HP HPMX-2003 Silicon bipolar rfic 900 mhz vector modulator Datasheet

Silicon Bipolar RFIC
900 MHz Vector Modulator
Technical Data
HPMX-2003
Features
Plastic SO-16 Package
• 800–1000 MHz Output
Frequency Range
• +6 dBm Peak Pout
• Unbalanced 50 Ω Output
• Internal 90° Phase Shifter
• 5 Volt, 36 mA Bias
• SO-16 Surface Mount Package
Pin Configuration
Applications
• Direct Modulator for 900
MHz Cellular Telephone
Handsets, Including GSM,
JDC, and NADC
• Direct Modulator for
900␣ MHz ISM Band SpreadSpectrum Transmitters and
LANs
V CC 1
16 VCCL
V CC 2
15 RFout
GROUND 3
14 GROUND
GROUND 4
13 GROUND
12 Iref
Qref 5
11 Imod
Qmod 6
LOin 7
10 GROUND
9 DO NOT CONNECT
LOgnd 8
Functional Block Diagram
I MIXER
Imod
Iref
VCC
VCCL
0°
LO +
LO –
φ
Σ
PHASE
SHIFTER
SUMMER
•
RFout
50 Ω ZO
unbalanced
OUTPUT
AMPLIFIER
90°
Qref
Qmod
5965-9103E
Q MIXER
7-38
Description
Hewlett Packard’s HPMX-2003 is a
Silicon RFIC direct conversion
vector modulator designed for use
at output frequencies between
800␣ MHz and 1 GHz. Housed in a
SO-16 surface mount plastic package, the IC contains two matched
Gilbert cell mixers, an RC phase
shifter, a summer, and an output
amplifier complete with 50 Ω
impedance match and DC block.
This device is suitable for use in
direct and offset-loop modulated
portable and mobile telephone
handsets for cellular systems such
as GSM, North American Digital
Cellular and Japan Digital Cellular. It can also be used in digital
transmitters operating in the
900 MHz ISM (Industrial-Scientific-Medical) band, including use
in Local Area Networks (LANs).
The HPMX-2003 is fabricated with
Hewlett-Packard’s 25 GHz
ISOSAT-II process, which
combines stepper lithography,
ion-implantation, self-alignment
techniques, and gold metallization
to produce RFICs with superior
performance, uniformity and
reliability.
HPMX-2003 Absolute Maximum Ratings, TA = 25°C
Units
Absolute
Maximum[1]
Pdiss
Power Dissipation[2,3]
mW
500
LOin
LO Input Power
dBm
15
VCC
Supply Voltage
V
10
Vp-p
5[4]
Reference Input Levels[4]
V
5[4]
TSTG
Storage Temperature
°C
-65 to +150
Tj
Junction Temperature
°C
150
Symbol
∆VImod,
∆VQmod
VIref, VQref
Parameter
Swing of VImod about VIref[4]
or VQmod about VQref
Thermal Resistance[2]:
θjc =125°C/W
Notes:
1. Operation of this device above any one
of these parameters may cause
permanent damage.
2. TC = 25°C (TC is defined to be the
temperature at the end of pin 3 where it
contacts the circuit board).
3. Derate at 8 mW/°C for TC > 88°C.
4. Do not exceed VCC by more than 0.8 V.
HPMX-2003 Guaranteed Electrical Specifications, TA = 25°C, ZO = 50 Ω
VCC = 5 V, LO= -12 dBm at 900 MHz (Unbalanced Input), VIref = VQref = 2.5 V (Unless Otherwise Noted).
Symbol
Parameters and Test Conditions
Id
Device Current
Pout
Output Power
LOleak
εmod
Min.
mA
Pout - LO at Output
Typ.
Max.
