General Description
The MAX2831/MAX2832 direct conversion, zero-IF, RF
transceivers are designed specifically for 2.4GHz to
2.5GHz 802.11g/b WLAN applications. The MAX2831
completely integrates all circuitry required to implement
the RF transceiver function, providing an RF power
amplifier (PA), RF-to-baseband receive path, baseband-
to-RF transmit path, VCO, frequency synthesizer, crystal
oscillator, and baseband/control interface. The MAX2832
integrates the same functional blocks except for the PA.
Both devices include a fast-settling sigma-delta RF syn-
thesizer with smaller than 20Hz frequency steps and a
digitally tuned crystal oscillator allowing use of a low-cost
crystal. The devices also integrate on-chip DC-offset
cancellation and I/Q errors and carrier leakage-detection
circuits. Only an RF bandpass filter (BPF), crystal, RF
switch, and a small number of passive components are
needed to form a complete 802.11g/b WLAN RF front-
end solution.
The MAX2831/MAX2832 completely eliminate the need
for an external SAW filter by implementing on-chip mono-
lithic filters for both the receiver and transmitter. The
baseband filters are optimized to meet the IEEE 802.11g
standard and proprietary turbo modes up to 40MHz
channel bandwidth. These devices are suitable for the full
range of 802.11g OFDM data rates (6Mbps to 54Mbps)
and 802.11b QPSK and CCK data rates (1Mbps to
11Mbps). The ICs are available in a small, 48-pin TQFN
package measuring only 7mm x 7mm x 0.8mm.
Applications
Wi-Fi, PDA, VOIP, and Cellular Handsets
Wireless Speakers and Headphones
General 2.4GHz ISM Radios
Features
2.4GHz to 2.5GHz ISM Band Operation
IEEE 802.11g/b Compatible (54Mbps OFDM and
11Mbps CCK)
Complete RF Transceiver, PA, and Crystal
Oscillator (MAX2831)
Best-in-Class Transceiver Performance
62mA Receiver Current
2.6dB Rx Noise Figure
-76dBm Rx Sensitivity (54Mbps OFDM)
No I/Q Calibration Required
0.1dB/0.35° Rx I/Q Gain/Phase Imbalance
33dB RF and 62dB Baseband Gain Control
Range
60dB Range Analog RSSI per RF Gain Setting
Fast Rx I/Q DC-Offset Settling
Programmable Baseband Lowpass Filter
20-Bit Sigma-Delta Fractional-N PLL with
< 20Hz Step Size
Digitally Tuned Crystal Oscillator
+18.5dBm Transmit Power (5.6% EVM with
54Mbps OFDM)
31dB Tx Gain Control Range
Integrated Power Detector (MAX2831)
Serial or Parallel Gain-Control Interface
> 40dB Tx Sideband Suppression without
Calibration
Tx/Rx I/Q Error Detection
Transceiver Operates from +2.7V to +3.6V
PA Operates from +2.7V to +4.2V (MAX2831)
Low-Power Shutdown Mode
Small 48-Pin TQFN Package
(7mm x 7mm x 0.8mm)
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
________________________________________________________________ Maxim Integrated Products 1
Ordering Information
19-0363; Rev 2; 3/11
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.
Pin Configuration appears at end of data sheet.
EVALUATION KIT
AVAILABLE
PART TEMP RANGE PIN-PACKAGE
M A X2 8 3 1 E TM + T- 40°C to + 85°C 48 TQFN- EP*
M A X2 8 3 2 E TM + T- 40°C to + 85°C 48 TQFN- EP*
*EP = Exposed pad.
+Denotes a lead(Pb)-free/RoHS-compliant package.
T = Tape and reel.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
2 _______________________________________________________________________________________
ABSOLUTE MAXIMUM RATINGS
DC ELECTRICAL CHARACTERISTICS
(MAX2831 EV kit: VCC_ = 2.7V to 3.6V, VCCPA = VCCTXPA = 2.7V to 4.2V, TA= -40°C to +85°C, Rx set to the maximum gain. CS =
high, RXHP = SCLK = DIN = low, RSSI and clock output buffer are off, no signal at RF inputs, all RF inputs and outputs terminated
into 50, receiver baseband outputs are open. 100mVRMS differential I and Q signals (54Mbps IEEE 802.11g OFDM) applied to I/Q
baseband inputs of transmitter in transmit mode, fREF = 40MHz, and registers set to recommended settings and corresponding test
mode, unless otherwise noted. Typical values are at VCC = 2.8V, VCCPA = 3.3V, and TA= +25°C, LO frequency = 2.437GHz, unless
otherwise noted. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB, balun,
and SMA connectors.) (Note 1)
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are stress ratings only, and functional
operation of the device at these 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.
VCCTXPA, VCCPA and TXRF_ to GND ....................-0.3V to +4.5V
VCCLNA, VCCTXMX, VCCPLL, VCCCP, VCCXTAL, VCCVCO,
VCCRXVGA, VCCRXFL, and VCCRXMX_ to GND....-0.3V to +3.9V
B6, B7, B3, B2, SHDN, B5, CS, SCLK, DIN, B1, TUNE, B4,
TXBBI_, TXBBQ_, RXHP, RXTX, RXBBI_, RXBBQ_, RSSI,
BYPASS, CPOUT, LD, CLOCKOUT, XTAL, CTUNE, RXRF_ to
GND .......................................-0.3V to (Operating VCC + 0.3V)
RXBBI_, RXBBQ_, RSSI, BYPASS, CPOUT, LD, CLOCKOUT
Short-Circuit Duration ..........................................................10s
RF Input Power ...............................................................+10dBm
Continuous Power Dissipation (TA= +70°C)
48-Pin TQFN (derates 27.8mW/°C above +70°C) ..........2.22W
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
Soldering Temperature (reflow) .......................................+260°C
CAUTION! ESD SENSITIVE DEVICE
PARAMETERS CONDITIONS MIN TYP MAX UNITS
VCC_ 2.7 3.6
Supply Voltage VCCPA, VCCTXPA 2.7 4.2 V
S hutd own m od e,
B7: B1 = 0000000,
r efer ence osci ll ator not
ap pl i ed
TA = +25°C 20 µA
TA = +25°C 28 35
Standby mode TA = -40°C to +85°C 35
TA = +25°C 62 78
Rx mode TA = -40°C to +85°C 82
MAX2831, transmit section 82 104
M AX 2831, P A, P
OU T = + 18.2d Bm 209 258
Tx mode, TA = +25°C,
VCC = 2.8V, VCCPA =
3.3V, (Note 2) MAX2832 86
Rx calibration mode TA = +25°C 101
Supply Current
Tx calibration mode TA = +25°C 78
mA
Rx I/Q Output Common-Mode
Voltage TA = +25°C at default common-mode setting 0.98 1.2 1.33 V
TA = -40°C (relative to TA = +25°C) -17
Rx I/Q Output Common-Mode
Voltage Variation TA = +85°C (relative to TA = +25°C) 15 mV
Tx Baseband Input Common-
Mode Voltage Operating Range DC-coupled 0.9 1.3 V
Tx Baseband Input Bias Current Source current 22 µA
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
_______________________________________________________________________________________ 3
DC ELECTRICAL CHARACTERISTICS (continued)
(MAX2831 EV kit: VCC_ = 2.7V to 3.6V, VCCPA = VCCTXPA = 2.7V to 4.2V, TA= -40°C to +85°C, Rx set to the maximum gain. CS =
high, RXHP = SCLK = DIN = low, RSSI and clock output buffer are off, no signal at RF inputs, all RF inputs and outputs terminated
into 50, receiver baseband outputs are open. 100mVRMS differential I and Q signals (54Mbps IEEE 802.11g OFDM) applied to I/Q
baseband inputs of transmitter in transmit mode, fREF = 40MHz, and registers set to recommended settings and corresponding test
mode, unless otherwise noted. Typical values are at VCC = 2.8V, VCCPA = 3.3V, and TA= +25°C, LO frequency = 2.437GHz, unless
otherwise noted. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB, balun,
and SMA connectors.) (Note 1)
PARAMETERS CONDITIONS MIN TYP MAX UNITS
LOGIC INPUTS: SHDN, RXTX, SCLK, DIN, CS, B7:B1, RXHP
Digital Input-Voltage High, VIH VCC -
0.4 V
Digital Input-Voltage Low, VIL 0.4 V
Digital Input-Current High, IIH -1 +1 µA
Digital Input-Current Low, IIL -1 +1 µA
LOGIC OUTPUTS: LD, CLOCKOUT
Digital Output-Voltage High, VOH Sourcing 100µA VCC -
0.4 V
Digital Output-Voltage Low, VOL Sinking 100µA 0.4 V
AC ELECTRICAL CHARACTERISTICS—Rx Mode
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA=+25°C, fRF = 2.439GHz, fLO = 2.437GHz; receiver baseband I/Q out-
puts at 112 mVRMS (-19dBV), fREF = 40MHz, SHDN = CS = high, RXTX = SCLK = DIN = low, with power matching for the differential
RF pins using the typical applications and registers set to default settings and corresponding test mode, unless otherwise noted.
Unmodulated single-tone RF input signal is used with specifications which normally apply over the entire operating conditions, unless
otherwise indicated. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB,
balun, and SMA connectors.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
RECEIVER SECTION: LNA RF INPUT-TO-BASEBAND I/Q OUTPUTS
RF Input Frequency Range 2.4 2.5 GHz
High RF gain 18
Mid RF gain 11
RF Input Return Loss
Low RF gain 14
dB
TA = +25°C 86 98
Maximum gain, B7:B1 =
1111111 TA = -40°C to +85°C 83
Total Voltage Gain
Minimum gain, B7:B1 =
0000000 TA = +25°C 3 8
dB
From high-gain mode (B7:B6 = 11) to medium-gain
mode (B7:B6 = 10) -16
RF Gain Steps (Note 3) From high-gain mode (B7:B6 = 11) to low-gain mode
(B7:B6 = 0X) -33
dB
RF Gain-Change Settling Time
Gain change from high gain to medium gain, high gain to
low, or medium gain to low gain; gain settling to within
±2dB of steady state; RXHP = 1
0.2 µs
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
4 _______________________________________________________________________________________
AC ELECTRICAL CHARACTERISTICS—Rx Mode (continued)
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA=+25°C, fRF = 2.439GHz, fLO = 2.437GHz; receiver baseband I/Q out-
puts at 112 mVRMS (-19dBV), fREF = 40MHz, SHDN = CS = high, RXTX = SCLK = DIN = low, with power matching for the differential
RF pins using the typical applications and registers set to default settings and corresponding test mode, unless otherwise noted.
