MAXIM MAX2510EEI

19-1296; Rev 1; 1/98
L
MANUA
ION KIT HEET
T
A
U
L
EVA
TA S
WS DA
FOLLO
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
____________________________Features
The MAX2510 is a highly integrated IF transceiver for
digital wireless applications. It operates from a +2.7V to
+5.5V supply voltage and features four operating
modes for advanced system power management.
Supply current is reduced to 0.2µA in shutdown mode.
In a typical application, the receiver downconverts a
high IF/RF (up to 600MHz) to a low IF (up to 30MHz)
using a double-balanced mixer. Additional functions
included in the receiver section are an IF buffer that
can drive an off-chip filter, an on-chip limiting amplifier
offering 90dB of received-signal-strength indication
(RSSI), and a robust differential limiter output driver
designed to directly drive a CMOS input. The transmitter section upconverts I and Q baseband signals to an
IF in the 100MHz to 600MHz range using a quadrature
modulator. The transmit output is easily matched to
drive a SAW filter with an adjustable output from 0dBm
to -40dBm and excellent linearity.
The MAX2511 has features similar to the MAX2510, but
upconverts a low IF with an image-reject mixer. The
MAX2511 downconverter also offers image rejection
with a limiter/RSSI stage similar to that of the MAX2510.
♦ +2.7V to +5.5V Single-Supply Operation
♦ Complete Receive Path: 600MHz (max) 1st IF to
30MHz (max) 2nd IF
♦ Unique, Wide-Dynamic-Range Downconverter
Mixer Offers -8dBm IIP3, 11dB NF
♦ 90dB Dynamic-Range Limiter with High-Accuracy
RSSI Function
♦ Differential Limiter Output Directly Drives
CMOS Input
♦ 100MHz to 600MHz Transmit Quadrature
Modulator with 41dB Sideband Suppression
♦ 40dB Transmit Gain-Control Range; Up to +1dBm
Output Power
♦ Advanced Power Management (four modes)
♦ 0.2µA Shutdown Supply Current
_______________Ordering Information
PART
MAX2510EEI
________________________Applications
PWT1900, Wireless Handsets, and Base Stations
PACS, PHS, DECT, and Other PCS Wireless
Handsets and Base Stations
400MHz ISM Transceivers
IF Transceivers
Wireless Data Links
TEMP. RANGE
-40°C to +85°C
___________________Pin Configuration
TOP VIEW
LIMIN 1
28 VREF
CZ 2
27 MIXOUT
CZ 3
26 GND
RSSI 4
25 RXIN
GC 5
LO 6
Typical Operating Circuit appears on last page.
PIN-PACKAGE
28 QSOP
24 TXOUT
MAX2510
23 TXOUT
GND 7
22 RXIN
VCC 8
21 VCC
LO 9
20 GND
GND 10
19 VCC
TXEN 11
18 Q
RXEN 12
17 Q
LIMOUT 13
16 I
LIMOUT 14
15 I
QSOP
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800.
For small orders, phone 1-800-835-8769.
MAX2510
________________General Description
MAX2510
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
ABSOLUTE MAXIMUM RATINGS
VCC to GND .............................................................-0.3V to 8.0V
VCC to Any Other VCC ........................................................±0.3V
I, I, Q, Q to GND .........................................-0.3V to (VCC + 0.3V)
I to I, Q to Q Differential Voltage ............................................±2V
RXIN to RXIN Differential Voltage ..........................................±2V
LOIN to LOIN Differential Voltage..........................................±2V
LIMIN Voltage .............................(VREF - 1.3V) to (VREF + 1.3V)
RXEN, TXEN, GC Voltage...........................-0.3V to (VCC + 0.3V)
RXEN, TXEN, GC Input Current ............................................1mA
RSSI Voltage...............................................-0.3V to (VCC + 0.3V)
Continuous Power Dissipation (TA = +70°C)
QSOP (derate 10mW/°C above +70°C) ........................650mW
Operating Temperature Range ...........................-40°C to +85°C
Junction Temperature ......................................................+150°C
Storage Temperature Range .............................-65°C to +165°C
Lead Temperature (soldering, 10sec) .............................+300°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.
DC ELECTRICAL CHARACTERISTICS
(VCC = +2.7V to +5.5V; 0.01µF across CZ and CZ; LO, LO open; MIXOUT tied to VREF through a 165Ω resistor; GC = 0.5V; RXIN,
RXIN open; LIMIN tied through 50Ω to VREF; LIMOUT, LIMOUT = open; RXEN, TXEN = high; bias voltage at I, I, Q, Q = 1.4V;
TA = -40°C to +85°C; unless otherwise noted. Typical values are at TA = +25°C.)
