MAXIM MAX2402

19-0392; Rev 1; 5/96
NUAL
KIT MA
ATION
U
EET
L
H
A
S
V
A
E
T
WS DA
FOLLO
800MHz to 1000MHz Transmitter
________________________Applications
Direct-Sequence Spread-Spectrum Transmitter
Frequency-Hopping Spread-Spectrum
Transmitter
FSK, GMSK, BPSK, and ASK Digital Transmitter
AM and FM Analog Transmitter
________________Functional Diagram
VGC
MODULATION
BUFFER
MOD
LO-
MIXER
OUT
VGC
LO INPUT
BUFFER
LO+
POWER
AMPLIFIER
MASTER BIAS
____________________________Features
♦ Low-Cost, Flexible Transmitter
♦ More than 100mW of Output Power into 50Ω
♦ Operates from 800MHz to 1000MHz
♦ Single +5V Supply
♦ 20-Pin SSOP Package
♦ Uses Less than 2µA in Power-Down
♦ More than 35dB of Power Adjustment Range
♦ LO Input Power Range from -6dBm to +6dBm
♦ 2V Linear Range on Modulation Input
______________Ordering Information
PART
TEMP. RANGE
PIN-PACKAGE
MAX2402EAP*
-40°C to +85°C
20 SSOP
* An alternate marking, MAX2402CAP, has been identically tested.
__________________Pin Configuration
TOP VIEW
VGC
1
20 GND
MOD
2
19 VCC
GND
3
18 GND
VCC
4
17 GND
GND
5
LO+
6
15 GND
LO-
7
14 OUT
GND
8
13 GND
SHDN
9
12 VCC
MAX2402
BADJ 10
16 OUT
11 LGND
SHDN
BADJ
SSOP
________________________________________________________________ Maxim Integrated Products
1
For free samples & the latest literature: http://www.maxim-ic.com, or phone 1-800-998-8800
MAX2402
_______________General Description
The MAX2402 transmitter integrates a double-balanced
mixer, buffered local oscillator (LO) port, variable gain
stage, and power amplifier into a single IC. It is intended for use in the 800MHz to 1000MHz band, and is
compatible with both direct-sequence and frequencyhopping spread-spectrum designs in the 902MHz to
928MHz ISM band.
In a typical application, a digital baseband signal is
mixed with a local oscillator signal to yield a BPSKmodulated carrier at the antenna. Alternatively, the
baseband input may be grounded and an FSKmodulated LO signal applied directly to the LO port.
The LO port consists of a limiting amplifier that can
accept a single-ended or differential signal with input
power between -6dBm and +6dBm in the 800MHz to
1000MHz frequency range. The baseband modulation
input is linear over a 2V range, and limits with larger
signal levels within the supply range. The doublebalanced mixer has been optimized for high carrier
rejection. The variable gain stage offers typically 40dB
of adjustment range. The power amplifier provides
more than 20dBm output power and has a bias adjustment, which allows adjustment of efficiency and
harmonic distortion.
A shutdown function reduces the current draw to less
than 2µA in less than 10µs. The MAX2402 comes in a
20-pin SSOP package to minimize board area.
MAX2402
800MHz to 1000MHz Transmitter
ABSOLUTE MAXIMUM RATINGS
Operating Temperature Range ...........................-40°C to +85°C
Storage Temperature Range .............................-65°C to +160°C
Lead Temperature (soldering, 10sec) .............................+300°C
VCC ........................................................................-0.3V to +6.5V
Continuous Power Dissipation (TA = +70°C)
SSOP (derate 16.7mW/°C above +70°C) ......................1.33W
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 = 4.75V to 5.5V, BADJ = open, SHDN = VCC - 0.5V, VGC = VCC, MOD = open, TA = -40°C to +85°C, unless otherwise noted.)