Unmodulated single-tone RF input signal is used with specifications which normally apply over the entire operating conditions, unless
otherwise indicated. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB,
balun, and SMA connectors.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
Baseband Gain Range From maximum baseband gain (B5:B1 = 11111) to
minimum baseband gain (B5:B1 = 00000) 55 62 67 dB
Voltage gain = maximum with B7:B6 = 11 2.6
Voltage gain = 50dB with B7:B6 = 11 3.2
Voltage gain = 45dB with B7:B6 = 10 16
DSB Noise Figure
Voltage gain = 15dB with B7:B6 = 0X 34
dB
B7:B6 = 11 -41
B7:B6 = 10 -24
In-Band Compression Point
Based on EVM
-19dBVRMS baseband
output EVM degrades to
9% B7:B6 = 0X -6
dBm
In-Band Output P-1dB Voltage gain = 90dB, with B7:B6 = 11 2.5 VP-P
B7:B6 = 11 -12
B7:B6 = 10 -4
Out-of-Band Input IP3 (Note 4)
B7:B6 = 0X 24
dBm
I/Q Phase Error 1σ variation (without calibration) ±0.35 D eg r ees
I/Q Gain Imbalance 1σ variation (without calibration) ±0.1 dB
Minimum differential resistance 10 k
RX I/Q Output Load Impedance
(R || C) Maximum differential capacitance 10 pF
Tx-to-Rx Conversion Gain for Rx
I/Q Calibration For receiver gain, B7:B1 = 1101111 (Note 5) 0.5 dB
Baseband VGA Settling Time Gain change from B5:B1 = 10111 to B5:B1 = 00111; gain
settling to within ±2dB of steady state 0.1 µs
I/Q Output DC Step when RXHP
Transitions from 1 to 0 in
Presence of 802.11g Short
Sequence
After switching RXHP to logic 0 from initial logic 1, during
ideal short sequence data at -55dBm input in AWGN
channel, for -19dBV output; normalized to RMS signal on
I and Q outputs; transition point varied from 0 to 0.8µs in
steps of 0.1µs
-5 dBc
I/Q Output DC Droop After switching RXHP to 0, D13:D12, Register 7
(A3:A0 = 0111) ±1 V/s
I/Q Static DC Offset RXHP = 1, B7:B1 = 1101110, 1σ variation ±1 mV
Spurious Signal Emissions from
LNA input RF = 1GHz to 26.5GHz -51 dBm
RECEIVER BASEBAND FILTERS
Gain Ripple in Passband 10kHz to 8.5MHz at baseband ±1.3 DBP-P
G r oup - D el ay Ri p p l e i n P assb and 10kHz to 8.5MHz at baseband ±45 nsP-P
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
_______________________________________________________________________________________ 5
AC ELECTRICAL CHARACTERISTICS—Rx Mode (continued)
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA=+25°C, fRF = 2.439GHz, fLO = 2.437GHz; receiver baseband I/Q out-
puts at 112 mVRMS (-19dBV), fREF = 40MHz, SHDN = CS = high, RXTX = SCLK = DIN = low, with power matching for the differential
RF pins using the typical applications and registers set to default settings and corresponding test mode, unless otherwise noted.
Unmodulated single-tone RF input signal is used with specifications which normally apply over the entire operating conditions, unless
otherwise indicated. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB,
balun, and SMA connectors.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
At 8.5MHz 3.2
At 15MHz 27
At 20MHz 50
Baseband Filter Rejection
(Nominal Mode)
At > 40MHz 80
dB
RSSI
RSSI Minimum Output Voltage RLOAD 10k || 5pF 0.4 V
RSSI Maximum Output Voltage RLOAD 10k || 5pF 2.4 V
RSSI Slope 30 mV/dB
+32dB signal step 200
RSSI Output Settling Time To within 3dB of steady
state -32dB signal step 600 ns
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
6 _______________________________________________________________________________________
AC ELECTRICAL CHARACTERISTICS—Tx Mode
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fRF = 2.439GHz , fLO = 2.437GHz. fREF = 40MHz, SHDN =
RXTX = CS = high, and SCLK = DIN = low, with power matching for the differential RF pins using the typical applications circuit.
100mVRMS sine and cosine signal (or 100mVRMS 54Mbps IEEE 802.11g I/Q signals wherever OFDM is mentioned) applied to base-
band I/Q inputs of transmitter (differential DC-coupled). Registers set to recommend settings and corresponding test mode, unless
otherwise noted. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB, balun,
and SMA connectors.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
TRANSMIT SECTION: Tx BASEBAND I/Q INPUTS TO RF OUTPUTS
RF Output Frequency Range 2.4 2.5 GHz
Output power adjusted
to meet 5.6% EVM,
and spectral mask
18.5
54Mbps 802.11g
OFDM signal
B6:B1 = 000000 -7.5
MAX2831
802.11b signal,
141mVRMS,
IEEE802.11b I/Q
signals
Output power adjusted
to meet spectral mask 21
-3dB VGA back off -5.3
Output Power
MAX2832 B6:B1 = 000000 -31.5
dBm
U nw anted S i d eb and S up p r essi on Without I/Q calibration, B6:B1 = 100001 -42 dBc
Carrier Leakage at Center
Frequency of Channel Without DC offset correction -30 dBc
1/3 x fLO -67
< 1GHz -36
> 1GHz -47
2/3 x fLO -64
4/3 x fLO -42
5/3 x fLO -65
8/3 x fLO -51
2 x fLO -33
Transmitter Spurious Signal
Emissions (MAX2831)
B6:B1 = 111000,
OFDM signal
3 x fLO -54
dBm/
MHz
1/3 x fLO -78
< 1GHz -65
> 1GHz -72
2/3 x fLO -78
4/3 x fLO -46
5/3 x fLO -72
8/3 x fLO -46
2 x fLO -60
Transmitter Spurious Signal
Emissions (MAX2832)
B6:B1 = 111111,
OFDM signal
3 x fLO -75
dBm/
MHz
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
_______________________________________________________________________________________ 7
AC ELECTRICAL CHARACTERISTICS—Tx Mode (continued)
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fRF = 2.439GHz , fLO = 2.437GHz. fREF = 40MHz, SHDN =
RXTX = CS = high, and SCLK = DIN = low, with power matching for the differential RF pins using the typical applications circuit.
100mVRMS sine and cosine signal (or 100mVRMS 54Mbps IEEE 802.11g I/Q signals wherever OFDM is mentioned) applied to base-
band I/Q inputs of transmitter (differential DC-coupled). Registers set to recommend settings and corresponding test mode, unless
otherwise noted. RF inputs/outputs specifications are referenced to device pins and do not include 1dB loss from EV kit PCB, balun,
and SMA connectors.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
MAX2831 -20
RF Output Return Loss O ff- chi p b al un + m atch, si ng l e-
end ed MAX2832 -10 dB
Minimum differential resistance 20 k
Tx I/Q Input Load Impedance
(R || C) Maximum differential capacitance 0.7 pF
Baseband -3dB Corner
Frequency
D1:D0 = 01, Register 8
(A3:A0 = 1000) Nominal mode 11 MHz
Baseband Filter Rejection At 30MHz, in nominal mode 62 dB
Minimum Power Detector Output
Voltage Short sequence transmitter power = +9dBm 0.3 V
Maximum Power Detector Output
Voltage Short sequence transmitter power = +19dBm 1.2 V
RF P ow er D etector Resp onse Ti m e 0.3 µs
TRANSMITTER LO LEAKAGE AND I/Q CALIBRATION USING LO LEAKAGE AND SIDEBAND DETECTOR (see the Tx/Rx
Calibration Mode section)
Tx BASEBAND I/Q INPUTS TO RECEIVER OUTPUTS
Output at 1 x fTONE
(for LO leakage = -29dBc),
fTONE = 2MHz, 100mVRMS
-34
LO Leakage and Sideband
Detector Output
Calibration register,
D12:D11 = 00,
A3:A0 = 0110 Output at 2 x fTONE
(for LO leakage = -240dBc),
fTONE = 2MHz, 100mVRMS
-44
d BV
RM S
Amplifier Gain Range D12:D11 = 00 to D12:D11 = 11, A3:A0 = 0110 30 dB
Lower -3dB Corner Frequency 1 MHz
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
8 _______________________________________________________________________________________
AC ELECTRICAL CHARACTERISTICS—Frequency Synthesis
(MAX2831 EV kit: VCC_ = 2.7V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, SCLK =
DIN = low, PLL loop bandwidth = 150kHz, and TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
FREQUENCY SYNTHESIZER
RF Channel Center Frequency 2.4 2.5 GHz
Channel Center Frequency
Programming Minimum Step Size 20 Hz
Charge-Pump Comparison
Frequency 20 MHz
Reference Frequency Range 20 44 MHz
Reference Frequency Input
Levels AC-coupled to XTAL pin 800 mVP-P
Resistance (XTAL) 5 k
Reference Frequency Input
Impedance (R || C) Capacitance (XTAL) 4 pF
fOFFSET = 1kHz -86
fOFFSET = 10kHz -94
fOFFSET = 100kHz -94
fOFFSET = 1MHz -110
Closed-Loop Phase Noise
fOFFSET = 10MHz -120
dBc/Hz
Closed-Loop Integrated Phase
Noise RMS phase jitter; integrate from 10kHz to 10MHz offset 0.9 D eg r ees
Charge-Pump Output Current 1mA
Reference Spurs 20MHz offset -55 dBc
3µs to 9µs 50
VCO Frequency Error M easur ed fr om Tx- Rx or Rx- Tx
tr ansi ti on > 9µs 1 kHz
VOLTAGE-CONTROLLED OSCILLATOR
Pushing Referred to 2400MHz LO, VCC varies by 0.3V 210 kHz
VCO Tuning Voltage Range 0.5 2.2 V
VTUNE = 0.5V 103
LO Tuning Gain VTUNE = 2.2V 86
MHz/V
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
_______________________________________________________________________________________ 9
AC ELECTRICAL CHARACTERISTICS—Miscellaneous Blocks
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, fLO = 2.437GHZ, fREF = 40MHz, SHDN = CS = high, SCLK = DIN = low,
and TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
CRYSTAL OSCILLATOR
M axi m um cap aci tance, A3:A0 = 1110, D 6:D 0 = 1111111 15.4
On-Chip Tuning Capacitance
Range M i ni m um cap aci tance, A3:A0 = 1110, D 6:D 0 = 0000000 0.5 pF
On-Chip Tuning Capacitance
Step Size 0.12 pF
ON-CHIP TEMPERATURE SENSOR
TA = -40°C 0.35
TA = +25°C 1Output Voltage A3:A0 = 1000, D 9:D 8 = 01
TA = +85°C 1.6
V
AC ELECTRICAL CHARACTERISTICS—Timing
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA=+25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, SCLK =
DIN = low, PLL loop bandwidth = 150kHz, and TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
SYSTEM TIMING (See Figure 3)
Turn-On Time From SHDN rising edge to LO settled within 1kHz using
external reference frequency input 60 µs
Crystal Oscillator Turn-On Time 90% of final output amplitude level 1 ms
Channel Switching Time Loop BW = 150kHz, fRF = 2.5GHz to 2.4GHz 25 µs
Rx to Tx 2
Rx/Tx Turnaround Time
Measured from Tx or Rx
enable rising edge; signal
settling to within ±2dB of
steady state Tx to Rx, RXHP = 1 2
µs
Tx Turn-On Time (from Standby
Mode)
From Tx-enable active rising edge; signal settling to
within ±2dB of steady state 1.5 µs
Tx Turn-Off Time (from Standby
Mode) From Tx-enable inactive rising edge 1 µs
Rx Turn-On Time (from Standby
Mode)
From Rx-enable active rising edge; signal settling to
within ±2dB of steady state 1.9 µs
Rx Turn-Off Time (from Standby
Mode) From Rx-enable inactive rising edge 0.1 µs
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
10 ______________________________________________________________________________________
AC ELECTRICAL CHARACTERISTICS—Timing (continued)
(MAX2831 EV kit: VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA=+25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, SCLK =
DIN = low, PLL loop bandwidth = 150kHz, and TA= +25°C, unless otherwise noted.) (Note 1)
PARAMETER CONDITIONS MIN TYP MAX UNITS
3-WIRE SERIAL-INTERFACE TIMING (See Figure 2)
SCLK Rising Edge to CS Falling
Edge Wait Time, tCSO 6ns
Falling Edge of CS to Rising
Edge of First SCLK Time, tCSS 6ns
DIN to SCLK Setup Time, tDS 6ns
DIN to SCLK Hold Time, tDH 6ns
SCLK Pulse-Width High, tCH 6ns
SCLK Pulse-Width Low, tCL 6ns
Last Rising Edge of SCLK to
Rising Edge of CS or Clock to
Load Enable Setup Time, tCSH
6ns
CS High Pulse Width, tCSW 20 ns
Time Between the Rising Edge of
CS and the Next Rising Edge of
SCLK, tCS1
6ns
Clock Frequency, fCLK 20 MHz
Rise Time, tR2ns
Fall Time, tF2ns
Note 1: Min and max limits are guaranteed by test at TA= +25°C and +85°C and guaranteed by design and characterization at
TA= -40°C. The power-on register settings are not production tested. Recommended register setting must be loaded after
VCC is supplied.