PARAMETER
CONDITIONS
Operating Voltage Range
Digital Input Voltage High
RXEN, TXEN
Digital Input Voltage Low
RXEN, TXEN
Digital Input Current High
RXEN, TXEN = 2.0V
Digital Input Current Low
RXEN, TXEN = 0.4V
MIN
TYP
MAX
UNITS
2.7
3.0
5.5
V
2.0
6
-5
V
30
µA
0.1
µA
20
Transmit mode, RXEN = low, TXEN = high
17
25
Standby mode, RXEN = high, TXEN = high
0.5
1
Shutdown mode, RXEN = low, TXEN = low
0.2
5
µA
VCC / 2 100mV
VCC / 2
VCC / 2 +
100mV
V
50
85
VREF Voltage
GC Input Resistance
0.4
14
Receive mode, RXEN = high, TXEN = low
Supply Current
V
(Note 1)
mA
kΩ
AC ELECTRICAL CHARACTERISTICS
(MAX2510 test fixture; VCC = +3.0V; RXEN = TXEN = low; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor;
TXOUT and TXOUT loaded with 100Ω differential; LO terminated with 50Ω, LO AC grounded; GC open; LIMOUT, LIMOUT are AC
coupled to 250Ω load; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input
matched); fRXIN, RXIN = 240MHz; bias voltage at I, I, Q, Q = 1.4V; VI,Q = 500mVp-p; fI,Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm;
TA = +25°C; unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
600
MHz
DOWNCONVERTER (RXEN = high)
Input Frequency Range
Conversion Gain
(Note 2)
100
TA = +25°C
20.5
TA = -40°C to +85°C (Note 3)
19.9
Noise Figure
Single sideband
Input 1dB Compression Point
(Note 4)
Input Third-Order Intercept
Two tones at 240MHz and 240.2MHz,
-30dBm per tone
LO to RXIN Isolation
Power-Up Time
2
22.5
25
25.5
dB
11
dB
-18.5
dBm
-8
dBm
49
dBc
Standby to RX or TX (Note 5)
_______________________________________________________________________________________
5
µs
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
(MAX2510 test fixture; VCC = +3.0V; RXEN = TXEN = low; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor;
TXOUT and TXOUT loaded with 100Ω differential; LO terminated with 50Ω, LO AC grounded; GC open; LIMOUT, LIMOUT are AC
coupled to 250Ω load; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input
matched); fRXIN, RXIN = 240MHz; bias voltage at I, I, Q, Q = 1.4V; VI,Q = 500mVp-p; fI,Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm;
TA = +25°C; unless otherwise noted.)
PARAMETER
CONDITIONS
MIN
TYP
MAX
UNITS
LIMITING AMPLIFIER AND RSSI (RXEN = high, fLIMIN = 10MHz, PLIMIN = -30dBm from 50Ω source, unless otherwise noted)
Limiter Output Voltage Swing
LIMOUT, LIMOUT
Phase Variation
-75dBm to 5dBm
±4.5
degrees
Minimum Linear RSSI Range
-75dBm to 5dBm
80
dB
Minimum Monotonic RSSI Range
-85dBm to 5dBm
90
dB
RSSI Slope
-75dBm to 5dBm from 50Ω
20
mV/dB
±270
RSSI Maximum Zero-Scale Intercept (Note 6)
RSSI Relative Error (Notes 6, 7)
±300
±350
-86
TA = +25°C
±0.5
TA = -40°C to +85°C (Note 3)
mV
dBm
±2.0
±3.0
dB
Minimum-Scale RSSI Voltage
At LIMIN input of -75dBm
0.25
V
Maximum-Scale RSSI Voltage
At LIMIN input of +5dBm
1.8
V
TRANSMITTER (TXEN = high)
Frequency Range
(Note 8)
I, I, Q, Q Allowable Common-Mode
Voltage Range
100
600
I, I, Q, Q inputs are 250mVp-p centered around
this voltage, GC = 2.0V (Note 9)
1.3
VCC 1.2
I, Q are 500mVp-p while I, Q are held at this DC
voltage (Note 9)
1.4
VCC 1.3
V
GC = 0.5V
-41
GC = open
Output Power
GC = 2.0V (Note 9)
MHz
-16
TA = +25°C
TA = -40°C to +85°C
-2.5
1
dBm
-3
I, I, Q, Q 1dB Bandwidth
(Note 3)
70
80
MHz
Unwanted Sideband Suppression
90° phase difference between I and Q inputs;
GC = 2V
30
40
dBc
LO Rejection
90° phase difference between I and Q inputs;
measured to fundamental tone; GC = 2V
30
44
dBc
Output IM3 Level
Output IM5 Level
GC = 0.5V (Note 11)
-49
GC = 2V (Note 11)
-33
GC = 2V (Note 11)
-51
dBc
dBc
Note 1: This pin is internally terminated to approximately 1.35V through the specified resistance.