36
44
VImod = VQmod = 3.75 V
dBm
+4.0
+6
VImod = VQmod = 2.5 V
dBc
+30
+37
√ (V
Average
Modulation
Error
Units
2
2
Imod - 2.5) + (VQmod - 2.5)
= 1.25 V
%
4
7
HPMX-2003 Summary Characterization Information, TA = 25°C, ZO = 50 Ω
VCC = 5 V, LO = -12 dBm at 900 MHz (Unbalanced Input), VIref = VQref = 2.5 V (Unless Otherwise Noted).
Symbol
Rin
Rin-gnd
Parameters and Test Conditions
Units
Typ.
Input Resistance (Imod to Iref or Qmod to Qref)
Ω
10 k
Input Resistance to Ground (Any I, Q Pin to Ground)
Ω
10 k
VSWRLO
LO VSWR (50 Ω)
GSM: 890-915 MHz Bandwidth
NADC: 824-850 MHz Bandwidth
JDC: 940-960 MHz Bandwidth
1.5:1
1.5:1
1.5:1
VSWRO
Output VSWR (50 Ω) (Tuned by
Placement of VccL Capacitor –
See Figures 22, 32, and 42)
GSM: 890-915 MHz Bandwidth
NADC: 824-850 MHz Bandwidth
JDC: 940-960 MHz Bandwidth
1.2:1
1.1:1
1.2:1
Output Noise Floor
VImod = VQmod = 3.75 V
dBm/Hz
-134
DSB Third Order Intermodulation Products
dBc
+34
Ai
RMS Amplitude Error
dB
0.3
Pi
RMS Phase Error
degrees
2
IM3
7-39
HPMX-2003 Pin
Description
Ground (pins 3, 4, 10, 13 & 14)
These pins should connect with
minimal inductance to a solid
ground plane (usually the backside of the PC board). Recommended assembly employs
multiple plated through via holes
where these leads contact the PC
board.
lar performance. The recommended level of unbalanced I and
Q signals is 2.5 Vp-p with an average level of 2.5 V above ground.
The reference pins should be DC
biased to this average data signal
level (VCC/2 or 2.5 V typ.). For
single ended drive, pins 5 and 12
can be tied together. For balanced
operation, 2.5 Vp-p signals may be
applied across the Imod/Iref and the
Qmod/Qref pairs. The average level
of all four signals should be about
2.5 V above ground. The impedance between any I or Q and
ground is typically 10 K Ω and the
impedance between Imod and Iref or
Qmod and Qref is typically 10 KΩ.
The input bandwidth typically
exceeds 40 MHz. It is possible to
reduce LO leakage through the IC
by applying slight DC imbalances
between Imod and Iref and/or Qmod
and Qref (see section entitled
“HPMX-2003 Using Offsets to Improve Lo Leakage”). All performance data shown on this data
sheet was taken with unbalanced
I/Q inputs.
Iref (pin 12) and Q ref (pin 5),
I␣ (pin 11) and Q (pin 6) Inputs
The I and Q inputs are designed
for unbalanced operation but can
be driven differentially with simi-
LO Input (pins 7 and 8)
The LO input of the HPMX-2003 is
balanced and matched to 50 For
drive from an unbalanced LO, pin
7 should be AC coupled to the LO
VCC (pins 1,2)
These two pins provide DC power
to the mixers in the RFIC, and are
connected together internal to the
package. They should be connected to a 5 V supply, with appropriate AC bypassing (1000 pF typ.)
used near the pins, as shown in
figures 1 and 2. The voltage on
these pins should always be
kept at least 0.8 V more positive than the DC level on any
of pins 5, 6, 11, or 12. Failure to
do so may result in the modulator
drawing sufficient current
through the data or reference
inputs to damage the IC.
using a 50 Ω transmission line and
a blocking capacitor (1000 pF
typ.), and pin 8 should be AC
grounded (1000 pF capacitor
typ.), as shown in figure 1. For
drive from a balanced LO source,
50 Ω transmission lines and blocking capacitors (1000 pF typ.) are
used on both pins 7 and 8, as
shown in figure 2. The internal
phase shifter allows operation
from 800 - 1000 MHz. The recommended LO input level is -12 dBm.
