MAX2741USBDONGLE+ - Maxim Integrated Products, Inc.

General Description

The MAX2741 L1-band GPS receiver IC offers a high-

performance, compact solution for mobile handsets,

PDAs, and automotive applications. Total voltage gain

of 80dB and a 4.7dB cascaded noise figure can pro-

vide receiver sensitivity for applications requiring

-185dBW for indoor tracking solutions.

This dual-conversion receiver downconverts the

1575.42MHz GPS signal to a 37.38MHz first IF, and then

a 3.78MHz second IF. An integrated 2- or 3-bit ADC (1-

bit SIGN, 1- or 2-bit MAG selectable) samples the sec-

ond IF and outputs the digitized signals to the baseband

processor.

The integrated synthesizer offers the flexibility in fre-

quency planning to allow a single board design to be

employed for reference frequencies from 2MHz to

26MHz. The integrated reference oscillator allows either

TCXO or crystal operation.

The receiver runs from a 2.7V to 3.0V supply, and draws

only 30mA when active. It is offered in a 28-pin thin QFN

package, and is specified for -40°C to +85°C at 3V.

Applications

In-Vehicle Navigation Systems (IVNS)

Telematics (Vehicle and Asset Tracking,

Inventory Management)

Automotive Security

Emergency Response Systems

Emergency Road-Side Assistance

Location-Based Services/Internet (PDAs)

Digital Cameras/Camcorders

Recreational Handhelds/Walkie-Talkies

Geographical Information Systems (GIS)

Consumer Electronics (Location-Based Games)

Precision Timing

Features

♦Supports All Popular Handset Reference

Frequencies Up to 26MHz

♦4.7dB Cascaded Noise Figure

♦80dB Cascaded Gain

♦Tolerates -90dBm In-Band Jammer

♦Tolerates +13dBm CDMA Out-of-Band Jammer at

Device Input

♦Integrated Synthesizer and VCO

♦Integrated 2- or 3-Bit ADC

♦50dB IF AGC Range

♦Small 28-Pin Thin QFN Package

♦SPI™ Control Interface

♦Clock Output for Baseband Processor

MAX2741

Integrated L1-Band GPS Receiver

________________________________________________________________ Maxim Integrated Products 1

28 27 26 25 24 23 22

VCC6

IFOUT+

IFOUT-

IFIN+

IFIN-

N.C.

891011 12 13 14

FILT

SCLK

SDI

SHDN

XTAL

REFCLK

GPSCLK

GPSIF2

GPSIF1

GPSIF0

VCC5

N.C.

SDO

GND

VCC4

VCC3VCO

3225.6MHz

VCC2

RFIN

N.C.

VCC1Σ

LNA

1612.8MHz

33.6MHz

16.8MHz

200kHz

90 0 /96

/192

/16128

P.D.

REF

OSC

ADC

SPI INTERFACE

MAX2741

MUX

Pin Configuration/

Functional Diagram

Ordering Information

19-3559; Rev 0; 1/05

For pricing, delivery, and ordering information, please contact Maxim/Dallas Direct! at

1-888-629-4642, or visit Maxim’s website at www.maxim-ic.com.

SPI is a trademark of Motorola, Inc.

PART TEMP RANGE PIN-PACKAGE

MAX2741ETI -40°C to +85°C 28 Thin QFN

EVALUATION KIT

AVAILABLE

MAX2741

Integrated L1-Band GPS Receiver

2_______________________________________________________________________________________

ABSOLUTE MAXIMUM RATINGS

DC ELECTRICAL CHARACTERISTICS

(Operating conditions (unless otherwise specified): VCC = 2.7V to 3.0V; REFCLK driven with 10MHz sinusoid, 1.2VP-P; registers set

according to mode; no RF input signal; digital baseband outputs left open; TA= -40°C to +85°C. Typical values are measured at VCC =

2.75V, TA= +25°C.)

Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional

operation of the device at these or any other conditions beyond those indicated in the operational sections of the specifications is not implied. Exposure to

absolute maximum rating conditions for extended periods may affect device reliability.