Note 2: Downconverter gain is typically greater than 20dB. Operation outside this frequency range is possible but has not been
characterized.
Note 3: Guaranteed by design and characterization.
_______________________________________________________________________________________
3
MAX2510
AC ELECTRICAL CHARACTERISTICS (continued)
Note 4: Driving RXIN or RXIN with a power level greater than the 1dB compression level forces the input stage out of its linear
range, causing harmonic and intermodulation distortion. The RSSI output increases monotonically with increasing input
levels beyond the mixer’s 1dB compression level. Input 1dB compression point is limited by MIXOUT voltage swing, which
is approximately 2Vp-p into a 165Ω load.
Note 5: Assuming the supply voltage has been applied, this includes limiter offset-correction settling and Rx or Tx bias stabilization
time. Guaranteed by design and characterization.
Note 6: The RSSI maximum zero-scale intercept is the maximum (over a statistical sample of parts) input power at which the RSSI
output would be 0V. This point is extrapolated from the linear portion of the RSSI Output Voltage vs. Limiter Input Power
graph in the Typical Operating Characteristics. This specification and the RSSI slope define the RSSI function’s ideal
behavior (the slope and intercept of a straight line), while the RSSI relative error specification defines the deviations from
this line. See the Typical Operating Characteristics for the RSSI Output Voltage vs. Limiter Input Power graph.
Note 7: The RSSI relative error is the deviation from the best-fitting straight line of the RSSI output voltage versus the limiter input
power. This number represents the worst-case deviation at any point along this line. A 0dB relative error is exactly on the
ideal RSSI transfer function. The limiter input power range for this test is -75dBm to 5dBm from 50Ω. See the Typical
Operating Characteristics for the RSSI Relative Error graph.
Note 8: Transmit sideband suppression is typically better than 35dB. Operation outside this frequency range is possible but has
not been characterized.
Note 9: Output IM3 level is typically better than -29dBc.
Note 10: The output power can be increased by raising GC above 2V. Refer to the Transmitter Output Power vs. GC Voltage and
Frequency graph in the Typical Operating Characteristics.
Note 11: Using two tones at 400kHz and 500kHz, 250mVp-p differential per tone at I, I, Q, Q.
__________________________________________Typical Operating Characteristics
(MAX2510 EV kit; VCC = +3.0V; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor; TXOUT and TXOUT loaded
with 100Ω differential; LO terminated with 50Ω; LO AC grounded; GC open; LIMOUT, LIMOUT open; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input matched); fRXIN, RXIN = 240MHz; bias voltage at I, I,
Q, Q = 1.4V; VI,Q = 500mVp-p; f I, Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm; TA = +25°C; unless otherwise noted.)
SUPPLY CURRENT
vs. TEMPERATURE
10
5
14
12
10
8
6
4
0
-20
0
20
40
60
TEMPERATURE (°C)
80
100
20
15
10
STANDBY
0
0
-40
25
5
2
STANDBY
30
SUPPLY CURRENT (mA)
15
Rx
MAX2510toc03
16
SUPPLY CURRENT (mA)
Rx
Tx
18
35
MAX2510toc02
20
MAX2510toc01
Tx
20
4
TRANSMITTER SUPPLY CURRENT
vs. GC VOLTAGE
SUPPLY CURRENT
vs. SUPPLY VOLTAGE
25
SUPPLY CURRENT (mA)
MAX2510
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
2.5
3.0
3.5
4.0
4.5
SUPPLY VOLTAGE (V)
5.0
5.5
0
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
GC VOLTAGE (V)
_______________________________________________________________________________________
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
MAX2510
____________________________ Typical Operating Characteristics (continued)
(MAX2510 EV kit; VCC = +3.0V; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor; TXOUT and TXOUT loaded
with 100Ω differential; LO terminated with 50Ω; LO AC grounded; GC open; LIMOUT, LIMOUT open; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input matched); fRXIN, RXIN = 240MHz; bias voltage at I, I,
Q, Q = 1.4V; VI,Q = 500mVp-p; f I, Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm; TA = +25°C; unless otherwise noted.)