All performance data shown on
this data sheet was taken with unbalanced LO operation.
RF Output (pin15)
The RF output of the HPMX-2003
is configured for unbalanced
operation. The output is internally
DC blocked and matched to 50 Ω,
so a simple 50 Ω microstrip line is
all that is required to connect the
modulator to other circuits.
VCCL (pin 16)
Pin 16 is the VCC input for the output stage of the IC. It is not internally connected to the other VCC
pins. The external connection allows the addition of a small inductor (0 - 6 nH) to tune the output
for minimum VSWR, depending
upon the operating frequency.
1000 pF
1000 pF
+5 V
+5 V
1000 pF
1000 pF
OPTIONAL INDUCTOR
OPTIONAL INDUCTOR
1
16
2
15
3
1
16
2
15
14
3
14
4
13
4
13
Qref
5
12
Iref
Qref
5
12
I ref
Qmod
6
11
Imod
Qmod
6
11
Imod
7
10
8
9
LOin
1000 pF
7
10
8
9
RF out
1000 pF
LOin+
DO NOT CONNECT
LOin–
RFout
DO NOT CONNECT
1000 pF
1000 pF
Figure 2. HPMX-2003 Connections Showing Balanced LO
and I, Q Inputs.
Figure 1. HPMX-2003 Connections Showing Unbalanced LO
and I, Q Inputs.
7-40
HPMX-2003 Typical Data
Measurement
Amplitude and phase are
measured by setting the network
analyzer for an S21 measurement
at frequency of choice. Set the
port 1 stimulus level to the LO
level you intend to use in your circuit (-12 dBm for the data sheet).
A 6-10 dB attenuator can be
placed in the line to port 2 to prevent network analyzer overload,
depending upon the network analyzer you are using.
Direct measurement of the amplitude and phase error at the output
is an accurate way to evaluate
modulator performance. By measuring the error directly, all the
harmonics, LO leakage, etc. that
show up in the output signal are
accounted for. Figure 3, below,
shows the test setup that was used
to create the amplitude and phase
error plots (figures 12 and 13).
By adjusting the VImod and VQmod
settings you can step around the
I, Q vector circle, reading magnitude and phase at each point.
The relative values of phase and
amplitude at the various points
will indicate the accuracy of the
modulator. Note: you must use
very low ripple power supplies
for the reference, VImod, and VQmod
supplies. Ripple or noise of only a
few millivolts will appear as wob-
Amplitude and phase error are
measured by using the four channel power supply to simulate I and
Q input signals. Real 2.5 Vp-p I and
Q signals would swing 1.25 volts
above and below an average 2.5 V
level, therefore, a “high” level input is simulated by applying
3.75␣ V, and a “low” level by applying 1.25 V to the I and/or Q inputs.
HP-8753C VECTOR NETWORK ANALYZER
PORT 2
PORT 1
VQmod
R
C
H
HP-6626A
SYSTEM DC POWER SUPPLY
(FOUR OUTPUTS)
Q
LO
VER 1
HPMX-2003/5
5V
C
V CC
5V
C
C
OUT
2.5 V
VImod
I
R
Figure 3. Test Setup for Measuring Amplitude and Phase Error, Input and Output
VSWR, Power Output and LO Leakage of the Modulator.
7-41
bling phase readings on the network analyzer.
The same test setup shown below
is used to measure input and output VSWR, reverse isolation, and
power vs. frequency. VImod and
VQmod are set to 3.75 V and the
appropriate frequency ranges are
swept. S11 provides input VSWR
data, S22 provides output VSWR
data. S21 provides power output
(add source power to S21 derived
gain).
LO leakage data shown in figures
18, and 19 is generated by setting
VImod = VQmod = VIref = VQref = 2.5 V
then performing an S21 sweep.
Since phase is not important for
these measurements, a scalar network analyzer or a signal generator and spectrum analyzer could
be used.