VCC Pins to GND ...................................................-0.3V to +3.3V

VCC Pins to Each Other.........................................-0.3V to +0.3V

FILT to GND................................................-0.3V to (VCC + 0.3V)

CMOS Inputs to GND (SHDN, SCLK,

CS, SDI).................................................+0.3V to (VCC + 0.3V)

CMOS Outputs to GND (CLKOUT,

GPSIF_, SDO).........................................-0.3V to (VCC + 0.3V)

RFIN to GND...............................................-0.3V to (VCC + 0.3V)

First IF Filter I/O to GND (IFOUT±, IFIN±).....-0.3V to (VCC + 0.3V)

Crystal Inputs to GND (XTAL, REFCLK).....-0.3V to (VCC + 0.3V)

Maximum RF Input Power...................................................0dBm

Continuous Power Dissipation (TA= +85°C)

28-Pin Thin QFN (derate 20.8mW/°C above +70°C) .1000mW

Operating Temperature Range ...........................-40°C to +85°C

Junction Temperature......................................................+150°C

Storage Temperature Range .............................-65°C to +160°C

Lead Temperature (soldering, 10s) .................................+300°C

PARAMETER CONDITIONS

MIN

TYP

MAX

UNITS

Supply Voltage 2.7 3.0 V

Normal operation (TA = +25°C) 30 42

Supply Current Standby (V SHDN = VIL, SYNTH:D8 = 0) 0.7 mA

Input-Logic High Threshold VCC -

0.1 V

Input-Logic Low Threshold 0.1 V

Input-Logic High/Low Current -10

+10

µA

Output-Logic High ILOAD = 100µA VCC -

0.3 V

Output-Logic Low ILOAD = 100µA 0.3 V

AC ELECTRICAL CHARACTERISTICS

(Operating conditions (unless otherwise specified): VCC = 2.7V to 3.0V for TA= -40°C to +85°C; REFCLK driven at 10MHz sinusoid,

1.2VP-P; registers set according to mode; using the Typical Application Circuit; CW RF signal at 1575.42MHz. Typical values are mea-

sured at VCC = 2.75V, TA= +25°C.)

PARAMETER CONDITIONS

MIN

TYP

MAX

UNITS

1st CONVERSION STAGE (RF TO 1st IF)

RF Frequency L1-band

1575.42

MHz

RF Conversion Gain (Note 1) 15 21 32 dB

Noise Figure Mid-gain (CONFIG1:D4–D0 = 10000) 4.7 dB

Input IP3 (Note 2) -30

dBm

RF Image Rejection (Notes 3, 4) 20 35 dB

LO Leakage at RF LO to RFIN pin -90

dBm

CAUTION! ESD SENSITIVE DEVICE

MAX2741

Integrated L1-Band GPS Receiver

_______________________________________________________________________________________ 3

AC ELECTRICAL CHARACTERISTICS (continued)

(Operating conditions (unless otherwise specified): VCC = 2.7V to 3.0V for TA= -40°C to +85°C; REFCLK driven at 10MHz sinusoid,

1.2VP-P; registers set according to mode; using the Typical Application Circuit; CW RF signal at 1575.42MHz. Typical values are mea-

sured at VCC = 2.75V, TA= +25°C.)

PARAMETER CONDITIONS

MIN TYP MAX

UNITS

2nd CONVERSION STAGE (1st IF TO ADC INPUT)

1st IF Frequency At IFOUT

37.38

MHz

Max gain (CONFIG1:D4–D0 = 11111) (Note 1) 48 61 74 dB

Conversion Gain Min gain (CONFIG1:D4–D0 = 00000) (Note 1) 10 dB

Input IP3 1st conversion (Note 5) -36

dBm

Noise Figure Max gain (CONFIG1:D4–D0 = 11111) 12 dB

Real

0.40

IF Output Port Admittance Imaginary 1.5 pF

Real

0.40

IF Input Port Admittance Imaginary

0.15

(SYNTH:D13–D10 = 1111) 2.9

LPF -3dB Corner Frequency (SYNTH:D13–D10 = 0000) 7.7 MHz

SYNTHESIZER

ICP_OH PLL charge-pump source current 75 µA

ICP_OL PLL charge-pump sink current

-100

µA

Closed-Loop Phase Noise At 1kHz offset -55

dBc/Hz

Comparison Spurs At ±200kHz offset -44

dBc/Hz

Reference Oscillator Frequency Sinusoid (Note 1) 2 10 26 MHz

REF Input Voltage Level Sinusoid (Note 1) 0.6 2.2 VP-P

VCO Coarse Tune Range Programmable (CONFIG1:D7 to D5 = 000 to 111)

(Note 1)

240

MHz

DIGITAL I/O

SPI Clock Frequency 1MHz

Note 1: Production tested for +25°C and +85°C, guaranteed by design and characterization for -40°C.

Note 2: Test tones at 1575.8MHz and 1576.8MHz at -60dBm/tone.

Note 3: Guaranteed by design and characterization.

Note 4: Image frequency is 1575.42MHz + 2(fIF) = 1650.18MHz

Note 5: Test tones at 37.38MHz and 36.88MHz at -50dBm/tone.

MAX2741

Integrated L1-Band GPS Receiver

4_______________________________________________________________________________________

Pin Description

PIN NAME FUNCTION

CC1LNA Supply Connection. External RF bypass capacitor to ground required.