Note 2: Guaranteed by design and characterization.
Note 3: The nominal part-to-part variation of the RF gain step is ±1dB.
Note 4: Two tones at +25MHz and +48MHz offset with -35dBm/tone. Measure IM3 at 2MHz.
Note 5: Tx I/Q inputs = 100mVRMS.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 11
Rx ICC vs. VCC
VCC (V)
ICC (mA)
MAX2831/32 toc01
2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6
61
62
63
64
65
66
67
TA = +25°C
TA = -40°C
TA = +85°C
NOISE FIGURE
vs. BASEBAND GAIN SETTINGS
BASEBAND GAIN SETTINGS
NF (dB)
MAX2831/32 toc02
02468101214161820222426283032
0
5
10
15
20
25
30
35
40
45
LNA = HIGH GAIN
LNA = MEDIUM GAIN
LNA = LOW GAIN
Rx VOLTAGE GAIN
vs. BASEBAND GAIN SETTING
BASEBAND GAIN SETTINGS
GAIN (dB)
MAX2831/32 toc03
02468101214161820222426283032
0
10
20
30
40
50
60
70
80
90
100
LNA = LOW GAIN
LNA = MEDIUM GAIN
LNA = HIGH GAIN
Rx IN-BAND OUTPUT P-1dB vs. GAIN
GAIN (dB)
OUTPUT P-1dB (dBVRMS)
MAX2831/32 toc04
15 25 35 45 55 75 85 95
-7
-6
-5
-4
-3
-2
-1
0
LNA MEDIUM/HIGH-
GAIN SWITCH POINT
LNA MEDIUM/LOW-
GAIN SWITCH POINT
Rx EVM vs. PIN
PIN (dBm)
EVM (%)
MAX2831/32 toc05
-80 -70 -60 -50 -40 -30 -20 -10 0
0
2
4
6
8
10
12
14
16
18
20
22
LNA = HIGH GAIN LNA = LOW GAIN
LNA = MEDIUM GAIN
Rx EVM vs. VOUT
VOUT (dBVRMS)
EVM (%)
MAX2831/32 toc06
-29 -27 -25 -23 -21 -19 -17 -15 -13 -11 -9
0
0.5
1.0
1.5
2.0
2.5
3.0
PIN = -50dBm
LNA = HIGH GAIN
OFDM EVM WITH OFDM JAMMER
vs. OFFSET FREQUENCY
PJAMMER (dBm)
EVM (%)
MAX2831/32 toc07
-65 -55 -45 -35 -25
0
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
fOFFSET = 20MHz
fOFFSET = 25MHz
fOFFSET = 40MHz
PIN = -62dBm
Rx EMISSION SPECTRUM, LNA INPUT
MAX2831/32 toc08
RBW = 300kHz
VCO LEAKAGE
1.5 VCO LEAKAGE
2x VCO LEAKAGE
3x VCO
4x VCO
dBM
-40
-50
-60
-70
-80
-90
-100
-110
-120
-130
-140
DC 26.5GHz
LNA = LOW GAIN
LNA INPUT RETURN LOSS
vs. RF FREQUENCY
RF FREQUENCY (MHz)
INPUT RETURN LOSS (dB)
MAX2831/32 toc09
2300 2350 2400 2450 2500 2550 2600
-30
-25
-20
-15
-10
-5
MID GAIN
LOW GAIN
HIGH GAIN
Typical Operating Characteristics
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
12 ______________________________________________________________________________________
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
Rx RSSI OUTPUT vs. INPUT POWER
PIN (dBm)
RSSI OUTPUT (V)
MAX2831/32 toc10
-120 -100 -80 -60 -40 -20 0 20
0
0.5
1.0
1.5
2.0
2.5
3.0
LNA = HIGH GAIN
LNA = MEDIUM GAIN
LNA = LOW GAIN
Rx RSSI STEP RESPONSE
(+32dB LNA GAIN STEP)
3V
0
0.45
1.45V
200ns/div
MAX2831/32 toc11
Rx RSSI STEP RESPONSE
(-32dB LNA GAIN STEP)
3V
0V
0V
1.5V
200ns/div
MAX2831/32 toc12
Rx I/Q DC OFFSET SETTLING RESPONSE
(+8dB BB VGA GAIN STEP)
2.0V
5mV
40ns/div
10mV
0V
0V
MAX2831/32 toc13
Rx I/Q DC OFFSET SETTLING RESPONSE
(-8dB BB VGA GAIN STEP)
MAX2831/32 toc14
2.5V
5mV
40ns/div
10mV
0V
0mV
Rx I/Q DC OFFSET SETTLING RESPONSE
(-16dB BB VGA GAIN STEP)
3V
MAX2831/32 toc15
5mV
400ns/div
10mV
0V
0V
Rx I/Q DC OFFSET SETTLING RESPONSE
(-32dB BB VGA GAIN STEP)
3V
MAX2831/32 toc16
5mV
400ns/div
10mV
0V
0V
I/Q OUTPUT DC ERROR DROOP
(RxHP = 10; 100Hz MODE)
3V
MAX2831/32 toc17
-5mV
20ms/div
0V
0V
-10mV
Rx BB VGA SETTLING RESPONSE
(+8 GAIN STEP)
500mV
-500mV
3V
0V
0V
MAX2831/32 toc18
40ns/div
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 13
Rx BB VGA SETTLING RESPONSE
(-8 GAIN STEP)
3V
0V
MAX2831/32 toc19
500mV
-500mV
0V
40ns/div
Rx BB VGA SETTLING RESPONSE
(-16 GAIN STEP)
MAX2831/32 toc20
500mV
-500mV
3V
0V
0V
40ns/div
Rx BB VGA SETTLING RESPONSE
(-32 GAIN STEP)
MAX2831/32 toc21
500mV
-500mV
3V
0V
0V
40ns/div
RF LNA SETTLING RESPONSE
(HIGH TO MEDIUM)
MAX2831/32 toc22
500mV
-500mV
3V
0V
0V
100ns/div
RF LNA SETTLING RESPONSE
(HIGH TO LOW)
MAX2831/32 toc23
500mV
-500mV
3V
0V
0V
100ns/div
Rx BB FREQUENCY RESPONSE vs.
FINE SETTING (COARSE SETTING = 8.5MHz)
FREQUENCY (MHz)
dB
MAX2831/32 toc24
-100
-80
-60
-40
-20
0
20
110100
Rx BB FREQUENCY RESPONSE vs.