DOWNCONVERTER MIXER CONVERSION
GAIN vs. SUPPLY VOLTAGE
AND TEMPERATURE
25
MAX2510toc05
25
MAX2510toc04
1.0
TA = -40°C
24
20
0.8
GAIN (dB)
TA = +85°C
0.6
TA = -40°C
22
GAIN (dB)
23
TA = +85°C
TA = +25°C
21
0.4
15
10
20
TA = +25°C
0.2
5
19
MISMATCH LOSS
COMPENSATED
18
3.0
3.5
4.0
4.5
5.0
0
2.5
5.5
3.0
3.5
4.0
4.5
5.0
5.5
0 100 200 300 400 500 600 700 800 900 1000
VOLTAGE (V)
SUPPLY VOLTAGE (V)
RF FREQUENCY (MHz)
RECEIVE MIXER INPUT 1dB
COMPRESSION POINT vs. SUPPLY VOLTAGE
-13
TA = +85°C
-14
-15
-16
TA = +25°C
-17
-18
TA = -40°C
-19
500
400
350
300
250
IMAGINARY
200
150
-20
100
-21
50
-22
SINGLE-ENDED
450
REAL IMPEDANCE (Ω)
-12
RXIN INPUT IMPEDANCE
vs. FREQUENCY
MAX2510toc07
2.5
MAX2510toc08
0
INPUT 1dB COMPRESSION (dBm)
SHUTDOWN SUPPLY CURRENT (µA)
1.2
DOWNCONVERTER MIXER CONVERSION
GAIN vs. RXIN FREQUENCY
MAX2510toc06
SHUTDOWN SUPPLY CURRENT
vs. SUPPLY VOLTAGE
REAL
0
2.5
3.0
3.5
4.0
4.5
SUPPLY VOLTAGE (V)
5.0
5.5
30
90
150 210 270 330 390 450 510
FREQENCY (MHz)
_______________________________________________________________________________________
5
____________________________ Typical Operating Characteristics (continued)
(MAX2510 EV kit; VCC = +3.0V; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor; TXOUT and TXOUT loaded
with 100Ω differential; LO terminated with 50Ω; LO AC grounded; GC open; LIMOUT, LIMOUT open; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input matched); fRXIN, RXIN = 240MHz; bias voltage at I, I,
Q, Q = 1.4V; VI,Q = 500mVp-p; f I, Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm; TA = +25°C; unless otherwise noted.)
RSSI ERROR (dB)
1.4
1.2
1.0
VOUT = +85°C
0.6
0.2
TATA= =+25°C
+25°C
2
1
0
-1
-2
VOUT = +25°C
0.4
VOUT = -40°C
0
-80
-60
-40
-20
0
1.2
1.0
0.8
-4
0.2
20
0
-95
-75
-55
-35
-15
-80 -70
5
-30
5
GC = 2.0V
0
OUTPUT POWER (dBm)
230MHz
-40
-20 -10
TRANSMITTER OUTPUT POWER
vs. FREQUENCY
MAX2510toc12
0
-60 -50
RXIN INPUT POWER (dBm)
LIMITER INPUT POWER (dBm, 50Ω)
10
-10
-20
500MHz
-30
200MHz
-40
-5
-10
-15
-20
-50
-25
-60
0.7
0.9
1.1
1.3
1.5
1.7
0
1.9
200
400
600
800
1000
GC VOLTAGE (V)
FREQUENCY (MHz)
TRANSMITTER IM3 LEVELS
vs. GC VOLTAGE
TRANSMITTER OUTPUT 1dB COMPRESSION
POINT vs. GC VOLTAGE
MAX2510toc13
-30
-35
-40
-45
-50
-55
10
OUTPUT 1dB COMPRESSION (dBm)
0.5
MAX2510toc15
OUTPUT POWER (dBm)
1.4
0.4
TRANSMITTER OUTPUT POWER
vs. GC VOLTAGE AND FREQUENCY
IM3 LEVELS (dBc)
1.6
-3
LIMITER INPUT POWER (dBm, 50Ω)
0
-10
-20
TA = +85°C
-30
TA = -40°C
-40
-50
TA = +25°C
-60
0
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
GC VOLTAGE (V)
6
1.8
0.6
TA = +85°C
-5
-120 -100
MAX2510toc11
TA = -40°C
3
2.0
MAX2510toc10
1.6
4
RSSI VOLTAGE (V)
1.8
0.8
5
MAX2510toc10a
2.0
RSSI OUTPUT VOLTAGE
vs. RXIN INPUT POWER
RSSI RELATIVE ERROR vs. LIMIN INPUT
POWER AND TEMPERATURE
MAX2510toc12a
RSSI OUTPUT VOLTAGE vs. LIMIN INPUT
POWER AND TEMPERATURE
RSSI VOLTAGE (V)
MAX2510
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