2, 20, 22, 23

N.C. Reserved. Make no connections to this pin.

3RFIN LNA Input. Connect to GPS antenna through a bandpass filter. This input requires an external

matching network to match to 50Ω. AC-couple to this pin.

CC2VCO Supply Connection. External RF bypass capacitor to ground required.

CC3CML Supply Connection. External RF bypass capacitor to ground required.

CC4Digital Logic and PLL Supply Connection. External RF bypass capacitor to digital ground required.

7GND Ground. Connect to PC board digital ground plane.

8FILT PLL Loop Filter Connection. This is the output of the phase detector’s charge pump. Use the

recommended filter on EV kit for optimal phase noise and lock time.

9SCLK SPI Clock Input (CMOS)

10 CS SPI Chip-Select Input (CMOS, Active Low)

11 SDI SPI Data Input (CMOS)

12 SHDN Full IC Power-Down. This shutdown pin disables the on-chip oscillator and the rest of the IC. To keep

the oscillator running, use the software shutdown (SYNTH:D8); (CMOS, active high).

13 XTAL Crystal Oscillator Feedback Capacitor Connection

14 REFCLK Reference Clock Input for PLL. Drive with 1.2VP-P when using TCXO module.

15 GPSCLK

GPS Clock Output to Baseband. This is the clock used by the ADC to sample the GPS data (CMOS).

16 GPSIF2 Sampled IF Output, Bit 2 (CMOS). See Table 5.

17 GPSIF1 Sampled IF Output, Bit 1 (CMOS). See Table 5.

18 GPSIF0 Sampled IF Output, Bit 0 (CMOS). See Table 5.

19 VCC5IF Supply Connection. External RF bypass capacitor to ground required.

21 SDO SPI Data Output (CMOS)

24 IFIN-

1st IF Input (Inverting). Connect this 2.5kΩ differentially terminated input to the 1st IF filter’s (-) output.

25 IFIN+ 1st IF Input (Noninverting). Connect this 2.5kΩ differentially terminated input to the 1st IF filter’s (+)

output.

26 IFOUT- 1st IF Output (Inverting). Connect this 2.4kΩ differential output to the 1st IF filter’s (-) input.

27 IFOUT+ 1st IF Output (Noninverting). Connect this 2.4kΩ differential output to the 1st IF filter’s (+) input.

28 VCC6RF Image-Reject Mixer Supply. External RF bypass capacitor to ground required.

Exposed GND

RF Ground. Ultra-low inductance connection to ground. Place several vias to PC board ground plane.

MAX2741

Integrated L1-Band GPS Receiver

_______________________________________________________________________________________ 5

Detailed Description

The MAX2741 GPS offers a high-performance super-

heterodyne receiver solution for low-power mobile

devices, with the benefit of using the system’s existing

clock reference. This receiver is ideal for integration into

mobile phone handsets using common reference fre-

quencies such as 10.0, 13.0, 14.4, 19.2, 20.0, and

26.0MHz. The only external components required are the

GPS RF filter, an IF filter (typically designed from inexpen-

sive discretes), a three-component PLL loop filter, and a

few other resistors and capacitors. The MAX2741 inte-

grates the reference oscillator core, the VCO and its tank,

the synthesizer, a 1- to 3-bit ADC, and all signal path

blocks except for the 1st IF filter. The typical application

area for the receiver is less than 2cm2.

RF/1st Conversion Stage (Front-End)

The MAX2741 RF front-end LNA and mixer are the most

important in the signal path. This stage sets the noise

figure for the receiver, defining the sensitivity, and mixes

the 1575.42MHz L1-band GPS signal down to a 1st IF of

37.38MHz. The LNA itself has an NF of approximately

1.5dB; the cascaded NF of the front-end (including the

mixer) is approximately 4.7dB, and the cascaded gain

is typically 21dB.

The image-reject mixer is set up for a high-side injected

RFLO (1612.80MHz), and offers typically better than 30dB

rejection of the image noise (1650.18MHz). The -30dBm

input 3rd-order intercept (IIP3) of the RF strip, in conjunc-

tion with the GPS IF filter, provides excellent out-of-band

interferer immunity.

The 1st IF outputs (IFOUT±) are internally biased to

approximately 2V, and have a differential source

impedance of approximately 2.5kΩ. The IF filter can be

implemented as a discrete L/C filter, or as a monolithic

SAW or ceramic if one is available.

IF/2nd Conversion Stage

The 2nd conversion stage consists of an active mixer, a

variable-gain amplifier (VGA), and a tunable lowpass

filter. The IF mixer is configured for low-side LO injec-

tion for a 2nd IF of 3.78MHz. Total gain in this stage is

62dB, and the VGA offers 51dB of gain adjustment. The

VGA is typically controlled by the baseband IC through

the SPI interface to optimize the signal swing for digiti-

zation by the ADC.