COARSE SETTING (FINE SETTING = 010)
FREQUENCY (MHz)
dB
MAX2831/32 toc25
-120
-100
-80
-60
-40
-20
0
20
1 10 100
RX BASEBAND FILTER
GROUP DELAY
MAX2831/32 toc26
FREQUENCY (MHz)
20ns/div
121
0
26
13
52
39
65
78
HISTOGRAM: Rx STATIC DC OFFSET
MAX2831/32 toc27
1σ/div
MEAN: 0mV
STD: 0.977mV
SAMPLE SIZE: 1006
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
14 ______________________________________________________________________________________
Tx ICC vs. VCC
VCC (V)
ICC (mA)
MAX2831/32 toc30
2.7 2.8 2.9 3.0 3.1 3.2 3.3 3.4 3.5 3.6
78
80
82
84
86
88
TA = +25°C
TA = -40°C
TA = +85°C
0
16
8
32
24
40
48
HISTOGRAM: Tx LO LEAKAGE
MAX2831/32 toc31
1σ/div
MEAN: -33.45dBc
STD: 6.31dB
SAMPLE SIZE: 999
0
24
12
48
36
60
72
HISTOGRAM: Tx SIDEBAND
SUPPRESSION
MAX2831/32 toc32
1σ/div
MEAN: -42dBc
STD: 1.9dB
SAMPLE SIZE: 1000
0
46
23
92
69
115
138
HISTOGRAM: Rx GAIN IMBALANCE
MAX2831/32 toc28
1σ/div
MEAN: 0dB
STD: 0.064dB
SAMPLE SIZE: 951
0
38
19
76
57
95
114
HISTOGRAM: Rx PHASE IMBALANCE
MAX2831/32 toc29
1σ/div
MEAN: 0.3°
STD: 0.314°
SAMPLE SIZE: 1013
0
4
2
8
6
10
12
HISTOGRAM: Tx OUTPUT POWER
VARIATION
MAX2831/32 toc33
0.1dB/div
MEAN: 18.5dBm
GAIN ADJUSTED
TO ACHIEVE 5.6%
EVM
-90
-70
-60
-50
-40
-30
-20
-10
0
0.1 1 10 100
Tx BASEBAND FREQUENCY RESPONSE
MAX2831/32 toc34
BASEBAND FREQUENCY (MHz)
FILTER RESPONSE (dB)
-80
Tx OUTPUT POWER vs. FREQUENCY
(B6:B1 = 111111)
(MAX2832 ONLY)
FREQUENCY (GHz)
POUT (dBm)
MAX2831/32 toc35
2.40 2.42 2.44 2.46 2.48 2.50
-4.0
-3.5
-3.0
-2.5
-2.0
-1.5
-1.0
-0.5
0
TA = +85°C
TA = +25°C
TA = -40°C
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
Tx OUTPUT POWER vs. GAIN SETTING
(MAX2832 ONLY)
GAIN SETTINGS
POUT (dBm)
MAX2831/32 toc36
0 4 8 12 16 20 24 28 32 36 40 44 48 52 56 60 64
-30
-25
-40
-35
-20
-15
-10
-5
0
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 15
11g SPECTRAL MASK
(MAX2832 ONLY)
FREQUENCY (MHz)
246724472407 2427
-99
-89
-79
-69
dBm
-59
-49
-39
-29
-19
-9
-109
2387 2487
MAX2831/32 toc37
POUT = -2.17dBm
EVM = 2.12%
PA SUPPLY CURRENT vs. POUT
POUT (dBm)
PA SUPPLY CURRENT (mA)
MAX2831/32 toc40
02468101214161820 2422
130
160
190
220
250
280
VCCPA = 2.7V, 3.0V, 3.3V
VCCPA = 4.2V
Tx GAIN VARIATION vs. FREQUENCY
(B6:B1 = 101001)
FREQUENCY (GHz)
1dB/div
MAX2831/32 toc41
2.40 2.42 2.44 2.46 2.48 2.50
TA = -40°C
TA = +25°C
TA = +85°C
Tx OUTPUT POWER vs. FREQUENCY
FREQUENCY (GHz)
POUT (dBm)
MAX2831/32 toc42
2.40 2.42 2.44 2.46 2.48 2.50
16
17
18
19
20
TA = -40°C
TA = +25°C
TA = +85°C
GAIN ADJUSTED TO ACHIEVE 5.6% EVM
11g SPECTRAL MASK
FREQUENCY (MHz)
POUT = 18.64dBm
EVM = 5.6%
246724472407 2427
-99
-89
-79
-69
-59
-49
dBm
-39
-29
-19
-9
-109
2387 2487
MAX2831/32 toc43
-80
-90
-10
-70
-60
-50
-40
dBm
-30
-20
-100
-110
Tx OUTPUT SPURS
(MAX2832 ONLY)
MAX2831/32 toc38
DC 26.5GHz
RF
VCO
2x RF
2x VCO
3x VCO
4x VCO
RBW = 1MHz
802.11g SIGNAL
Tx EVM vs. POUT
POUT (dBm)
EVM (%)
MAX2831/32 toc39a
0246810121416182022
2
3
4
5
6
7
8
VCCPA = 2.7V
VCCPA = 3.0V
VCCPA = 3.3V
VCCPA = 4.2V
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
EVM vs. Tx OUTPUT POWER
(MAX2832 ONLY)
OUTPUT POWER (dBm)
EVM (%)
MAX2831/32 toc36a
-30 -24 -18 -12 -6 0
1.00
1.25
1.50
1.75
2.00
2.25
2.50
2.75
3.00
802.11g POUT vs. GAIN SETTING
(UPPER GAIN CONTROL RANGE)
GAIN SETTINGS
POUT (dBm)
MAX2831/32 toc44
40 44 48 52 56 60 64
12
14
16
18
20
22
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
16 ______________________________________________________________________________________
POWER DETECTOR OVER FREQUENCY
OUTPUT POWER (dBm)
POWER DETECTOR (V)
MAX2831/32 toc45
0 2 4 6 8 10 12 14 16 18 20 22
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
fRF = 2.4GHz
fRF = 2.5GHz
POWER DETECTOR OVER SUPPLY VOLTAGE
OUTPUT POWER (dBm)
POWER DETECTOR (V)
MAX2831/32 toc46
0 2 4 6 8 10 12 14 16 18 20 22
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
VCCPA = 2.7V, 3.0V
VCCPA = 3.3V, 4.2V
0
6
4
2
8
10
12
PA OUTPUT POWER HISTORGRAM
FOR 1.1V POWER DETECTOR OUTPUT
MAX2831/32 toc50
0.1dB/div
MEAN = 18.5dBm
PA OUTPUT ENVELOPE RESPONSE
1µs/div
MAX2831/32 toc49
-20dBm
0
20dBm
-50mV
50mV
PA ENVELOPE
TX I/Q INPUT
Tx OUTPUT SPURS
MAX2831/32 toc52
0
-80
-90
10
-70
-60
-50
-40
-30
-20
-10
26.5GHzDC
RF
VCO2x RF
2x VCO
3x RF
4x RF
RBW = 1MHz
802.11g SIGNAL
POWER-DETECTOR OUTPUT
100ns/div
MAX2831/32 toc48
300mV
-300mV
0V
1V
20dB GAIN STEP PA ENVELOPE
POWER DETECTOR
POWER DETECTOR OVER TEMPERATURE
POUT (dBm)
POWER DETECTOR (V)
MAX2831/32 toc47
0 2 4 6 8 10 12 14 16 18 20 22
0
0.2
0.4
0.6
0.8
1.0
1.2
1.4
1.6
1.8
2.0
TA = +85°C
TA = -40°C,
+25°C
PA OUTPUT RETURN LOSS
vs. RF FREQUENCY
RF FREQUENCY (MHz)
OUTPUT RETURN LOSS (dB)
MAX2831/32 toc51
2300 2350 2400 2450 2500 2550 2600
-30
-25
-20
-15
-10
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 17
CHANNEL SWITCHING FREQUENCY
SETTLING (FROM 2500MHz TO 2400MHz)
50kHz
-50kHz
250µs0
10kHz/
div
MAX2831/32 toc55
PLL SETTLING TIME FROM
SHUTDOWN TO STANDBY MODE
50kHz
-50kHz
0 2ms
10kHz/
div
MAX2831/32 toc56
PLL SETTLING TIME
FROM STANDBY TO Tx
50kHz
-50kHz
030
µs
10kHz/
div
MAX2831/32 toc57
LO FREQUENCY vs. VTUNE
VTUNE (V)
LO FREQUENCY (MHz)
MAX2831/32 toc53
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0 2.2 2.4
2300
2350
2400
2450
2500
2550
2600
LO PHASE NOISE
vs. OFFSET FREQUENCY
OFFSET FREQUENCY (MHz)
PHASE NOISE (dBc/Hz)
MAX2831/32 toc54
-150
-140
-130
-120
-110
-100
-90
-80
-70
-60
-50
0.001 0.01 0.1 1 10
Typical Operating Characteristics (continued)
(MAX2831 EV kit, VCC_ = 2.8V, VCCPA = VCCTXPA = 3.3V, TA= +25°C, fLO = 2.437GHz, fREF = 40MHz, SHDN = CS = high, RXHP =
SCLK = DIN = low.)
Rx TO Tx TURNAROUND
PLL SETTLING TIME
25kHz
-25kHz
50µs0
5kHz/
div
MAX2831/32 toc58
CLOCK OUTPUT
0V
10ns/div
3V
MAX2831/32 toc60
fCLOCK = 40MHz
CLOAD = 5pF
CRYSTAL-OSCILLATOR OFFSET FREQUENCY
vs. CRYSTAL-OSCILLATOR TUNING BITS
CTUNE (DIGITAL BITS)
CRYSTAL OFFSET FREQUENCY (Hz)
MAX2831/32 toc61
0 102030405060708090100110120130
-800
-700
-600
-500
-400
-300
-200
-100
0
100
200
300
400
500
600
700
800 KYOCERA
(CX-3225SB)
Tx-Rx TURNAROUND PLL SETTLING TIME
5kHz/div
-25kHz
050µs
25kHz
MAX2831/32 toc59
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
18 ______________________________________________________________________________________
B2
1
2
3
4
5
6
7
8
9
10
11
12
13 14 15 16 17 18 19 20 21 22 23 24
48 47 46 45 44 43 42 41 40 39 38 37
36
35
34
33
32
31
30
29
28
27
26
25
VCCLNA
B6
GNDRXLNA
RXRF+
RXRF-
B7
VCCPA
TXRF+
TXRF-
SHDN
POWER DETECTOR
SERIAL
INTERFACE
TEMP
SENSOR
AM
DETECTOR
VCCTXPA
B5
CS
RSSI
VCCTXMX
SCLK
DIN
VCCPLL
CLOCKOUT
LD
B1
CPOUT
RXBBQ+
RXBBQ-
RX Q
OUTPUTS
RX/TX GAIN
CONTROL
B4
BYPASS
TUNE
GNDVCO
CTUNE
VCCVCO
XTAL
PLL
÷
GNDCP
SERIAL INPUTS
VCCXTAL
VCCCP
RXTX
GNDTEST
VCCRXMX
TXBBI+
TXBBI-
TXBBQ+
TXBBQ-
VCCRXFL
RXHP
VCCRXVGA
RXBBI+
RXBBI-
MAX2831
MODE
CONTROL
RX/TX GAIN
CONTROL
RX/TX GAIN
CONTROL
REFERENCE
CLOCK BUFFER
OUTPUT
NOTE: ALL GROUND (PINS 2, 26, AND 31) AND BYPASS CAPACITORS’ GROUND REQUIRE THEIR OWN VIAS TO GROUND.
DO NOT CONNECT THEM TO THE EXPOSED PADDLE GROUND.
RX BASEBAND HPF
CORNER FREQUENCY
CONTROL
B3
RX/TX
GAIN CONTROL
RX INPUT
TX OUTPUT
MODE CONTROL
RX/TX GAIN
CONTROL
RX/TX GAIN
CONTROL
RX GAIN
CONTROL
TX INPUT RX I OUTPUTS
0°
90°
RSSI
MUX
TO RSSI
MUX
RSSI
TEMP
SENSOR
CRYSTAL
OSCILLATOR/
BUFFER
÷
RSSI
TO
RSSI
MUX MUX
IMUX QMUX
MUX
Block Diagrams/Typical Operating Circuits
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 19
B2
1
2
3
4
5
6
7
8
9
10
11
12
13 14 15 16 17 18 19 20 21 22 23 24
48 47 46 45 44 43 42 41 40 39 38 37
36
35
34
33
32
31
30
29
28
27
26
25
VCCLNA
B6
GNDRXLNA
RXRF+
RXRF-
B7
VCCPA
TXRF+
TXRF-
SHDN
SERIAL
INTERFACE
TEMP
SENSOR
VCCTXPA
B5
CS
RSSI
VCCTXMX
SCLK
DIN
VCCPLL
CLOCKOUT
LD
B1
CPOUT
RXBBQ+
RXBBQ-
RX Q
OUTPUTS
RX/TX GAIN
CONTROL
B4
BYPASS
TUNE
GNDVCO
CTUNE
VCCVCO
XTAL
PLL
÷
GNDCP
SERIAL INPUTS
VCCXTAL
VCCCP
RXTX
GNDTEST
VCCRXMX
TXBBI+
TXBBI-
TXBBQ+
TXBBQ-
VCCRXFL
RXHP
VCCRXVGA
RXBBI+
RXBBI-
MAX2832
MODE
CONTROL
RX/TX GAIN
CONTROL
RX/TX GAIN
CONTROL
REFERENCE
CLOCK BUFFER
OUTPUT
RX BASEBAND HPF
CORNER FREQUENCY
CONTROL
B3
RX/TX
GAIN CONTROL
RX INPUT
TX OUTPUT
MODE CONTROL
RX/TX GAIN
CONTROL
RX/TX GAIN
CONTROL
RX GAIN
CONTROL
TX INPUT RX I OUTPUTS
0°
90°
RSSI
MUX
TO RSSI
MUX
RSSI
TEMP
SENSOR
CRYSTAL
OSCILLATOR/
BUFFER
÷
RSSI
TO
RSSI
MUX
AM
DETECTOR
IMUX QMUX
NOTE: ALL GROUND (PINS 2, 26, AND 31) AND BYPASS CAPACITORS’ GROUND REQUIRE THEIR OWN VIAS TO GROUND.