0 0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
GC VOLTAGE (V)
_______________________________________________________________________________________
0
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
0.4
-14
TA = -40°C
0.2
-16
-18
-20
-22
-24
-26
50
SIDEBAND SUPPRESSION (dB)
TA = +85°C
GC = OPEN
-12
OUTPUT POWER (dBm)
TA = +25°C
MAX2510toc16
0.8
OUTPUT POWER (dBm)
-10
MAX2510toc15
1.0
0.6
TRANSMITTER SIDEBAND SUPPRESSION
vs. RF FREQUENCY
OUTPUT POWER
vs. BASEBAND INPUT VOLTAGE
MAX2510toc17
TRANSMITTER OUTPUT POWER
vs. SUPPLY VOLTAGE
40
30
20
10
-28
0
3.5
4.0
4.5
5.0
5.5
50
100
150
200
250
300
350
0
400
200
400
600
800
1000
SUPPLY VOLTAGE (V)
BASEBAND INPUT VOLTAGE (mVp)
RF FREQUENCY (MHz)
TRANSMITTER DIFFERENTIAL
OUTPUT IMPEDANCE vs. FREQUENCY
TRANSMIT NOISE POWER
vs. GC VOLTAGE
TRANSMITTER OUTPUT POWER
vs. LO POWER
-200
-300
-400
Tx OFF
IMAGINARY
-500
Tx MODE
IMAGINARY
-600
-700
-13.0
-138
-140
-142
-144
-146
-148
-13.5
-14.0
-14.5
-15.0
-15.5
-16.0
-16.5
-150
-17.0
-900
-152
-17.5
-1000
-154
-800
200
300
400
FREQUENCY (MHz)
500
MAX2510toc20
Af = 200kHz
-136
OUTPUT POWER (dBm)
Tx OFF REAL
-100
-134
MAX2510toc19
Tx MODE REAL
OUTPUT NOISE POWER (dBm/Hz)
0
3.0
MAX2510toc18
REAL AND IMAGINARY IMPEDANCE (Ω)
100
0
-30
2.5
-18.0
0
0.2 0.4 0.6 0.8 1.0 1.2 1.4 1.6 1.8 2.0
GC VOLTAGE (V)
-20 -18 -16 -14 -12 -10 -8
-6
-4
-2
0
LO POWER (dBm)
_______________________________________________________________________________________
7
MAX2510
____________________________ Typical Operating Characteristics (continued)
(MAX2510 EV kit; VCC = +3.0V; 0.01µF across CZ and CZ; MIXOUT tied to VREF through 165Ω resistor; TXOUT and TXOUT loaded
with 100Ω differential; LO terminated with 50Ω; LO AC grounded; GC open; LIMOUT, LIMOUT open; 330pF at RSSI pin; 0.1µF connected from VREF pin to GND; PRXIN, RXIN = -30dBm differentially driven (input matched); fRXIN, RXIN = 240MHz; bias voltage at I, I,
Q, Q = 1.4V; VI,Q = 500mVp-p; f I, Q = 200kHz; fLO, LO = 230MHz; PLO = -13dBm; TA = +25°C; unless otherwise noted.)
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
MAX2510
Pin Description
8
PIN
NAME
FUNCTION
1
LIMIN
2, 3
CZ, CZ
4
RSSI
5
GC
6, 9
LO, LO
7
GND
Local-Oscillator Input Ground. Connect to PC board ground plane with minimal inductance.
Limiter Input. Connect a 330Ω (typical) resistor to VREF for DC bias, as shown in the Typical Operating
Circuit.
Offset-Correction Capacitor Pins. Connect a 0.01µF capacitor between CZ and CZ.
Received Signal-Strength Indicator Output. The voltage on RSSI is proportional to the signal power at
LIMIN. The RSSI output sources current pulses into a 330pF (typical) external capacitor. This output is
internally terminated with 11kΩ, and this RC time constant sets the decay time.
Gain-Control Pin. Applying a DC voltage to GC between 0V and 2.0V adjusts the transmitter gain by
more than 40dB. GC is internally terminated to 1.35V via an 85kΩ resistor.