The on-chip lowpass filter has an adjustable cutoff fre-

quency, programmable from 2.9MHz to 7.7MHz in 16

steps. This LPF further reduces out-of-band noise and

band-limits the signal to the ADC, ensuring that the

sampling process does not generate alias components.

DC offset compensation at the ADC input is performed by

an on-chip 4-bit DAC. This compensates for any DC error

introduced by transistor mismatch in the differential stage

driving the ADC input, allowing the downconverted GPS

signal’s DC level to be centered within the threshold volt-

ages of the ADC.

ADC

The on-chip ADC samples the down-converted GPS

signal at the 2nd IF (3.78MHz). Sampled output is pro-

vided in either 2-bit (1-bit magnitude, 1-bit sign) or 3-bit

(2-bit magnitude, 1-bit sign) formats, as determined by

the ADC mode configuration bit (CONFIG1:D15); see

Table 5 for details. The ADC sample clock (system GPS

clock) is derived either directly from the reference clock

(SYNTH:D9 = 1), or from an RFLO divide-by-96 block to

provide a 16.8MHz sample clock (SYNTH:D9 = 0). The

clock is available to the baseband processor at

GPSCLK (pin 15). The sampled ADC data bits are

available on pins 16, 17, and 18 (GPSIF2, GPSIF1, and

GPSIF0). The functionality of the pins is different in

each mode (2-bit vs. 3-bit)—see Table 5 in determining

the interface connection for the application circuit.

Synthesizer

The MAX2741 integrates an integer-N synthesizer; all

blocks except the loop filter are on-chip. The reference

can be either a crystal (driven by the internal oscillator),

or a TCXO module. The oscillator provides a 5pF load

to the crystal. A TCXO module should provide a swing

in the 0.6VP-P to 2.2VP-P range.

The reference divider (/R) is programmable (SYNTH:

D7–D0), and can accommodate reference frequencies

up to 26MHz. The reference divider needs to be set so

the comparison frequency (fCOMP) at the frequency/

phase detector is 200kHz. The VCO runs at twice the fre-

quency of the RFLO; the RFLO is therefore generated

from the VCO using a quadrature divide-by-2 block. The

RF LO is fCOMP x 8064 (typically 1612.80MHz), and the

1st IF LO is fCOMP x 168 (typically 33.6MHz); the RF and

IF LO division ratios are not adjustable. This configuration

allows for the use of reference frequencies common to

GSM, CDMA, TDMA, TD-SCDMA, and UMTS handsets:

9.6MHz (R = 48), 13.0MHz (R = 65), 14.4MHz (R = 72),

19.2MHz (R = 96), 26.0MHz (R = 130), etc.

MAX2741

Integrated L1-Band GPS Receiver

6_______________________________________________________________________________________

The VCO offers a bank of tuning capacitors that can be

latched in/out to adjust the center frequency. Because

the system does not require any RF LO frequency

change (i.e., changing channels), the VCO varactor tun-

ing gain is very low by design, which means the tuning

range of the VCO is narrow. The coarse-tune capacitors

in the tank circuit allow the system to adjust the VCO

center frequency as needed to guarantee that the syn-

thesizer can lock. In practice, process and temperature

effects on VCO centering are negligible, and a coarse-

tune setting of 110 (CONFIG:D7 to D5) will center the

VCO tuning range correctly in virtually all cases. To aid in

bench and prototype testing, the PFD offers out-of-lock-

high and out-of-lock-low indicators, available in the SPI

STATUS register (STATUS:D9 to D8). Use these flags to

determine if the VCO tuning range needs to be adjusted

higher or lower in the case where the PLL cannot lock.

The PLL filter is the only external block of the synthesizer.

The typical filter is a classic C-R-C two-pole shunt network

on the tune line. Low phase noise is preferred at the

expense of longer PLL settling times, so a low 10kHz to

20kHz loop bandwidth is used. The recommended PLL

10kHz filter implementation, with charge pump set to

200µA (CONFIG1:D10 = 1), is shown in Figure 1.

The system/GPS clock is derived either directly from

the reference oscillator, or synthesized from the RFLO

(see the ADC section). This clock is used as the sam-

pling clock for the on-chip ADC, and is seen at pin 15,

GPSCLK.

SPI Bus, Address and Bit Assignments

An SPI-compatible serial interface is used to program the

MAX2741 for configuring the different operating modes.

In addition, data can be read out of the MAX2741 for sta-

tus and diagnostic use. The serial interface is controlled

by four signals: SCLK (serial clock), CS (chip-select), SDI

(data input), and SDO (data output).