DO NOT CONNECT THEM TO THE EXPOSED PADDLE GROUND.
MUX
MUX
Block Diagrams/Typical Operating Circuits (continued)
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
20 ______________________________________________________________________________________
Pin Description
PIN NAME FUNCTION
1V
CCLNA LNA Supply Voltage
2 GNDRXLNA LNA Ground
3 B6 Receiver and Transmitter Gain-Control Logic-Input Bit 6
4 RXRF+
5 RXRF-
LNA Differential Input. Input is internally AC-coupled and matched to 100 differential. Connect
directly to a 2:1 balun.
6 B7 Receiver Gain-Control Logic-Input Bit 7
7V
CCPA Supply Voltage for Second Stage of Power Amplifier
8 B3 Receiver and Transmitter Gain-Control Logic-Input Bit 3
9 TXRF+
10 TXRF-
Power-Amplifier Differential Output for the MAX2831. PA output must be AC-coupled. PA driver
internally AC-coupled differential outputs and matched to 100 differential for the MAX2832. Connect
directly to a 2:1 balun.
11 B2 Receiver and Transmitter Gain-Control Logic-Input Bit 2
12 SHDN Active-Low Shutdown and Standby Logic Input. See Table 31 for operating modes.
13 VCCTXPA Supply Voltage for First-Stage of PA and PA Driver
14 B5 Receiver and Transmitter Gain-Control Logic-Input Bit 5
15 CS Active-Low Chip-Select Logic Input of 3-Wire Serial Interface (See Figure 2)
16 RSSI RSSI, PA Power Detector (MAX2831 Only) or Temperature-Sensor Multiplexed Analog Output
17 VCCTXMX Transmitter Upconverter Supply Voltage
18 SCLK Serial-Clock Logic Input of 3-Wire Serial Interface (See Figure 2)
19 DIN Data Logic Input of 3-Wire Serial Interface (See Figure 2)
20 VCCPLL PLL and Registers Supply Voltage. Connect to the supply voltage to retain the register settings.
21 CLOCKOUT Reference Clock Buffer Output
22 LD Lock- D etect Log i c Outp ut of Fr eq uency S ynthesi zer . O utp ut hi g h i nd i cates that the fr eq uency synthesi zer
i s l ocked . O utp ut p r og r am m ab l e as C M OS or op en- d r ai n outp ut. ( S ee Tab l es 16 and 20.)
23 B1 Receiver and Transmitter Gain-Control Logic-Input Bit 1
24 CPOUT Charge-Pump Output. Connect the frequency synthesizer’s loop filter between CPOUT and TUNE
(see the Block Diagrams/Typical Operating Circuits).
25 VCCCP PLL Charge-Pump Supply Voltage
26 GNDCP Charge-Pump Circuit Ground
27 VCCXTAL Crystal Oscillator Supply Voltage
28 XTAL Crystal or Reference Clock Input. AC-couple a crystal or a reference clock to this analog input.
29 CTUNE Connection for Crystal Oscillator Off-Chip Capacitors. When using an external reference clock input,
leave CTUNE unconnected.
30 VCCVCO VCO Supply Voltage
31 GNDVCO VCO Ground
32 TUNE VCO TUNE Input (see the Block Diagrams/Typical Operating Circuits)
33 BYPASS On-Chip VCO Regulator Output Bypass. Bypass with a 0.1µF to 1µF capacitor to GND. Do not
connect other circuitry to this point.
34 B4 Receiver and Transmitter Gain-Control Logic-Input Bit 4
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 21
Detailed Description
The MAX2831/MAX2832 single-chip, low-power, direct
conversion, zero-IF transceivers are designed to support
802.11g/b applications operating in the 2.4GHz to
2.5GHz band. The fully integrated transceivers include a
receive path, transmit path, voltage-controlled oscillator
(VCO), sigma-delta fractional-N synthesizer, crystal oscil-
lator, RSSI, PA power detector (MAX2831), temperature
sensor, Rx and Tx I/Q error-detection circuitry, baseband-
control interface and linear power amplifier (MAX2831).
The only additional components required to implement a
complete radio front-end solution are a crystal, a pair of
baluns, a BPF, a switch, and a small number of passive
components (RCs, no inductors required).
Receiver
The fully integrated receiver achieves a noise figure of
2.6dB in high-gain mode, and an input compression point
of -6dBm in low-gain mode, while consuming only 62mA
of supply current. The receiver integrates an LNA and
VGA with a 95dB digitally programmable gain control
range, direct-conversion downconverters, I/Q baseband
lowpass filters with programmable LPF corner frequen-
cies, analog RSSI and integrated DC-offset correction cir-
cuitry. A logic-low on the RXTX input (pin 48) and a
logic-high on the SHDN input (pin 12) enable the receiver.
LNA Input Matching
The LNA features a differential input that is internally
AC-coupled and internally matched to 100. Connect a
2:1 balun transformer directly to the RXRF+ (pin 4) and
RXRF- (pin 5) ports to convert the differential 100
input impedance to a single-ended 50input. Provide
electrically symmetrical input traces from the LNA input
to the balun to maintain IP2 performance and RF com-
mon-mode noise rejection.
LNA Gain Control
The LNA has three gain modes: max gain, max gain -
16dB, and max gain - 33dB. The three LNA gain modes
can be serially programmed through the SPI™ interface
by programming bits D6:D5 in Register 11 (A3:A0 =
1011) or programmed in parallel through the digital
logic gain-control pins, B7 (pin 6) and B6 (pin 3). Set
bit D12 = 1 in Register 8 (A3:A0 = 1000) to enable pro-
gramming through the SPI interface, or set bit D12 = 0
to enable parallel programming. See Table 1 for LNA
gain-control settings.
Pin Description (continued)
PIN NAME FUNCTION
35 RXBBQ-
36 RXBBQ+
Receiver Baseband Q-Channel Differential Outputs. In TX calibration mode, these pins are the LO
leakage and sideband detector outputs.
37 RXBBI-
38 RXBBI+
Receiver Baseband I-Channel Differential Outputs. In TX calibration mode, these pins are the LO
leakage and sideband detector outputs.
39 VCCRXVGA Receiver VGA Supply Voltage
40 RXHP Receiver Baseband AC-Coupling High-Pass Corner Frequency Control Logic Input
41 VCCRXFL Receiver Baseband Filter Supply Voltage
42 TXBBQ-
43 TXBBQ+ Transmitter Baseband I-Channel Differential Inputs
44 TXBBI-
45 TXBBI+ Transmitter Baseband Q-Channel Differential Inputs
46 VCCRXMX Receiver Downconverters Supply Voltage
47 GNDTEST Connect to Ground
48 RXTX RX/TX Mode Control Logic Input. See Table 31 for operating modes.
—EP
Exposed Paddle. Connect to the ground plane with multiple vias for proper operation and heat
dissipation. Do not share with any other pin grounds and bypass capacitors' ground.
Table 1. LNA Gain-Control Settings (Pins
B7:B6 or Register A3:A0 = 1011, D6:D5)
B7 OR D6 B6 OR D5 NAME DESCRIPTION
1 1 High Max gain
1 0 Medium Max gain - 16dB (typ)
0 X Low Max gain - 33dB (typ)
SPI is a trademark of Motorola, Inc.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
22 ______________________________________________________________________________________
Baseband Variable-Gain Amplifier
The receiver baseband variable-gain amplifiers provide
62dB of gain control range programmable in 2dB steps.
The VGA gain can be serially programmed through the
SPI interface by setting bits D4:D0 in Register 11 (A3:A0
= 1011) or programmed in parallel through the digital
logic gain-control pins, B5 (pin 14), B4 (pin 34), B3 (pin
8), B2 (pin 11), and B1 (pin 23). Set bit D12 = 1 in
Register 8 (A3:A0 = 1000) to enable serial programming
through the serial interface or set bit D12 = 0 to enable
parallel programming through the external logic pins.
See Table 2 for the gain-step value and Table 3 for
baseband VGA gain-control settings.
Receiver Baseband Lowpass Filter
The receiver integrates lowpass filters that provide an
upper -3dB corner frequency of 8.5MHz (nominal mode)
with 50dB of attenuation at 20MHz, and 45ns of group
delay ripple in the passband (10kHz to 8.5MHz). The
upper -3dB corner frequency is tightly controlled on-chip
and does not require user adjustment. However, provi-
sions are made to allow fine tuning of the upper -3dB cor-
ner frequency. In addition, coarse frequency tuning
allows the -3dB corner frequency to be set to 7.5MHz
(11b mode), 8.5MHz (11g mode), 15MHz (turbo 1 mode),
and 18MHz (turbo 2 mode) by programming bits D1:D0
in Register 8 (A3:A0 = 1000). See Table 4. The coarse
corner frequency can be fine-tuned approximately ±10%
in 5% steps by programming bits D2:D0 in Register 7
(A3:A0 = 0111). See Table 5 for receiver LPF fine -3dB
corner frequency adjustment.
Baseband Highpass Filter
and DC Offset Correction
The receiver implements programmable AC and near-
DC coupling of I/Q baseband signals. Temporary AC-
coupling is used to quickly remove LO leakage and
other DC offsets that could saturate the receiver out-
puts. When DC offsets have settled, near DC-coupling
is enabled to avoid attenuation of the received signal.
AC-coupling is set (-3dB highpass corner frequency of
600kHz) when a logic-high is applied to RXHP (pin 40).
Near DC-coupling is set (-3dB highpass corner fre-
quency of 100Hz nominal) when a logic-low is applied
to RXHP. Bits D13:D12 in Register 7 (A3:A0 = 0111)
allow the near DC-coupling -3B highpass corner fre-
quency to be set to 100Hz (D13:D12 = 00), 4kHz
(D13:D12 = X1), or 30kHz (D13:D12 = 10). See Table 6.