Differential LO Inputs. In a typical application, externally terminate LO with 50Ω to ground, then AC couple into LO. AC terminate LO directly to ground for single-ended operation, as shown in the Typical
Operating Circuit.
8
VCC
Local-Oscillator Input VCC Pin. Bypass directly to local-oscillator input ground (pin 8).
10
GND
Limiter Ground. Connect to PC board ground plane with minimal inductance.
11
TXEN
Transmitter-Enable Pin. When high, TXEN enables the transmitter if RXEN is low. If both TXEN and
RXEN are high, the part is in standby mode; if both are low, the part is in shutdown. See the Power
Management section for details.
12
RXEN
Receiver Enable Pin. When high, RXEN enables the receiver if TXEN is low. If both RXEN and TXEN are
high, the part is in standby mode; if both are low, the part is in shutdown. See the Power Management
section for details.
13, 14
LIMOUT,
LIMOUT
Differential Outputs of the Limiting Amplifier. These outputs are complementary emitter followers capable
of driving 250Ω single-ended loads to ±300mV.
15, 16
I, I
Baseband In-Phase Inputs. The differential voltage across these inputs forms the quadrature modulator’s
I-channel input. The signal input level is typically up to 500mVp-p centered around a 1.4V (typical) DC
bias level on I.
17, 18
Q, Q
Baseband Quadrature-Phase Inputs. The differential voltage across these inputs forms the quadrature
modulator’s Q-channel input. The signal input level is typically up to 500mVp-p, centered around a 1.4V
(typical) DC bias level on Q.
19, 21
VCC
General-Purpose VCC Pins. Bypass with a 0.047µF low-inductance capacitor to GND.
20
GND
Receiver/Transmitter Ground. Connect to PC board ground plane with minimal inductance.
22, 25
RXIN,
RXIN
Differential Inputs of the Downconverter Mixer. An impedance-matching network may be required in
some applications. See the Applications Information section for details.
23, 24
TXOUT,
TXOUT
26
GND
27
MIXOUT
28
VREF
Differential Outputs of the Upconverter. In a typical application, these open-collector outputs are pulled
up to VCC with two external inductors and AC coupled to the load. See the Applications Information section for more details, including information on impedance matching these outputs to a load.
Receiver Mixer Ground. Connect to PC board ground plane with minimal inductance.
Single-Ended Output of the Downconverter Mixer. This pin is high-impedance and must be biased to the
VREF pin through an external terminating resistor whose value depends on the interstage filter characteristics. See the Applications Information section for details.
Reference Voltage Pin. VREF provides an external bias voltage for the MIXOUT and LIMIN pins. Bypass
this pin with a 0.1µF capacitor to ground. The VREF voltage is equal to VCC / 2. See the Typical
Operating Circuit for more information.
_______________________________________________________________________________________
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
MAX2510
IF BPF
LIMIN
VREF
MIXOUT
CZ
CZ
OFFSET
CORRECTION
RXIN
LIMITER
gm
LIMOUT
RXIN
LIMOUT
VREF = VCC / 2
LO
LO
RXEN
TXEN
RSSI
RSSI
POWER
MANAGEMENT
I
GC
I
VGA
TXOUT
Σ
PA
0°
90°
LO PHASE
SHIFTER
MAX2510
TXOUT
Q
TRANSMIT VGA/PA
Q
Figure 1. Functional Diagram
_______________Detailed Description
The following sections describe each of the blocks
shown in Figure 1.
Receiver
The receiver consists of two basic blocks: the downconverter mixer and the limiter/received-signal-strength
indicator (RSSI) section.
The receiver inputs are the RXIN and RXIN pins, which
should be AC coupled and may require a matching
network as shown in the Typical Operating Circuit. To
design a matching network for a particular application,
consult the RXIN Input Impedance plots in the Typical
Operating Characteristics, as well as the Applications
Information sections.
Downconverter Mixer
The downconverter consists of an a double-balanced
mixer and an output buffer. The MIXOUT output, a singleended current source, can drive a shunt-terminated
330Ω filter (165Ω load) to more than 2Vp-p over the
entire supply range, providing excellent dynamic
range. The local oscillator (LO) input is buffered and
drives the mixer.
Limiter
The signal passes through an external IF bandpass filter into the limiter input (LIMIN). LIMIN is a singleended input that is biased at the VREF pin voltage. The
open-circuit input impedance is typically greater than
10kΩ to VREF. For proper operation, LIMIN must be
tied to VREF through the filter-terminating impedance
(which should be less than 1kΩ). The limiter provides a
constant output level, which is largely independent of
the limiter input signal level over a 90dB input range.