The control of the PLL, AGC, test, offset management,

and block selection is performed through the SPI bus

from the baseband controller. A 20-bit word, with the MSB

(D15) being sent first, is clocked into a serial shift register

when the chip-select signal is asserted low.

The SPI bus has four control lines: serial clock (SCLK),

chip-select (CS), data in (SDI), and data out (SDO).

Enable SDO functionality by setting the digital test bus

bits: CONFIG1:D9 to D8 = 01. The timing of the inter-

face signals is shown in Figure 2 and Table 1 along

with typical values for setup and hold time require-

ments.

For best performance, the SPI bus should be configured

during the startup initialization and then left with the opti-

mum values in the registers. Any changes to the ADC

and VGA bits during GPS signal processing may cause

glitches and corrupt the analog signal path. Reading

from the SPI bus does not interrupt GPS operation.

VCC4

GND

FILT

SCLK

MAX2741

22nF

36kΩ

100pF

Figure 1. Recommended 3rd-Order PLL Filter

LSB MSB

SCLK

SDI

tSETUPD

tHDATA tPERIOD

tEND

tSETUPSS

Figure 2. SPI Timing Diagram

Table 1. SPI Timing Requirements

SYMBOL

PARAMETER TYP

VALUE

UNITS

tSETUPD Data to SCLK setup 20 ns

tPERIOD SCLK period 100 ns

tHDATA Data hold to SCLK 20 ns

tSETUPSS CS to SCLK disable 20 ns

tEND

Falling SCLK to CS inactive

20 ns

MAX2741

Integrated L1-Band GPS Receiver

_______________________________________________________________________________________ 7

Table 2. Register Address and Data Bit Assigments (Write)

DATA ADDRESS

NAME

D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 A3 A2 A1

SYNTH

Reserved

LPF Autotune

Initiate

LPF Tuning

Word (MSB)

LPF Tuning

Word

LPF Tuning

Word

LPF Tuning

Word (LSB)

XTAL Clock

Select

Standby

PLL Ref Div

Ratio (MSB)

PLL Ref Div

Ratio

PLL Ref Div

Ratio

PLL Ref Div

Ratio

PLL Ref Div

Ratio

PLL Ref Div

Ratio

PLL Ref Div

Ratio

PLL Ref Div

Ratio (LSB)

010

CONFIG 1

ADC Mode

ADC Offset Control

(LSB)

ADC Offset Control

(MSB)

ADC Offset Control

(SIGN)

Double Charge-

Pump Current

Digital Test Bus

Mode Select (MSB)

Digital Test Bus

Mode Select (LSB)

VCO Coarse Tuning

Range (MSB)

VCO Coarse Tuning

Range

VCO Coarse Tuning

Range (LSB)

AGC Gain (MSB)

AGC Gain

AGC Gain (LSB)

010

CONFIG 2

Reset CMOS

Drive VCO Low

Drive VCO High

Reserved

Analog Test

Mode Select

Analog Test

Mode Select

Analog Test

Mode Select

Analog Test

Mode Select

Analog Test

Mode Select

011

Table 3. Register Address and Data Bit Assigments (Read)

DATA ADDRESS

NAME

D15 D14 D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 A3 A2 A1

STATUS

Reserved

Out-of-Lock

(High)

Out-of-Lock

(Low)

XTAL Clock

Selected

Parity

Reserved

LPF Auto-

calibrate End

LPF Autotune

(MSB)

LPF Autotune

(LSB)

011

MAX2741

Integrated L1-Band GPS Receiver

8_______________________________________________________________________________________

Detailed Register Definitions

Table 4. Detailed Register Definition for Write Address 0100: SYNTH

DATA BIT

DEFAULT

DESCRIPTION

D15 1 Reserved

D14 1 LPF Autotune Initiate: I = Initiate autotune, 0 = Manual tuning.

D13–D10

0100 LPF Tuning Word: 0000 ~ 7.7MHz, 1111 ~ 2.9MHz.

D9 1 XTAL Clock Select: 1 = External reference, 0 = Synthesized 16.8MHz.

D8 0 Standby: 0 = Normal operating mode, 1 = Standby (oscillator remains active), but only if D9 = 1.

D7–D0

01100000

Reference Division Ratio. Default 19.2MHz external reference (R = 96dec). R = fREF / 200kHz.

Table 5. Detailed Register Definition for Write Address 0101: CONFIG 1

DATA BIT

DEFAULT

DESCRIPTION

D15 1

ADC Mode. Select 1 for 1-bit magnitude and sign, select 0 for 2-bit magnitude and sign.