Table 2. Receiver Baseband VGA Gain-
Step Value (Pins B5:B1 or Register D4:D0,
A3:A0 = 1011)
Table 3. Baseband VGA Gain-Control
Settings in Receiver Gain-Control Register
(Pin B5:B1 or Register D4:D0, A3:A0 = 1011)
Table 4. Receiver LPF Coarse -3dB
Corner Frequency Settings in Register
(A3:A0 = 1000)
Table 5. Receiver LPF Fine -3dB Corner
Frequency Adjustment in Register
(A3:A0 = 0111)
PIN/BIT GAIN STEP (dB)
B1/D0 2
B2/D1 4
B3/D2 8
B4/D3 16
B5/D4 32
BITS (D2:D0) % ADJUSTMENT RELATIVE TO
COARSE SETTING
000 90
001 95
010 100
011 105
100 110
B5:B1 OR D4:D0 GAIN
11111 Max
11110 Max - 2dB
11101 Max - 4dB
::
00000 Min
BITS (D1:D0) -3dB CORNER
FREQUENCY (MHz) MODE
00 7.5 11b
01 8.5 11g
10 15 Turbo 1
11 18 Turbo 2
Table 6. Receiver Highpass Filter -3dB
Corner Frequency Programming
RXHP A3:A0 = 0111,
D13:D12
-3dB HIGHPASS CORNER
FREQUENCY (Hz)
1 XX 600k
0 00 100 (recommended)
0X1 4k
0 10 30k
X = Don’t care.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 23
Receiver I/Q Baseband Outputs
The differential outputs (RXBBI+, RXBBI-, RXBBQ+,
RXBBQ-) of the baseband amplifiers have a differential
output impedance of ~300Ω, and are capable of dri-
ving differential loads up to 10kΩ|| 10pF. The outputs
are internally biased to a common-mode voltage of
1.1V and are intended to be DC-coupled to the in-
phase (I) and quadrature (Q) analog-to-digital data
converter inputs of the accompanying baseband IC.
Additionally, the common-mode output voltage can be
adjusted from 1.1V to 1.4V through programming bits
D11:D10 in Register 15 (A3:A0 = 1111).
Received Signal-Strength Indicator (RSSI)
The RSSI output (pin 16) can be programmed to multi-
plex an analog output voltage proportional to the
received signal strength, the PA output power
(MAX2831), or the die temperature. Set bits D9:D8 = 00
in Register 8 (A3:A0 = 1000) to enable the RSSI output
in receive mode (off in transmit mode). Set bit D10 = 1
to enables the RSSI output when RXHP = 1, and dis-
able the RSSI output when RXHP = 0. Set bit D10 = 0 to
enable the RSSI output independent of RXHP. See
Table 7 for a summary of the RSSI output versus regis-
ter programming and RXHP.
The received signal strength indicator provides an ana-
log voltage proportional to the log of the sum of the
squares of the I and Q channels, measured after the
receive baseband filters and before the variable-gain
amplifiers. The RSSI analog output voltage is propor-
tional to the RF input signal level and LNA gain state
over a 60dB range, and is not dependent upon VGA
gain. See the graph RX RSSI Output vs. Input Power in
the Typical Operating Characteristics for further details.
Transmitter
The transmitter integrates baseband lowpass filters,
direct-upconversion mixers, a VGA, a PA driver, and a lin-
ear RF PA with a power detector (MAX2831). A logic-high
on the RXTX input (pin 48) and a logic-high on the SHDN
input (pin 12) enable the transmitter.
Transmitter I/Q Baseband Inputs
The differential analog inputs of the transmitter baseband
amplifier I/Q inputs (TXBBI+, TXBBI-, TXBBQ+, TXBBQ-)
have a differential impedance of 20kΩ|| 1pF. The inputs
require an input common-mode voltage of 0.9V to 1.3V,
which is provided by the DC-coupled I and Q DAC out-
puts of the accompanying baseband IC.
Transmitter Baseband Lowpass Filtering
The transmitter integrates lowpass filters that can be
tuned to -3dB corner frequencies of 8MHz (11b),
11MHz (11g), 16.5MHz (turbo 1 mode), and 22.5MHz
(turbo 2 mode) through programming bits D1:D0 in
Register 8 (A3:A0 = 1000) and bit D5:D3 in Register 7
(A3:A0 = 0111). The -3dB corner-frequency is tightly con-
trolled on-chip and does not require user adjustment.
Additionally, provisions are made to fine tune the -3dB cor-
ner frequency through bits D5:D3 in the Filter
Programming register (A3:A0 = 0111). See Tables 8 and 9.
Table 7. RSSI Pin Truth Table
Table 8. Transmitter LPF Coarse -3dB
Corner Frequency Settings in Register
(A3:A0 = 1000)
BITS (D1:D0) -3dB CORNER
FREQUENCY (MHz) MODE
00 8 11b
01 11 11g
10 16.5 Turbo 1
11 22.5 Turbo 2
Table 9. Transmitter LPF Fine -3dB
Corner Frequency Adjustment in
Register (A3:A0 = 0111)
BITS (D5:D3) % ADJUSTMENT RELATIVE TO
COARSE SETTING
000 90
001 95
010 100
011 105
100 110 (11g)
101 115
101–111 Not used
INPUT CONDITIONS
A3:A0 = 1000,
D9:D8
A3:A0 = 1000,
D10 RXHP RSSI OUTPUT
X 0 0 No signal
00 0 1 RSSI
01 0 1 Temperature
sensor
10 0 1 Power detector
(MAX2831)
00 1 X RSSI
01 1 X Temperature
sensor
10 1 X Power detector
(MAX2831)
X = Don’t care.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
24 ______________________________________________________________________________________
Transmitter Variable-Gain Amplifier
The variable-gain amplifier of the transmitter provides
31dB of gain control range programmable in 0.5dB
steps over the top 8dB of the gain control range and in
1dB steps below that. The transmitter gain can be pro-
grammed serially through the SPI interface by setting
bits D5:D0 in Register 12 (A3:A0 = 1100) or in parallel
through the digital logic gain-control pins B6:B1 (pins
3, 6, 8, 11, 14, 23, and 34, respectively). Set bit D10 =
0 in Register 9 (A3:A0 = 1001) to enable parallel pro-
gramming, and set bit D10 = 1 to enable programming
through the 3-wire serial interface. See Table 10 for the
transmitter VGA gain-control settings.
Power-Amplifier Driver Output Matching (MAX2832)
The PA driver of the MAX2832 has a 100differential
output with on-chip AC-coupling capacitors. Provide
electrically symmetrical traces to present a balanced
load to the PA driver output to help maintain driver lin-
earity and RF common-mode rejection.
Power-Amplifier Bias, Enable Delay
and Output Matching (MAX2831)
The MAX2831 integrates a 2-stage PA, providing
+18.5dBm of output power at 5.6% EVM (54Mbps
OFDM signal) in 802.11g mode while exceeding the
802.11g spectral mask requirements. The first and sec-
ond stage PA bias currents are set through program-
ming bits D2:D0 and bits D6:D3 in Register 10 (A3:A0 =
1010), respectively. An adjustable PA enable delay, rel-
ative to the transmitter enable (RXTX low-to-high transi-
tion), can be set from 200ns to 7µs through
programming bits D13:D10 in Register 10 (A3:A0 =
1010).
The PA of the MAX2831 has a 100differential output
that is internally matched. The output has to be AC-cou-
pled using two off-chip 1.5pF capacitors to a 100:50
balun. Provide electrically symmetrical traces from the
PA output to the balun to present a balanced load and to
reduce out-of-band spurs.
Power Detector (MAX2831)
The MAX2831 integrates a voltage-peak detector at the
PA output and provides an analog voltage proportional
to PA output power. See the Power Detector Over
Frequency and Power Detector Over Supply Voltage
graphs in the Typical Operating Characteristics. Set bits
D9:D8 = 10 in Register 8 (A3:A0 = 1000) to multiplex the
power-detector analog output voltage to the RSSI output
(pin 16).
Synthesizer Programming
The MAX2831/MAX2832 integrate a 20-bit sigma-delta
fractional-N synthesizer, allowing the device to achieve
excellent phase-noise performance (0.9° RMS from
10kHz to 10MHz), fast PLL settling times, and an RF fre-
quency step-size of 20Hz. The synthesizer includes a
divide-by-1 or a divide-by-2 reference frequency
divider, an 8-bit integer portion main divider with a divi-
sor range programmable from 64 to 255, and a 20-bit
fractional portion main-divider. Bit D2 in Register 5
(A3:A0 = 0101) sets the reference oscillator divider ratio
to 1 or 2. Bits D7:D0 in Register 3 (A3:A0 = 0011) set
the integer portion of the main divider. The 20-bit frac-
tional portion of the main-divider is split between two
registers. The 14 MSBs of the fractional portion are set
in Register 4 (A3:A0 = 0100), and the 6 LSBs of the frac-
tional portion of the main divider are set in Register 3
(A3:A0 = 0011). See Tables 11 and 12.
Table 10. Transmitter VGA Gain-Control
Settings
NUMBER D5:D0 Or
B6:B1 OUTPUT SIGNAL POWER
63 111111 Max
62 111110 Max - 0.5dB
61 111101 Max - 1.0dB
:: :
49 110001 Max - 7dB
48 110000 Max - 7.5dB
47 101111 Max - 8dB
46 101110 Max - 8dB
45 101101 Max - 9dB
44 101100 Max - 9dB
:: :
5 000101 Max - 29dB
4 000100 Max - 29dB
3 000011 Max - 30dB
2 000010 Max - 30dB
1 000001 Max - 31dB
0 000000 Max - 31dB
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 25
Calculating Integer and Fractional Divider Ratios
The desired integer and fractional divider ratios can be
calculated by dividing the RF frequency (fRF) by fCOMP.
For nominal 802.11g/b operation, a 40MHz reference
oscillator is divided by 2 to generate a 20MHz compari-
son frequency (fCOMP). The following method can be
used when calculating divider ratios supporting various
reference and comparison frequencies:
LO Frequency Divider = fRF / fCOMP = 2437MHz /
20MHz = 121.85
Integer Divider = 121 (d) = 0111 1001 (binary)
Fractional Divider = 0.85 x (220 - 1) = 891289 (decimal)
= 1101 1001 1001 1001 1001
See Table 13 for integer and fractional divider ratios for
802.11g/b systems using a 20MHz comparison frequency.
Table 11. Integer Divider Register (A3:A0 = 0011)
BIT RECOMMENDED DESCRIPTION
D13:D8 00000 6 LSBs of 20-Bit Fractional Portion of Main Divider
D7:D0 01111001 8-Bit Integer Portion of Main Divider. Programmable from 64 to 255.