The low-impedance limiter outputs provide 600mVp-p
single-ended swing (1.2Vp-p differential swing) and
can drive CMOS inputs directly.
_______________________________________________________________________________________
9
MAX2510
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
Received Signal-Strength Indicator
The RSSI output provides a linear indication of the
received power level on the LIMIN input. The RSSI
monotonic dynamic range exceeds 90dB while providing better than 80dB linear range. The RSSI output
pulses current into a 330pF (typical) external filter
capacitor. The output is internally terminated to ground
with 11kΩ, and this R-C time constant sets the decay
time. The rise time is limited by the RSSI pin’s output
drive current. The rise time is typically less than 100ns
with no capacitor connected. Larger capacitor values
slow the rise time.
Transmitter
The I, I and Q, Q baseband signals are input to a pair
of double-balanced mixers, which are driven from a
quadrature LO source. The quadrature LO is generated
on-chip from the oscillator input present at the LO and
LO pins. The two mixers’ outputs are summed. With
quadrature baseband inputs at the I, I and Q, Q pins,
the unwanted sideband is largely canceled. The resulting signal from the mixers is fed through a variable-gain
amplifier (VGA) with more than 40dB of gain-adjust
range.
The VGA output is connected to a driver amplifier with
an output 1dB compression point of +2dBm. The output power can be adjusted from approximately +2dBm
to -40dBm by controlling the GC pin. The resulting signal appears as a differential output on the TXOUT and
TXOUT pins.
TXOUT and TXOUT are open-collector outputs and
need external pull-up inductors to VCC for proper operation, as well as a DC block so the load does not affect
DC biasing. A shunt resistor across TXOUT and TXOUT
(100Ω typical) can be used to back terminate an external filter, as shown in the Typical Operating Circuit.
Alternatively, a single-ended load can be connected to
TXOUT, as long as TXOUT is tied directly to VCC. Refer
to the Applications Information section for details.
Local-Oscillator Inputs
The MAX2510 requires an external LO source for the
mixers. LO and LO are high-impedance inputs (>1kΩ).
The external LO signal is buffered internally and fed to
both the receive mixer and the LO phase shifter used
for the transmit mixers.
In a typical application, externally terminate the LO
source with a 50Ω resistor and then AC couple into LO.
Typically, the LO power range should be -13dBm to
10
0dBm (into 50Ω). Connect a bypass capacitor from LO
to ground. Alternatively, a differential LO source (externally terminated) can drive LO and LO through series
coupling capacitors.
Power Management
To provide advanced system power management, the
MAX2510 features four operating modes that are
selected via the RXEN and TXEN pins, according to
Table 1 (supply currents assume GC = 0.5V).
In shutdown mode, all part functions are off. Standby
mode allows fastest enabling of either transmit or receive
mode by keeping the VREF generator active. This avoids
delays in stabilizing the limiter input circuitry and the offset correction loop. Transmit mode enables the LO
buffer, LO phase shifter, upconverter mixer, transmit
VGA, and transmit output driver amplifier. Receive mode
enables the LO buffer, downconverter mixer, limiting
amplifier, and RSSI functions.
Table 1. Power-Supply Mode Selection
TXEN
STATE
MODE
TYPICAL
SUPPLY
CURRENT (A)
Low
Low
Shutdown
0.2µ
Low
High
Transmit
17m
RXEN
STATE
High
Low
Receive
14m
High
High
Standby
0.5m
__________Applications Information
RX Input Matching
The RXIN, RXIN port typically needs an impedance
matching network for proper connection to external circuitry, such as a filter. See the Typical Operating Circuit
for an example circuit topology. Note that the receiver
input can be driven either single-ended or differentially.
The component values used in the matching network
depend on the desired operating frequency as well as
on filter impedance. The following table indicates the
RXIN, RXIN single-ended input impedance (that is,
the impedance looking into either RXIN or RXIN). The
information in Table 2 is also plotted in the Typical
Operating Characteristics.
______________________________________________________________________________________
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
FREQUENCY
(MHz)
SERIES IMPEDANCE
(Ω)
100
275 - j203
200
149 - j184
300
94 - j143
400
64 - j109
500
53 - j87
Receive IF Filter
The interstage filter, located between the MIXOUT pin
and the LIMIN pin, is typically a three-terminal, 330Ω,
10.7MHz bandpass filter. This filter prevents the limiter
from acting on any undesired signals that are present
at the mixer’s output, such as LO feedthrough, out-ofband channel leakage, and spurious mixer products.