1: GPSIF2 = sign, GPSIF1 = magnitude, GPSIF0 = X

0: GPSIF2 = MSB magnitude, GPSIF1 = LSB magnitude, GPSIF0 = sign

D14–D11

0000 ADC Offset Control (approx 4mV/step): D14 = LSB, D12 = MSB, D11 = sign.

D10 0 Double Charge-Pump Current: 0 = 100µA, 1 = 200µA.

D9 to D8

00 Digital Test Bus Mode Select. See Table 9 for test-mode descriptions.

D7 to D5

001 VCO Coarse Tuning Range. 000 = Lowest frequency, 111 = Highest frequency.

D4–D0 11111 AGC Gain. Digital control of the AGC amplifier in the 2nd IF section. 00000 => min gain, 11111 =>

max gain (linear gain ~2.5dB per unit SPI word).

Table 6. Detailed Register Definition for Write Address 0110: CONFIG 2

DATA BIT

DEFAULT

DESCRIPTION

D15 1 Reset CMOS: 0 = Hold CMOS dividers in reset and PFD is tri-stated, 1 = Inactive.

D14 1 Drive VCO Low: 0 = Active, forces VCO to lowest frequency.

N.B. do not activate both D14 and D13 at the same time.

D13 1 Drive VCO High: <forces LCP low FET on, driving VTUNE low, forcing VCO to highest extreme> 0 =

Active, forces VCO to highest frequency. N.B. do not activate both D14 and D13 at the same time.

D12–D7 100000 Reserved

D6 to D5

11 Must be programmed to 11

D4–D0 11111 Analog Test Mode Select: Reserved

MAX2741

Integrated L1-Band GPS Receiver

_______________________________________________________________________________________ 9

Applications Information

Fundamentally, the only application areas that require

careful consideration are the LNA input match and the

1st IF filter. Of course, proper supply bypassing,

grounding, and layout is required for reliable perfor-

mance from any RF circuit.

LNA Input Matching

Input matching is critical for optimum noise figure and

system sensitivity. Optimum source impedance (as seen

from the LNA input) for lowest noise figure is 29Ω+ j47Ω.

Remember that optimum noise match and optimum gain

match (return loss) do not occur simultaneously, so a

good application circuit will sacrifice gain slightly in favor

of reduced noise figure. Gain and noise circles are pro-

vided in Figure 3; S11 tabular data is provided in Table 8.

1st IF Interface and Filtering

The typical application uses a 37.38MHz 1st IF, and

employs an IF filter. The order of the filter should be tai-

lored to suit the application—stand-alone GPS

receivers will not require the channel-selection and

stopband attenuation of GPS receivers that are inte-

grated into other wireless handsets. Be sure that the fil-

ter topology provides DC-blocking for the IF I/O ports.

Table 7. Detailed Register Definition for Read Address 0111: STATUS

DATA BIT

DEFAULT

DESCRIPTION

D15–D10

XXXXXX Reserved

D9 X Out-of-Lock (High Frequency): 1 = PLL is out of lock, VCO free-running at its highest frequency,

0 = Locked.

D8 X Out-of-Lock (Low Frequency): 1 = PLL is out of lock, VCO free-running at its lowest frequency,

0 = Locked high.

D7 1 XTAL Clock Selected: 1 = Synthesized 16.8MHz reference, 0 = External clock.

D6 X Parity: 1 = Even, 0 = Odd.

D5 X Reserved

D4 X LPF Autotune End: 0 = Autotune run ended; 1 = Calibrating or manual tuning.

D3–D0 XXXX LPF Autotune: 0000 ~ 7.7MHz; 1111 = 2.9MHz.

Table 8. MAX2741 S11

G = Gmax - 1dB NF = NFmin + 0.2dB

Figure 3. Gain and Noise Circles for MAX2741 LNA Input

FREQ (MHz) S11 (MAG) S11 (°)

1100 0.874 -50.9

1200 0.867 -56.1

1300 0.859 -61.5

1400 0.842 -66.9

1500 0.821 -72.3

1550 0.809 -74.9

1560 0.806 -75.4

1570 0.804 -75.9

1575 0.803 -76.2

1580 0.801 -76.4

1590 0.799 -77.0

1600 0.796 -77.5

1650 0.783 -80.0

1700 0.768 -82.5

1800 0.739 -87.4

1900 0.708 -92.3

2000 0.677 -96.8

MAX2741

Integrated L1-Band GPS Receiver

10 ______________________________________________________________________________________

28 27 26 25 24 23 22

VCC6

IFOUT+

IFOUT-

IFIN+

IFIN-

N.C.

891011 12 13 14

FILT

SCLK

SDI

SHDN

XTAL

REFCLK

GPSCLK

GPSIF2

GPSIF1

GPSIF0

VCC5

N.C.