Table 12. Fractional Divider Register (A3:A0 = 0100)
BIT RECOMMENDED DESCRIPTION
D13:D0 11011001100110 14 MSBs of 20-Bit Fractional Portion of Main Divider
Table 13. IEEE 802.11g/b Divider-Ratio Programming Words
INTEGER DIVIDER FRACTIONAL DIVIDER
fRF
(MHz) (fRF / fCOMP)A3:A0 = 0011, D7:D0 A3:A0 = 0100, D13:D0 A3:A0 = 0011, D13:D8
2412 120.6 0111 1000b 2666h 1Ah
2417 120.85 0111 1000b 3666h 1Ah
2422 121.1 0111 1001b 0666h 1Ah
2427 121.35 0111 1001b 1666h 1Ah
2432 121.6 0111 1001b 2666h 1Ah
2437 121.85 0111 1001b 3666h 1Ah
2442 122.1 0111 1010b 0666h 1Ah
2447 122.35 0111 1010b 1666h 1Ah
2452 122.6 0111 1010b 2666h 1Ah
2457 122.85 0111 1010b 3666h 1Ah
2462 123.1 0111 1011b 0666h 1Ah
2467 123.35 0111 1011b 1666h 1Ah
2472 123.6 0111 1011b 2666h 1Ah
2484 124.2 0111 1100b 0CCCh 33h
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
26 ______________________________________________________________________________________
Crystal Oscillator
The crystal oscillator has been optimized to work with
low-cost crystals (e.g., Kyocera CX-3225SB). See Figure
1. The crystal oscillator frequency can be fine tuned
through bits D6:D0 in Register 14 (A3:A0 = 1110), which
control the value of CTUNE from 0.5pF to 15.4pF in
0.12pF steps. See the Crystal-Oscillator Offset
Frequency vs. Crystal-Oscillator Tuning Bits graph in the
Typical Operating Characteristics. The crystal oscillator
can be used as a buffer for an external reference fre-
quency source. In this case, the reference signal is AC-
coupled to the XTAL pin, and capacitors C1 and C2 are
not connected. When used as a buffer, the XTAL input
pin has to be AC-coupled. The XTAL pin has an input
impedance of 5k|| 4pF, (set D6:D0 = 0000000 in
Register 14 A3:A0 = 1110).
Reference Clock Output Divider/Buffer
The reference oscillator of the MAX2831/MAX2832 has
a divider and a buffered output for routing the refer-
ence clock to the accompanying baseband IC. Bit D10
in Register 14 (A3:A0 = 1110) sets the buffer divider to
divide by 1 or 2, independent of the divide ratio for the
reference frequency provided to the PLL. Bit B9 in the
same register enables or disables the reference buffer
output. See the Clock Output waveform in the Typical
Operating Characteristics.
Loop Filter
The PLL charge-pump output, CPOUT (pin 24), con-
nects to an external third-order, lowpass RC loop-filter,
which in turn connects to the voltage tuning input,
TUNE (pin 32), of the VCO, completing the PLL loop.
The charge-pump output sink and source current is
1mA, and the VCO tuning gain is 103MHz/V at 0.5V
tune voltage and 86MHz/V at 2.2V tune voltage. The RC
loop-filter values have been optimized for a loop band-
width of 150kHz, to achieve the desired Tx/Rx turn-
around settling time, while maintaining loop stability
and good phase noise. Refer to the MAX2831 EV kit
schematic for the recommended loop-filter component
values. Keep the line from this pinto the tune input as
short as possible to prevent spurious pickup.
Lock-Detector Output
The PLL features a logic lock-detect output. A logic-high
indicates the PLL is locked, and a logic-low indicates
the PLL is not locked. Bit D5 in Register 5 (A3:A0 =
0101) enables or disables the lock-detect output. Bit
D12 in Register 1 (A3:A0 = 0001) configures the lock-
detect output as a CMOS or open-drain output. In open-
drain output mode, bit D9 in Register 5 (A3:A0 = 0101)
enables or disables an internal 30kpullup resistor
from the open-drain output.
Figure 1. Crystal Oscillator Schematic
XTAL
CTUNE
5.9k
CTUNE
C2
C1
FOR EXTERNAL REFERENCE CLOCK SET, C1 = C2 = OPEN
1.35k
28
29
MAX2831
MAX2832
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 27
*The power-on register settings are not production tested. Recommended register settings must be loaded after VCC is supplied.
Table 14. Recommended Register Settings*
DATA ADDRESS
REGISTER D13 D12 D11 D10 D9 D8 D7 D6 D5 D4 D3 D2 D1 D0 (A3:A0) TABLE
0 01011101000000 0000 15
1 01000110011010 0001 16
2 01000000000011 0010 17
3 00000001111001 0011 18
4 11011001100110 0100 19
5 00000010100100 0101 20
6 00000001100000 0110 21
7 01000000100010 0111 22
8 10000000100001 1000 23
9 00001110110101 1001 24
10 01110110100100 1010 25
11 00000001111111 1011 26
12 00000101000000 1100 27
13 00111010010010 1101 28
14 00001100111011 1110 29
15 00000101000101 1111 30
BIT 16BIT 2BIT 1 BIT 24BIT 23BIT 15
tCH
DIN
tCSS
SCLK
tCSO
tDS
tDH
tCL
tCSW
tCSH
t
CS1
CS
Figure 2. 3-Wire SPI Serial-Interface Timing Diagram
Programmable Registers and
3-Wire SPI-Interface
The MAX2831/MAX2832 include 16 programmable, 18-
bit registers. The 14 most significant bits (MSBs) are
used for register data. The 4 least significant bits
(LSBs) of each register contain the register address.
See Table 14 for a summary of the registers and rec-
ommended register settings.
Register data is loaded through the 3-wire SPI/
MICROWIRE™-compatible serial interface. Data is
shifted in MSB first and is framed by CS. When CS is
low, the clock is active, and data is shifted with the ris-
ing edge of the clock. When CS transitions high, the
shift register is latched into the register selected by the
contents of the address bits. See Figure 2. Only the last
18 bits shifted into the device are retained in the shift
register. No check is made on the number of clock
pulses. For programming data words less than 14 bits
long, only the required data bits and the address bits
need to be shifted, resulting in faster Rx and Tx gain
control where only the LSBs need to be programmed.
MICROWIRE is a trademark of National Semiconductor Corp.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
28 ______________________________________________________________________________________
Table 20. Register 5 (A3:A0 = 0101)
BIT RECOMMENDED DESCRIPTION
D13:D10 0000 Set to recommended value.
D9 0
Lock-Detect Output Internal Pullup Resistor Enable. Set to 1 to enable internal 30k pullup
resistor or set to 0 to disable the resistor. Only available when lock-detect, open-drain output
is selected (A3:A0 = 0010, D12 = 1).
D8:D6 010 Set to recommended value.
D5 1 Lock-Detect Output Enable. Set to 1 to enable the lock-detect output or set to 0 to disable the
output. The output is high impedance when disabled.
D4:D3 00 Set to recommended value.
D2 1 Reference Frequency Divider Ratio to PLL. Set to 0 to divide by 1. Set to 1 to divide by 2.
D1:D0 00 Set to recommended value.
Table 15. Register 0 (A3:A0 = 0000)
DATA BITS RECOMMENDED DESCRIPTION
D13:D11 000 Set to recommended value.
D10 1 Fractional-N PLL Mode Enable. Set 1 to enable the fractional-N PLL or set 0 to enable the
integer-N PLL.
D9:D0 1101000000 Set to recommended value.
Table 16. Register 1 (A3:A0 = 0001)
DATA BITS RECOMMENDED DESCRIPTION
D13 0 Set to recommended value.
D12 1
Lock-Detector Output Select. Set to 1 for CMOS Output. Set to 0 for open-drain output. Bit D9
in register (A3:A0 = 0101) enables or disables an internal 30k pullup resistor in open-drain
output mode.
D11:D0 000110011010 Set to recommended value.
Table 17. Register 2 (A3:A0 = 0010)
DATA BITS RECOMMENDED DESCRIPTION
D13:D0 01000000000011 Set to recommended value.
This register contains the 8-bit integer portion and 6 LSBs of the fractional portion of the divider ratio of the synthesizer.
Table 18. Register 3 (A3:A0 = 0011)
BIT RECOMMENDED DESCRIPTION
D13:D8 00000 6 LSBs of 20-Bit Fractional Portion of Main Divider
D7:D0 01111001 8-Bit Integer Portion of Main Divider. Programmable from 64 to 255.
Table 19. Register 4 (A3:A0 = 0100)
BIT RECOMMENDED DESCRIPTION
D13:D0 11011001100110 14 MSBs of 20-Bit Fractional Portion of Main Divider
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 29
Table 21. Register 6 (A3:A0 = 0110)
DATA BIT RECOMMENDED DESCRIPTION
D13 0 Set to recommended value.
D12:D11 00 Tx I/Q Calibration LO Leakage and Sideband Detector Gain-Control Bits. D12:D11 = 00: 9dB;
01 19dB; 10: 29dB; 11: 39dB.
D10:D7 0000 Set to recommended value.
D6 1 Power-Detector Enable in Tx Mode. Set to 1 to enable the power detector or set to 0 to
disable the detector.
D5:D2 1000 Set to recommended value.
D1 0 Tx Calibration Mode. Set to 1 to place the device in Tx calibration mode or 0 to place the
device in normal Tx mode when RXTX is set to 1 (see Table 31).
D0 0 Rx Calibration Mode. Set to 1 to place the device in Rx calibration mode or 0 to place the
device in normal Rx mode when RXTX is set to 0 (see Table 31).
Table 22. Register 7 (A3:A0 = 0111)
BIT RECOMMENDED DESCRIPTION
D13:D12 01 Receiver Highpass Corner Frequency Setting for RXHP = 0. Set to 00 for 100Hz, X1 for 4kHz,
and 10 for 30kHz.
D11:D6 000000 Set to recommended value.
D5:D3 100 Transmitter Lowpass Filter Corner Frequency Fine Adjustment (Relative to Coarse Setting).
See Table 8. Bits D1:D0 in A3:A0 = 1000 provide the lowpass filter corner coarse adjustment.
D2:D0 010 Receiver Lowpass Filter Corner Frequency Fine Adjustment (Relative to Coarse Setting). See
Table 5. Bits D1:D0 in A3:A0 = 1000 provide the lowpass filter corner coarse adjustment.
Table 23. Register 8 (A3:A0 = 1000)
BIT RECOMMENDED DESCRIPTION
D13 1 Set to recommended value.
D12 0
Enable Receiver Gain Programming Through the Serial Interface. Set to 1 to enable
programming through the 3-wire serial interface (D6:D0 in Register A3:A0 = 1011). Set to 0 to
enable programming in parallel through external digital pins (B7:B1).
D11 0 Set to recommended value.
D10 0 RSSI Operating Mode. Set to 1 to enable RSSI output independent of RXHP. Set to 0 to
disable RSSI output if RXHP = 0, and enable the RSSI output if RXHP = 1.
D9:D8 00
RS S I, P ow er D etector or Tem p er atur e S ensor O utp ut S el ect. S et to 00 to enab l e the RS S I
outp ut i n r ecei ve m od e. S et to 01 to enab l e the tem p er atur e sensor outp ut i n r ecei ve and
tr ansm i t m od es. S et to 10 to enab l e the p ow er - d etector outp ut i n tr ansm i t m od e. S ee Tab l e 7.
D7:D2 001000 Set to recommended value.
D1:D0 01 Receiver and Transmitter Lowpass Filter Corner Frequency Coarse Adjustment. See Tables 4
and 7.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
30 ______________________________________________________________________________________
Table 26. Register 11 (A3:A0 = 1011)
BIT RECOMMENDED DESCRIPTION
D13:D7 0000000 Set to recommended value.
D6:D5 11 LNA Gain Control. Set to 11 for high-gain mode. Set to 10 for medium-gain mode, reducing
LNA gain by 16dB. Set to 0X for low-gain mode, reducing LNA gain by 33dB.
