1:0] [2:0]

The R8 Register controls some additional bits that may be useful in optimizing phase noise, lock time, and spurs.

CPUD[2:0] -- Charge Pump User Definition

This bit allows the user to choose from several different modes in the charge pump. The charge pump current is

unaffected, but the fractional spurs and phase noise are impacted by a few dB. In some designs, particularly if

the loop bandwidth is wide and a 4th order delta-sigma engine is used, small spurs may appear at a fraction of

where the first fractional spur should appear. In other designs, these sub-fractional spurs are not present. The

user needs to use this adjustment to make these sub-fractional spurs go away, while still getting the best phase

noise possible.

CPUD Mode Name Phase Noise Sub-Fractional Spurs

0 Reserved N/A N/A

1 Reserved N/A N/A

2 Minimum Best Worst

3 Maximum Worst Best

4 Reserved N/A N/A

5 Reserved N/A N/A

6 Reserved N/A N/A

7 Nominal Medium Medium

PDCP[1:0] -- Power Drive for Charge Pump

If this bit is enabled, the Fastlock current can be doubled during Fastlock. The charge pump current in steady

state is unaffected. States 0 and 1 should never be used.

PDCP Fastlock Charge Pump Current

0 Reserved

1 Reserved

2 Double Fastlock Current

3 Disabled

Product Folder Links: LMX2470

LMX2470

www.ti.com

SNAS195B –MARCH 2003–REVISED MARCH 2013

DITH[1:0] -- Dithering Control

Dithering is a technique used to spread out the spur energy. Enabling dithering can reduce the main fractional

spurs, but can also give rise to a family of smaller spurs. Whether dithering helps or hurts is application specific.

Enabling the dithering may also increase the phase noise. In most cases where the fractional numerator is zero,

dithering usually degrades performance.

Determining tends to be most beneficial in applications where there is insufficient filtering of the spurs. This often

occurs when the loop bandwidth is very wide or a higher order delta-sigma modulator is used. Dithering tends

not to impact the main fractional spurs much, but has a much larger inpact on the sub-fractional spurs. If it is

decided that dithering will be used, best results will be obtained when the fractional denominator is at least 1000.

DITH Dithering Mode Used

0 Dithering Enabled

1 Reserved

2 Reserved

3 Dithering Disabled

Product Folder Links: LMX2470

LMX2470

SNAS195B –MARCH 2003–REVISED MARCH 2013

www.ti.com

REVISION HISTORY

Changes from Revision A (March 2013) to Revision B Page

• Changed layout of National Data Sheet to TI format .......................................................................................................... 33

Product Folder Links: LMX2470

PACKAGE OPTION ADDENDUM

www.ti.com 11-Apr-2013

Addendum-Page 1

PACKAGING INFORMATION

Orderable Device Status

(1)

Package Type Package

Drawing Pins Package

Qty Eco Plan

(2)

Lead/Ball Finish MSL Peak Temp

(3)

Op Temp (°C) Top-Side Markings

(4)

Samples

LMX2470SLEX ACTIVE ULGA NPF 24 2500 Green (RoHS

& no Sb/Br) NIAU Level-1-260C-UNLIM -40 to 85 X2470

SLE

LMX2470SLEX/NOPB ACTIVE ULGA NPF 24 2500 Green (RoHS

& no Sb/Br) NIAU Level-1-260C-UNLIM -40 to 85 X2470

SLE

(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 - The planned eco-friendly classification: Pb-Free (RoHS), Pb-Free (RoHS Exempt), or Green (RoHS & no Sb/Br) - please check http://www.ti.com/productcontent for the latest availability

information and additional product content details.

TBD: The Pb-Free/Green conversion plan has not been defined.

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.

Pb-Free (RoHS Exempt): This component has a RoHS exemption for either 1) lead-based flip-chip solder bumps used between the die and package, or 2) lead-based die adhesive used between

the die and leadframe. The component is otherwise considered Pb-Free (RoHS compatible) as defined above.

Green (RoHS & no Sb/Br): TI defines "Green" to mean Pb-Free (RoHS compatible), and free of Bromine (Br) and Antimony (Sb) based flame retardants (Br or Sb do not exceed 0.1% by weight

in homogeneous material)

(3) MSL, Peak Temp. -- The Moisture Sensitivity Level rating according to the JEDEC industry standard classifications, and peak solder temperature.

(4) Multiple Top-Side Markings will be inside parentheses. Only one Top-Side Marking contained in parentheses and separated by a "~" will appear on a device. If a line is indented then it is a

continuation of the previous line and the two combined represent the entire Top-Side Marking for that device.

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. TI has taken and

continues to take reasonable steps to provide representative and accurate information but may not have conducted destructive testing or chemical analysis on incoming materials and chemicals.

TI and TI suppliers consider certain information to be proprietary, and thus CAS numbers and other limited information may not be available for release.

In no event shall TI's liability arising out of such information exceed the total purchase price of the TI part(s) at issue in this document sold by TI to Customer on an annual basis.