SDO

GND

VCC4

VCC3

VCC2

RFIN

N.C.

VCC1

MAX2741

SDO

SD1

SCLK

GPSIF0

GPSIF1

GPSIF2

GPSCLK

REFCLK

BASEBAND IC

I/O CONNECTION RECEIVER RF BPF

RFIN LNA Input RF BPF Output

I/O CONNECTION RECEIVER IF FILTER

IFOUT+ 1st IF Output from Mixer (+) IF BPF Input, 2.5kΩ Differential

IFOUT- 1st IF Output from Mixer (-) IF BPF Input, 2.5kΩ Differential

IFIN+ 1st IF Input (+) IF BPF Input, 2.5kΩ Differential

IFIN- 1st IF Input (-) IF BPF Input, 2.5kΩ Differential

BASEBAND

I/O CONNECTION RECEIVER BB IC/MAC

SCLK CMOS Input CMOS Output

CS CMOS Input CMOS Output

SDI CMOS Input CMOS Output

SDO CMOS Output CMOS Input

SHDN CMOS Input CMOS Output

GPSCLK CMOS Output CMOS Input

GPSIF0 CMOS Output CMOS Input

GPSIF1 CMOS Output CMOS Input

GPSIF2 CMOS Output CMOS Input

SYNTHESIZER

I/O CONNECTION RECEIVER EXTERNAL COMPONENTS

FILT PLL Phase-Detector Charge-Pump PLL Loop Filter

XTAL Crystal Oscillator Feedback Feedback Capacitors

REFCLK External TCXO or Crystal Analog (also connected to REFCLK input to MAC)

Typical Interface Diagram

Interface Summary

All I/O connections are DC-coupled. Supply voltages as specified in the electrical specifications.

MAX2741

Integrated L1-Band GPS Receiver

______________________________________________________________________________________ 11

Digital Test Bus

The digital test bus (DTB) is provided to allow for easy

bench analysis of the digital workings of the receiver.

Typical Application Circuit

VCC6

IFOUT+

IFOUT-

IFIN+

IFIN-

N.C.

FILT

SCLK

SDI

SHDN

XTAL

REFCLK

GPSCLK

GPSIF2

GPSIF1

GPSIF0

VCC5

N.C.

SDO

GND

VCC4

VCC3

VCC2

RFIN

N.C.

VCC1

VCC

GPS RF INPUT

FROM GPS BPF

VCC

2.2pF

100pF 22pF

VCC

1nF100pF

220pF

100nF 100pF

1nF 100pF

6.2nH

SPI DATA OUT

TO BASEBAND PROCESSOR

GPS DATA AND CLOCK

TO BASEBAND PROCESSOR

22nF

36kΩ

100pF

H/W SHUTDOWN LINE

FROM BASEBAND PROCESSOR

SPI CLOCK AND DATA INTO

BASEBAND PROCESSOR SYSTEM TCXO

(2MHz TO 26MHz)

VCC

100pF 22pF

39pF 470µH 470µH 39pF

680pF 5.6pF 680pF

100pF

28 27 26 25 24 23 22

891011 12 13 14

VCO

3225.6MHz

LNA

1612.8MHz

33.6MHz

16.8MHz

200kHz

90 0 /96

/192

/16128

P.D.

REF

OSC

ADC

SPI INTERFACE

MAX2741

MUX

Table 9. Digital Test-Mode-Select Description

DIGITAL OUTPUT FUNCTION

MODE

CONFIG1:D9 to D8

GPSIF2 GPSIF1 GPSIF0

311 SIGN LSB MSB

210M COUNTER R COUNTER HANDSHAKE STATUS

101CHARGE PUMP UP CHARGE PUMP DOWN SDO

000CML CLOCK CALIBRATE LPF END XTL CLOCK SELECTED

MAX2741

Integrated L1-Band GPS Receiver

Maxim cannot assume responsibility for use of any circuitry other than circuitry entirely embodied in a Maxim product. No circuit patent licenses are

implied. Maxim reserves the right to change the circuitry and specifications without notice at any time.

12 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600

QFN THIN.EPS

(ND-1) X e

PIN # 1

I.D.

(NE-1) X e

E/2

0.08 C

0.10 C

A1 A3

DETAIL A

E2/2

0.10 M C A B

PIN # 1 I.D.

0.35x45∞

D/2 D2/2

e e

DETAIL B

XXXXX

MARKING

21-0140

PACKAGE OUTLINE,

16, 20, 28, 32L THIN QFN, 5x5x0.8mm

-DRAWING NOT TO SCALE-

COMMON DIMENSIONS

3.353.15

T2855-1 3.25 3.353.15 3.25

MAX.