PARAMETER
Supply Current
Shutdown Supply Current
SYMBOL
ICC
ICCPD
Supply Voltage Range
VCC
VGC Input Bias Current
IVGC
MOD Bias Current
IMOD
SHDN Bias Current
IPD
SHDN Low Threshold
VSHDN Low
SHDN High Threshold
VSHDN High
CONDITIONS
MIN
TYP
Not transmitting
105
SHDN = 0.5V
0.15
4.75
VGC = VCC
MOD = VCC
MAX
mA
2
V
115
µA
-320
SHDN = VCC
µA
5.50
325
MOD = 0V
UNITS
µA
10.5
µA
0.5
V
VCC - 0.5
V
AC ELECTRICAL CHARACTERISTICS
(MAX2402 evaluation kit, VCC = 5.0V, BADJ = 2V, SHDN = VCC, MOD = 0V, VGC = VCC, RLOAD = 35Ω, fLO = 900MHz,
LO power = -3dBm, TA = -40°C to +85°C, unless otherwise noted.)
SYMBOL
CONDITIONS
Supply Current
PARAMETER
ICCAC
POUT = 20dBm (including current to load)
165
mA
Maximum Output Power
PMAX
(Note 1)
21
dBm
Minimum Output Power
PMIN
VGC = 0V (Note 1)
-19
dBm
Power Gain from LO
PGAIN
24
dB
LO Input Power Range
LO Frequency Range
PLO
For max power out (50Ω input term)
(Note 2)
MIN
TYP
MAX
UNITS
-6
6
dBm
800
1000
MHz
25
MHz
fLO
(Note 2)
MODBW
(Note 2)
VGC Control Range
VGC
(Note 2)
Carrier Suppression
CS
MOD = 5Vp-p @ 100kHz
30
dBC
2nd Harmonic Suppression
HS2
(Note 1)
22
dBC
3rd Harmonic Suppression
HS3
(Note 1)
25
dBC
Output IP3 (BADJ = 1.0V)
IP3
fLO = 900MHz + 901MHz
28.4
dBm
MOD Usable Bandwidth
1.0
2.5
Note 1: See Typical Operating Characteristics graphs.
Note 2: Guaranteed by design.
2
_______________________________________________________________________________________
V
800MHz to 1000MHz Transmitter
OUTPUT POWER vs. FREQUENCY
vs. TEMPERATURE
10
5
0
-5
-10
22.0
MAX2402 TOC 2
+24°C
23
OUTPUT POWER (dBm)
15
-40°C
OUTPUT POWER (dBm)
20
+85°C
21
19
17
-15
21.5
21.0
20.5
-20
900MHz INPUT
15
800 820 840 860 880 900 920 940 960 980
2.5
2.0
1.5
OUTPUT POWER vs. BIAS CONTROL VOLTAGE
vs. FREQUENCY
800MHz
23
900MHz
21
19
17
990MHz
15
13
11
10
-10
30
50
70
90
TEMPERATURE (°C)
260
240
SUPPLY CURRENT (mA)
OUTPUT POWER (dBm)
-30
SUPPLY CURRENT vs. BIAS CONTROL VOLTAGE
vs. FREQUENCY
MAX2402 TOC 4
25
800MHz
220
200
900MHz
180
990MHz
160
140
120
9
7
100
0
1
2
3
4
5
0
1
2
4
3
5
BADJ VOLTAGE (V)
BADJ VOLTAGE (V)
AMPLITUDE OF 3rd & 5th HARMONICS
OF MODULATED WAVEFORM
OUTPUT POWER LEVEL OF
2nd AND 3rd HARMONICS OF LO
TA = -40°C
10
1.0 1.5
2.0 2.5
3.0 3.5
4.0
4.5 5.0
MODULATION VOLTAGE, PEAK-TO-PEAK (V)
(LO = 900MHz, -3dBm, MOD = 5V)
OUTPUT POWER BELOW FUNDAMENTAL (dBC)
MAX2402 TOC 7
(100kHz SINEWAVE MODULATION OF 900MHz LO)
42
TA = +85°C
38
TA = +24°C
34
900.5MHz
30
TA = -40°C
26
TA = +85°C
22
900.3MHz
18
TA = +24°C
14
-50
FREQUENCY (MHz)
VGC (V)
39
37
35
33
31
29
27
25
23
21
19
17
15
13
MAX2402 TOC 6
1.0
20.0
MAX2402 TOC 5
-25
OUTPUT POWER (dBC) BELOW 900.1MHz
OUTPUT POWER (dBm)
25
MAX2402 TOC 1
25
OUTPUT POWER vs.
TEMPERATURE
MAX2402 TOC 3
OUTPUT POWER vs.