The filter connections are also set up to feed DC bias
from VREF into LIMIN and MIXOUT through two 330Ω
filter-termination resistors. (See the Typical Operating
Circuit for more information).
Transmit Output Matching
The transmit outputs, TXOUT and TXOUT, are opencollector outputs and therefore present a high
impedance.
For differential drive, TXOUT and TXOUT are connected
to VCC via chokes, and each side is AC coupled to the
load. A terminating resistor between TXOUT and
TXOUT sets the output impedance. This resistor provides a stable means of matching to the load.
TXOUT and TXOUT are voltage-swing limited, and
therefore cannot drive the specified maximum power
across more than 150Ω load impedance. This load
impedance typically consists of a shunt-terminating
resistor in parallel with a filter load impedance. To drive
higher output load impedances, the gain must be
reduced (via the GC pin) to avoid saturating the TX output stage.
For single-ended applications, connect the unused TX
output output pin directly to VCC.
noise amplifier (LNA) that can operate over the same
supply voltage range. The MAX2630–MAX2633 family
of amplifiers meets this requirement. In many applications, the MAX2510’s transmit output power is sufficient
to eliminate the need for an external power amplifier.
______________________Layout Issues
A well-designed PC board is an essential part of an RF
circuit. Use the MAX2510 evaluation kit and the recommendations below as guides to generate your own
layout.
Power-Supply Layout
A star topology, which has a heavily decoupled central
VCC node, is the ideal power-supply layout for minimizing coupling between different sections of the chip. The
VCC traces branch out from this node, each going to
one VCC connection in the MAX2510 typical operating
circuit. At the end of each of these traces is a bypass
capacitor that presents low impedance at the RF frequency of interest. This method provides local decoupling at each VCC pin. At high frequencies, any signal
leaking out of a supply pin sees a relatively high impedance (formed by the VCC trace impedance) to the central VCC node, and an even higher impedance to any
other supply pin, minimizing Vcc supply-pin coupling.
A single ground plane suffices. Where possible, multiple parallel vias aid in reducing inductance to the
ground plane.
Place the VREF decoupling capacitor (0.1µF typical) as
close to the MAX2510 as possible for best interstage filter performance. For best results, use a high-quality,
low-ESR capacitor.
Matching/biasing networks around the receive and
transmit pins should be symmetric and as close to the
chip as possible. A cutout in the ground plane under
the matching network components can be used to
reduce parasitic capacitance.
Decouple pins 19 and 21 (VCC) directly to pin 20 (Rx,
Tx ground), which should be directly connected the
ground plane. Similarly, decouple pin 8 directly to pin 7.
Refer to the Pin Description table for more information.
400MHz ISM Applications
The MAX2510 can be used as a front-end IC in applications where the RF carrier frequency is in the
400MHz ISM band. In this case, Maxim recommends
preceding the MAX2510 receiver section with a low-
______________________________________________________________________________________
11
MAX2510
Table 2. RXIN or RXIN Input Impedance
Low-Voltage IF Transceiver with
Limiter/RSSI and Quadrature Modulator
MAX2510
Typical Operating Circuit
VCC
100pF
FOR SINGLE-ENDED
TX OPERATION
VCC
220nH
100Ω
23
TXOUT
I
I
TX OUTPUT
(TO FILTER)
Q
24
MAX2510
TXOUT
Q
0.001µF
25
MATCH
LIMOUT
RXIN
LIMOUT
10pF
FOR SINGLE-ENDED
RX OPERATION
RXEN
22
TXEN
RXIN
15
BASEBAND
I INPUT
16
18
BASEBAND
Q INPUT
17
13
RECEIVE IF
OUTPUT
14
12
CONTROL
LOGIC
11
VCC
330pF
VCC LO
8
0.001µF
GNDLO
26
GND
LOIN
VCC
VCC
21
LOIN
VCC
GND
19
0.001µF
VCC
GC
0.001µF
20
27
7
RSSI
GND
CZ
6
9
47pF
10
47pF
5
GAIN CONTROL
4
0.001µF
3
RSSI OUTPUT
MIXOUT
LIMIN
10.7MHz
BpF, Z0 = 330Ω
1
VREF
28
330pF
CZ
2
0.01µF
IF
BYPASS
FILTER
330Ω
330Ω
0.1µF
12
FROM
LOCAL
OSCILLATOR
5OΩ
______________________________________________________________________________________