D4:D0 11111 Receiver VGA Control. Set D4:D0 = 00000 for minimum gain and D4:D0 = 11111 for
maximum gain.
Table 27. Register 12 (A3:A0 = 1100)
BIT RECOMMENDED DESCRIPTION
D13:D6 00000101 Set to recommended value.
D5:D0 000000 Transmitter VGA Gain Control. Set D5:D0 = 000000 for minimum gain, and set D5:D0 =
111111 for maximum gain.
Table 28. Register 13 (A3:A0 = 1101)
BIT RECOMMENDED DESCRIPTION
D13:D10 0011 Set to recommended value.
D9:D6 1010 Set to recommended value.
D5:D0 010010 Set to recommended value.
Table 25. Register 10 (A3:A0 = 1010)
BIT RECOMMENDED DESCRIPTION
D13:D10 0111 P ow er - Am p l i fi er E nab l e D el ay. S ets a d el ay b etw een RX TX l ow - to- hi g h tr ansi ti on and i nter nal P A
enab l e. P r og r am m ab l e i n 0.5µs step s. D 13:D 10 = 0001 ( 0.2µs) and D 13:D 10 = 1111 ( 7µs) .
D9:D7 011 Set to recommended value.
D6:D3 0100 Second-Stage Power-Amplifier Bias Current Adjustment. Set to XXXX for 802.11g/b.
D2:D0 100 First-Stage Power-Amplifier Bias Current Adjustment. Set to XXX for 802.11g/b.
Table 24. Register 9 (A3:A0 = 1001)
BIT RECOMMENDED DESCRIPTION
D13:D11 000 Set to recommended value.
D10 0
Enable Transmitter Gain Programming Through the Serial or Parallel Interface. Set to 1 to
enable programming through the 3-wire serial interface (D5:D0 in Register A3:A0 = 1011).
Set to 0 to enable programming in parallel through external digital pins (B6:B1).
D9:D0 1110110101 Set to recommended value.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 31
Table 29. Register 14 (A3:A0 = 1110)
BIT RECOMMENDED DESCRIPTION
D13:D11 000 Set to recommended value.
D10 0 Reference Clock Output Divider Ratio. Set 1 to divide by 2 or set 0 to divide by 1.
D9 1 Refer ence C l ock Outp ut E nab l e. S et 1 to enab l e the r efer ence cl ock outp ut or set 0 to d i sab l e.
D8:D7 10 Set to recommended value.
D6:D0 XXXXXXX Crystal-Oscillator Fine Tune. Tunes crystal oscillator over ±20ppm to within ±1ppm.
Table 30. Register 15 (A3:A0 = 1111)
BIT RECOMMENDED DESCRIPTION
D13:D12 00 Set to recommended value.
D11:D10 00 Receiver I/Q Output Common-Mode Voltage Adjustment. Set D11:D10 = 00: 1.1V,
01: 1.2V, 10: 1.3V, 11: 1.45V.
D9:D0 0101000101 Set to recommended value.
Table 31. Operating Mode Table
LOGIC PINS REGISTER
SETTINGS CIRCUIT BLOCK STATES
MODE
SHDN RXTX D1:D0
(A3:A0 = 0110) Rx PATH Tx PATH
PLL, VCO,
LO GEN,
AUTO-TUNER
CALIBRATION
SECTIONS ON
Shutdown 0 0 00 Off Off Off None
Standby 0 1 00 Off Off On None
Rx 1 0 X0 On Off On None
Tx 1 1 0X Off On On None
Rx Calibration 1 0 X1 On
(except LNA) Upconverters On C al tone, RF p hase
shi ft, Tx fi l ter
Tx Calibration 1 1 1X Off On (except PA
driver and PA) On AM detector,
Rx I/Q buffers
X = Don’t care.
X = Don’t care.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
32 ______________________________________________________________________________________
Modes of Operation
The modes of operation for the MAX2831/MAX2832 are
shutdown, standby, transmit, receive, transmitter calibra-
tion, and receiver calibration. See Table 31 for a summa-
ry of the modes of operation. The logic-input pins, SHDN
(pin 12) and RXTX (pin 48), control the various modes.
Shutdown Mode
The MAX2831/MAX2832 feature a low-power shutdown
mode that disables all circuit blocks, except the serial-
interface and internal registers, allowing the registers to
be loaded and values maintained, as long as VCC is
applied. Set SHDN and RXTX logic-low to place the
device in shutdown mode.
After supply voltage ramp up, supply current in shut-
down mode could be high. Program the default value to
SPI register 0 to eliminate high shutdown current.
Standby Mode
The standby mode is used to enable the frequency
synthesizer block while the rest of the device is pow-
ered down. In this mode, the PLL, VCO, and LO gener-
ators are on, so that Tx or Rx modes can be quickly
enabled from this mode. Set SHDN to a logic-low and
RXTX to a logic-high to place the device in standby
mode.
Receive (Rx) Mode
The complete receive signal path is enabled in this
mode. Set SHDN to logic-high and RXTX to logic-low to
place the device in Rx mode.
Transmit (Tx) Mode
The complete transmitter signal path is enabled in this
mode. Set SHDN and RXTX to logic-high to place the
device in Tx mode.
Tx/Rx Calibration Mode
The MAX2831/MAX2832 feature Rx/Tx calibration modes
to detect I/Q imbalances and transmit LO leakage. In the
Tx calibration mode, all Tx circuit blocks, except the PA
driver and external PA, are powered on and active. The
AM detector and receiver I and Q channel buffers are
also on, along with multiplexers in the receiver side to
route this AM detector’s signal. In this mode, the LO
leakage calibration is done only for the LO leakage sig-
nal that is present at the center frequency of the channel
(i.e., in the middle of the OFDM or QPSK spectrum). The
LO leakage calibration includes the effect of all DC off-
sets in the entire baseband paths of the I/Q modulator
and direct leakage of the LO to the I/Q modulator output.
The LO leakage and sideband detector output are
taken at the receiver I and Q channel outputs during
this calibration phase.
During Tx LO leakage and I/Q imbalance calibration, a
sine and cosine signal (f = fTONE) is input to the base-
band I/Q Tx pins from the baseband IC. At the LO leak-
age and sideband-detector output, the LO leakage
corresponds to the signal at fTONE and the sideband
suppression corresponds to the signal at 2 x fTONE. The
output power of these signals vary 1dB for 1dB of varia-
tion in the LO leakage and sideband suppression. To
calibrate the Tx path, first set the power-detector gain
to 9dB using D12:D11 in Register 5 (see Table 21).
Adjust the DC offset of the baseband inputs to minimize
the signal at fTONE (LO leakage). Then, adjust the base-
band input relative magnitude and phase offsets to
reduce the signal at 2 x fTONE.
In Rx calibration mode, the calibrated Tx RF signal is
internally routed to the Rx inputs. In this mode, the
VCO/LO generator/PLL blocks are powered on and
active except for the low-noise amplifier (LNA).
Applications Information
Layout Issues
The MAX2831 EV kit can be used as a starting point for
layout. For best performance, take into consideration
grounding and RF, baseband, and power-supply rout-
ing. Make connections from vias to the ground plane as
short as possible. Do not connect the device ground
pin to the exposed paddle ground. Keep the buffered
clock output trace as short as
possible. Do not share the trace with the RF input layer,
especially on or inter-layer or back side of the board.
On the high-impedance ports, keep traces short to min-
imize shunt capacitance. EV kit Gerber files can be
requested at www.maxim-ic.com.
Power-Supply Layout
To minimize coupling between different sections of the
IC, a star power-supply routing configuration with a
large decoupling capacitor at a central VCC node is rec-
ommended. The VCC traces branch out from this node,
each going to a separate VCC node in the circuit. Place
a bypass capacitor as close as possible to each supply
pin. This arrangement provides local decoupling at
each VCC pin. Use at least one via per bypass capacitor
for a low-inductance ground connection. Do not share
the capacitor ground vias with any other branch and the
exposed paddle ground.
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
______________________________________________________________________________________ 33
SCLK
POWER SUPPLY
ON
IREF
SHUTDOWN
MODE
STANDBY
MODE
DIN
SHUTDOWN
SCLK (CLOCK)
DIN (DATA)
RXTX
RECEIVE
MODE
TRANSMIT
MODE
INTERNAL PA
ENABLED PA ENABLE
(DRIVES POWER RAMP CONTROL)
3-WIRE SERIAL INTERFACE AVAILABLE
POWER
SPI:
CHANNEL FREQUENCY, PA BIAS, TRANSMITTER LINEARITY,
RECEIVER RSSI OPERATION, CALIBRATION MODE, ETC.
MAC SPI MAC
0 TO 7µs
CS
SHDN
CS (SELECT)
MAX2831/MAX2832
Figure 3. Timing Diagram
Pin Configuration
TOP VIEW
MAX2831
MAX2832
GNDCP
EP
SHDN
B2
TXRF-
TXRF+
B3
VCCPA
B7
RXRF-
RXRF+
B6
+
GNDRXLNA
VCCLNA
CPOUT
B1
LD
CLOCKOUT
VCCPLL
DIN
SCLK
VCCTXMX
RSSI
CS
B5
VCCTXPA
RXBBI-
RXBBI+
VCCRXVGA
RXHP
VCCRXFL
TXBBQ-
TXBBQ+
TXBBI-
TXBBI+
VCCRXMX
GNDTEST
RXTX
1
2
3
4
5
6
7
8
9
10
11
12
13 14 15 16 17 18 19 20 21 22 23 24
48 47 46 45 44 43 42 41 40 39 38 37
36
35
34
33
32
31
30
29
28
27
26
25
RXBBQ+
RXBBQ-
B4
BYPASS
TUNE
GNDVCO
VCCVCO
CTUNE
XTAL
VCCXTAL
VCCCP
TQFN
Chip Information
PROCESS: BiCMOS
Package Information
For the latest package outline information and land patterns
(footprints), go to www.maxim-ic.com/packages. Note that a
"+", "#", or "-" in the package code indicates RoHS status only.
Package drawings may show a different suffix character, but
the drawing pertains to the package regardless of RoHS status.
PACKAGE
TYPE
PACKAGE
CODE
OUTLINE
NO.
LAND PATTERN
NO.
48 TQFN- E P T4877+ 421 - 01 44 90 - 01 30
MAX2831/MAX2832
2.4GHz to 2.5GHz 802.11g/b
RF Transceivers with Integrated PA
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.
34 ____________________Maxim Integrated Products, 120 San Gabriel Drive, Sunnyvale, CA 94086 408-737-7600
© 2011 Maxim Integrated Products Maxim is a registered trademark of Maxim Integrated Products, Inc.
Revision History
REVISION
NUMBER
REVISION
DATE DESCRIPTION PAGES
CHANGED
0 10/06 Initi al rel ease
1 3/10 Removed MAX2832 future product reference and made minor corrections 1, 2, 10, 18, 19, 20
23/11
Corrected conditions for Rx I/Q Output Common-Mode Voltage Variation in the
DC Electrical Characteristics; corrected Tables 14, 17, and 27; added text to
Shutdown Mode section
2, 27, 28,
30, 32