GAIN CONTROL VOLTAGE
3rd HARMONIC T = -40°C
A
TA = +24°C
TA = +85°C
TA = +85°C
2nd HARMONIC
TA = +24°C
TA = -40°C
0.5
1.0
1.5
2.0
2.5
3.0
3.5
4.0
BADJ VOLTAGE (V)
_______________________________________________________________________________________
3
MAX2402
__________________________________________Typical Operating Characteristics
(MAX2402 evaluation kit, VCC = 5.0V, BADJ = 2V, SHDN = VCC, MOD = 0V, VGC = VCC, RLOAD = 35Ω, fLO = 900MHz,
LO power = -3dBm)
MAX2402
800MHz to 1000MHz Transmitter
_____________________Pin Description
PIN
NAME
FUNCTION
1
VGC
Variable Gain Control Input.
Connect to VCC for maximum gain.
2
MOD
Baseband Modulation Input to mixer
3, 5, 8,
13, 15, 17,
18, 20
GND
Ground
4, 12, 19
VCC
Supply Voltage, set between 4.75V
and 5.5V
6
LO+
Local-Oscillator Positive Input
7
LO-
Local-Oscillator Negative Input
9
SHDN
Shutdown Control Input.
Low level = off, high level = on.
10
BADJ
Bias Adjustment Control for power
amplifier. Connect resistor from
BADJ to V+ or GND (see Table 1).
11
LGND
Connect 27nH inductor from LGND
to GND to maximize output power.
14, 16
OUT
Power-Amplifier Output
_______________Detailed Description
The MAX2402 transmitter is a versatile design that integrates several RF functions on a single IC. It has a wide
variety of applications in portable and stationary wireless designs. Each of the functional blocks (shown in
the Functional Diagram) is described in detail in the following sections.
LO Inputs
The LO inputs are internally capacitively coupled and
self biasing. The LO port can be driven differentially or
single ended. When terminated at the LO inputs with
50Ω, the transmitter will provide full output power for LO
inputs from -6dBm to +6dBm with single-ended drive,
and -12dBm to +6dBm with differential drive. Input
power beyond this range may saturate the LO input
buffer, while input power below this range may result in
less output power. The limiter is two cascaded differential stages, which also isolates the LO input from the
mixer. This will help reduce any frequency-pulling
effects in an external LO due to mixer loading. The limiter output drives one port of a double-balanced Gilbert
mixer.
4
MOD Input
The mixer’s other port, the MOD input, remains linear
over a 2V range from about 1.5V to 3.5V at the input.
When driven with digital modulation (0V to 5V), this port
will completely limit, resulting in a hard BPSKmodulated signal. Since this input is self biasing, carrier
suppression can be improved by externally capacitively
coupling the signal into the port (the MOD input resistance is approximately 10kΩ). This would compensate
for voltage offset or duty-cycle offset at this port, thus
increasing carrier suppression. This MOD self bias is
designed for very low on-chip offset, resulting in excellent carrier suppression. Since this port self biases
when the signal is removed from MOD, the mixer will
attenuate the output power by about 40dB, resulting in
further attenuation past that attained from VGC control—a useful feature for ASK modulation.
VGC Stage
The mixer output drives the VGC stage. This stage
attenuates through a multiplication technique that does
not distort the signal with increased attenuation. VGC
control is nonattenuating when connected to the V CC
supply. VGC will attenuate for voltages from 2.5V to
1.0V. Most attenuation occurs between 1V and 2V.
Maximum attenuation is achieved below 0.8V. Typical
maximum attenuation is 40dB. At or beyond 40dB of
attenuation, the signal may be slightly nonmonotonic.
This means that there may be a slight upturn in the signal level at the low end of the VGC control range (typically about 1dB). Because of the stability implications,
we suggest that the user not plan on attenuating past
35dB within a feedback loop.
Power Amplifier
The VGC stage passes the signal to the power amplifier. This class AB stage will produce at least 20dBm of
output power for almost the complete transmit frequency range (with T A = +25°C). See Typical Operating
Characteristics.
BADJ Input
The BADJ input adjusts the bias of the output stage.