TAPE AND REEL INFORMATION

*All dimensions are nominal

Device Package

Type Package

Drawing Pins SPQ Reel

Diameter

(mm)

Reel

Width

W1 (mm)

(mm) B0

(mm) K0

(mm) P1

(mm) W

(mm) Pin1

Quadrant

LMX2470SLEX ULGA NPF 24 2500 330.0 12.4 3.8 4.8 1.3 8.0 12.0 Q1

LMX2470SLEX/NOPB ULGA NPF 24 2500 330.0 12.4 3.8 4.8 1.3 8.0 12.0 Q1

PACKAGE MATERIALS INFORMATION

www.ti.com 26-Mar-2013

Pack Materials-Page 1

*All dimensions are nominal

Device Package Type Package Drawing Pins SPQ Length (mm) Width (mm) Height (mm)

LMX2470SLEX ULGA NPF 24 2500 367.0 367.0 35.0

LMX2470SLEX/NOPB ULGA NPF 24 2500 367.0 367.0 35.0

PACKAGE MATERIALS INFORMATION

www.ti.com 26-Mar-2013

Pack Materials-Page 2

MECHANICAL DATA

NPF0024A

www.ti.com

IMPORTANT NOTICE

Texas Instruments Incorporated and its subsidiaries (TI) reserve the right to make corrections, enhancements, improvements and other

changes to its semiconductor products and services per JESD46, latest issue, and to discontinue any product or service per JESD48, latest

issue. Buyers should obtain the latest relevant information before placing orders and should verify that such information is current and

complete. All semiconductor products (also referred to herein as “components”) are sold subject to TI’s terms and conditions of sale

supplied at the time of order acknowledgment.

TI warrants performance of its components to the specifications applicable at the time of sale, in accordance with the warranty in TI’s terms

and conditions of sale of semiconductor products. Testing and other quality control techniques are used to the extent TI deems necessary

to support this warranty. Except where mandated by applicable law, testing of all parameters of each component is not necessarily

performed.

TI assumes no liability for applications assistance or the design of Buyers’ products. Buyers are responsible for their products and

applications using TI components. To minimize the risks associated with Buyers’ products and applications, Buyers should provide

adequate design and operating safeguards.

TI does not warrant or represent that any license, either express or implied, is granted under any patent right, copyright, mask work right, or

other intellectual property right relating to any combination, machine, or process in which TI components or services are used. Information

published by TI regarding third-party products or services does not constitute a license 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 significant portions 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. TI is not responsible or liable for such altered

documentation. Information of third parties may be subject to additional restrictions.

Resale of TI components or services with statements different from or beyond the parameters stated by TI for that component or service

voids all express and any implied warranties for the associated TI component or service and is an unfair and deceptive business practice.

TI is not responsible or liable for any such statements.

Buyer acknowledges and agrees that it is solely responsible for compliance with all legal, regulatory and safety-related requirements

concerning its products, and any use of TI components in its applications, notwithstanding any applications-related information or support

that may be provided by TI. Buyer represents and agrees that it has all the necessary expertise to create and implement safeguards which

anticipate dangerous consequences of failures, monitor failures and their consequences, lessen the likelihood of failures that might cause

harm and take appropriate remedial actions. Buyer will fully indemnify TI and its representatives against any damages arising out of the use

of any TI components in safety-critical applications.

In some cases, TI components may be promoted specifically to facilitate safety-related applications. With such components, TI’s goal is to

help enable customers to design and create their own end-product solutions that meet applicable functional safety standards and

requirements. Nonetheless, such components are subject to these terms.

No TI components are authorized for use in FDA Class III (or similar life-critical medical equipment) unless authorized officers of the parties

have executed a special agreement specifically governing such use.

Only those TI components which TI has specifically designated as military grade or “enhanced plastic” are designed and intended for use in

military/aerospace applications or environments. Buyer acknowledges and agrees that any military or aerospace use of TI components

which have not been so designated is solely at the Buyer's risk, and that Buyer is solely responsible for compliance with all legal and

regulatory requirements in connection with such use.

TI has specifically designated certain components as meeting ISO/TS16949 requirements, mainly for automotive use. In any case of use of

non-designated products, TI will not be responsible for any failure to meet ISO/TS16949.

Products Applications

Audio www.ti.com/audio Automotive and Transportation www.ti.com/automotive

Amplifiers amplifier.ti.com Communications and Telecom www.ti.com/communications

Data Converters dataconverter.ti.com Computers and Peripherals www.ti.com/computers

DLP® Products www.dlp.com Consumer Electronics www.ti.com/consumer-apps

DSP dsp.ti.com Energy and Lighting www.ti.com/energy

Clocks and Timers www.ti.com/clocks Industrial www.ti.com/industrial

Interface interface.ti.com Medical www.ti.com/medical

Logic logic.ti.com Security www.ti.com/security

Power Mgmt power.ti.com Space, Avionics and Defense www.ti.com/space-avionics-defense

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

RFID www.ti-rfid.com

OMAP Applications Processors www.ti.com/omap TI E2E Community e2e.ti.com

Wireless Connectivity www.ti.com/wirelessconnectivity

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

Mouser Electronics

Authorized Distributor

Click to View Pricing, Inventory, Delivery & Lifecycle Information:

Texas Instruments:

LMX2470EVAL LMX2470SLEX LMX2470SLEX/NOPB