3.20

EXPOSED PAD VARIATIONS

3.00T2055-2 3.10

NOM.MIN.

3.203.00 3.10

MIN.

NOM. MAX.

PKG.

CODES

1. DIMENSIONING & TOLERANCING CONFORM TO ASME Y14.5M-1994.

2. ALL DIMENSIONS ARE IN MILLIMETERS. ANGLES ARE IN DEGREES.

3. N IS THE TOTAL NUMBER OF TERMINALS.

4. THE TERMINAL #1 IDENTIFIER AND TERMINAL NUMBERING CONVENTION SHALL

CONFORM TO JESD 95-1 SPP-012. DETAILS OF TERMINAL #1 IDENTIFIER ARE

OPTIONAL, BUT MUST BE LOCATED WITHIN THE ZONE INDICATED. THE TERMINAL #1

IDENTIFIER MAY BE EITHER A MOLD OR MARKED FEATURE.

5. DIMENSION b APPLIES TO METALLIZED TERMINAL AND IS MEASURED BETWEEN 0.25 mm AND 0.30 mm

FROM TERMINAL TIP.

6. ND AND NE REFER TO THE NUMBER OF TERMINALS ON EACH D AND E SIDE RESPECTIVELY.

7. DEPOPULATION IS POSSIBLE IN A SYMMETRICAL FASHION.

8. COPLANARITY APPLIES TO THE EXPOSED HEAT SINK SLUG AS WELL AS THE TERMINALS.

9. DRAWING CONFORMS TO JEDEC MO220, EXCEPT EXPOSED PAD DIMENSION FOR T2855-1,

T2855-3 AND T2855-6.

NOTES:

SYMBOL

PKG.

10. WARPAGE SHALL NOT EXCEED 0.10 mm.

JEDEC

T1655-1 3.203.00 3.10 3.00 3.10 3.20

0.70 0.800.75

4.90

0.25

WHHB

0.350.30

5.10

5.105.00

0.80 BSC.

5.00

0.05

0.20 REF.

0.02

MIN. MAX.NOM.

16L 5x5

3.10

T3255-2 3.00 3.20 3.00 3.10 3.20

2.70

T2855-2 2.60 2.602.80 2.70 2.80

L0.30 0.500.40

------

WHHC

5.00

0.30

0.55

0.65 BSC.

0.45

0.25

4.90

0.25

0.65

5.10

0.35

20L 5x5

0.20 REF.

0.75

0.02

NOM.

0.70

MIN.

0.05

0.80

MAX.

---

WHHD-1

5.00

0.25

0.55

0.50 BSC.

0.45

0.25

4.90

0.20

0.65

5.10

0.30

28L 5x5

0.20 REF.

0.75

0.02

NOM.

0.70

MIN.

0.05

0.80

MAX.

---

WHHD-2

5.00

0.40

0.50 BSC.

0.30

0.25

4.90

0.50

5.10

32L 5x5

0.20 REF.

0.75

0.02

NOM.

0.70

MIN.

0.05

0.80

MAX.

0.20 0.25 0.30

DOWN

BONDS

ALLOWED

YES3.103.00 3.203.103.00 3.20T2055-3

3.103.00 3.203.103.00 3.20T2055-4

T2855-3 3.15 3.25 3.35 3.15 3.25 3.35

T2855-6 3.15 3.25 3.35 3.15 3.25 3.35

T2855-4 2.60 2.70 2.80 2.60 2.70 2.80

T2855-5 2.60 2.70 2.80 2.60 2.70 2.80

T2855-7 2.60 2.70 2.80 2.60 2.70 2.80

3.203.00 3.10T3255-3 3.203.00 3.10

3.203.00 3.10T3255-4 3.203.00 3.10

YES

3.203.00T1655-2 3.10 3.00 3.10 3.20 YES

NO3.203.103.003.10T1655N-1 3.00 3.20

3.353.15T2055-5 3.25 3.15 3.25 3.35 Y

3.35

3.15T2855N-1 3.25 3.15 3.25 3.35 N

3.35

3.15T2855-8 3.25 3.15 3.25 3.35 Y

3.203.10T3255N-1 3.00 NO

3.203.103.00

0.40

SEE COMMON DIMENSIONS TABLE

±0.15

11. MARKING IS FOR PACKAGE ORIENTATION REFERENCE ONLY.

21-0140

PACKAGE OUTLINE,

16, 20, 28, 32L THIN QFN, 5x5x0.8mm

-DRAWING NOT TO SCALE-

12. NUMBER OF LEADS SHOWN ARE FOR REFERENCE ONLY.

Package Information

(The package drawing(s) in this data sheet may not reflect the most current specifications. For the latest package outline information,

go to www.maxim-ic.com/packages.)