Increasing this voltage decreases bias current in the
output devices, which increases efficiency, but also
increases harmonic distortion (since the stage will be
pushed further toward class B operation). Decreasing
BADJ’s voltage increases bias current in the output
devices, resulting in higher output power and less harmonic distortion. Be sure to optimize BADJ for your
application.
_______________________________________________________________________________________
800MHz to 1000MHz Transmitter
Table 1. Bias-Adjust Voltage for Various
Resistor Values
Resistor
Value (Ω)
BADJ with Resistor
Connected to GND (V)*
BADJ with Resistor
Connected to VCC (V)
Power Amplifier Output
The power amplifier has an open-collector output that
can drive into a load of 30Ω to 50Ω; however, maximum
power transfer is obtained at about 35Ω. 27nH to
ground is recommended on LGND (pin 11), as shown
in the Typical Application Circuit. This inductor is used
as a current source on the base of the output stage to
pull stored charge out of the base.
SHDN Input
The SHDN input completely shuts down the current
from the supply and all signal pins when switched
below 0.5V. During normal operation, SHDN should
remain above VCC - 0.5V.
The shutdown control shuts down the total current to
below 150nA (typ). Power-up occurs within 10µs.
__________Applications Information
The MAX2402 transmitter operates within the 800MHz
to 1000MHz frequency range. Figure 1 shows a typical
application circuit. Additional applications information
can be obtained from the MAX2402 evaluation kit
manual.
VARIABLE
GAIN CONTROL
MODULATION
0.36
4.54
20k
0.63
4.27
30k
0.84
4.05
40k
1.00
3.89
39pF
1.13
3.75
100k
1.54
3.34
200k
1.89
3.00
300k
2.05
2.85
400k
2.13
2.75
500k
2.20
2.68
1M
2.31
2.57
* Typical variation of BADJ over temperature and process is
less than 5%.
2
4
5
GND
VCC
19
MOD
VCC
GND
GND
VCC
GND
GND
MAX2402
18
39pF
0.01µF
17
16
OUT
50Ω
6
VCO
50k
20
VGC
3
VCC
10k
1
7
LO+
GND
LO-
OUT
GND
GND
15
VCC
47nH
14
50Ω
8
SHUTDOWN
CONTROL
9
SHDN
VCC
BADJ
LGND
10
300k
13
12
39pF
VCC
11
27nH
Figure 1. Typical Application Circuit
_______________________________________________________________________________________
5
MAX2402
BADJ can be left open or adjusted with a single pullup or pull-down resistor to VCC or GND, respectively.
The value of this resistor determines the amount of
adjustment applied. A single resistor results in no current flow at BADJ during power-down (whereas a
resistor divider always has current flowing through the
resistors). Table 1 shows the approximate bias adjust
voltage at the pin for different resistor values. At lower
LO frequencies, where the transmitter gain and output
power is the highest, setting BADJ to a low voltage
(maximum bias current) causes excessive current in
the output and can cause unstable behavior in the IC.
At lower LO frequencies (around 800MHz), more than
22dBm of power is easily obtained with BADJ set for
3V or more. If higher bias current and less distortion is
desired in the 800MHz range, using a lower inductor
value on LGND (pin 11) (see the Typical Application
Circuit) might make the desired bias level stable. At
higher frequencies (near 1000MHz), a lower bias level
voltage results in more power (see the Output Power vs.
Bias Control Voltage vs. Frequency graph in the Typical
Operating Characteristics).
MAX2402
800MHz to 1000MHz Transmitter
________________________________________________________Package Information
DIM
A
A1
B
C
D
E
e
H
L
α
e
E
H
INCHES
MAX
MIN
0.078
0.068
0.008
0.002
0.015
0.010
0.009
0.005
0.289
0.278
0.212
0.205
0.0256 BSC
0.311
0.301
0.037
0.022
8˚
0˚
MILLIMETERS
MIN
MAX
1.73
1.99
0.05
0.21
0.25
0.38
0.13
0.22
7.07
7.33
5.20
5.38
0.65 BSC
7.65
7.90
0.55
0.95
0˚
8˚
21-0003A
D
α
A
0.127mm
0.004in.
B
6
A1
C
L
20-PIN SSOP
SHRINK
SMALL OUTLINE
PACKAGE
_______________________________________________________________________________________