45
50
42
45
DEVICE CURRENT (mA)
DEVICE CURRENT (mA)
HPMX-2003 Typical Performance
39
36
33
40
35
30
30
25
-55
-35
-15
5
25
45
65
85
4.5
4
5
TEMPERATURE (°C)
5.5
6
V CC (VOLTS)
Figure 4. HPMX-2003 Device Current
vs. Temperature, VCC = 5 V.
Figure 5. HPMX-2003 Device Current
vs. VCC, TA = 25°C.
10
10
10
4.25 V
8
3.75 V
8
6
4
2
4
OUTPUT POWER (dBm)
6
OUTPUT POWER (dBm)
OUTPUT POWER (dBm)
8
3.25 V
2
0
3.0 V
-2
-4
-6
6
4
2
2.75 V
-8
-10
0
-55
-35
-15
5
25
45
65
0
4
85
4.25
4.5
4.75
5
5.25
5.5
5.75
6
-25
V CC (VOLTS)
TEMPERATURE (°C)
Figure 6. HPMX-2003 Power Output
vs. Temperature at 900 MHz,
LO␣ =␣ -12␣ dBm, VImod = VQmod = 3.75 V,
VIref = VQref = 2.5 V, VCC = 5 V.
5:1
4:1
4:1
-15
-10
-5
0
LO INPUT POWER (dBm)
Figure 7. HPMX-2003 Power Output
vs. VCC and I, Q Level at 900 MHz,
LO␣ =␣ -12 dBm, VImod = VQmod, TA = 25°C.
5:1
-20
Figure 8. HPMX-2003 Power Output
vs. LO Level at 900 MHz, VCC = 5 V,
VImod = VQmod = 3.75 V, TA = 25°C.
2:1
3:1
2:1
OUTPUT VSWR
OUTPUT VSWR
INPUT VSWR
1.8:1
3:1
1.4:1
2:1
-55 °C
850
1.2:1
-55 °C
85 °C
1:1
750
1.6:1
950
1050
FREQUENCY (MHz)
Figure 9. HPMX-2003 LO Input VSWR
vs. Frequency and Temperature,
VCC␣ =␣ 5 V.
1:1
750
85 °C
1:1
850
950
1050
FREQUENCY (MHz)
Figure 10. HPMX-2003 Output VSWR
vs. Frequency and Temperature.
7-42
4
4.5
5
5.5
V CC (VOLTS)
Figure 11. HPMX-2003 Output VSWR
vs. VCC at 900 MHz, TA = 25°C.
6
HPMX-2003 Modulation Accuracy (Sample Part)
OUTPUT AMPLITUDE ERROR (dB)
1
0.5
85 °C
-55 °C
0
-0.5
-1
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 12. HPMX-2003 Amplitude Error vs. Input Phase at 900 MHz,
VCC␣ = 5 V, √ (VImod -2.5)2 + (VQmod - 2.5)2 = 1.25 V, LO = -12 dBm.
25°C␣ Curve Deleted for Clarit y.
OUTPUT PHASE ERROR (DEGREES)
4
2
0
-55 °C
-2
85 °C
-4
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 13. HPMX-2003 Output Phase Error vs. Input Phase at 900 MHz,
VCC␣ = 5 V, √ (VImod -2.5)2 + (VQmod - 2.5)2 = 1.25 V, LO = -12 dBm.
25°C Curve Deleted for Clarity.
OUTPUT MODULATION ERROR (%)
8
6
85 °C
4
2
-55 °C
0
0
90
180
270
INPUT PHASE (DEGREES)
Figure 14. Modulation Error vs. Input Phase at 900 MHz, VCC = 5 V,
√ (VImod -2.5) 2 + (VQmod -2.5)2 = 1.25 V, LO = -12 dBm. Percent Modulation
Error is Calculated from the Values of Amplitude and Phase Error.
7-43
360
HPMX-2003 Single and
Double Sideband
Performance
and DSB output spectrum graphs
(figures 15 and 16).
flect the performance of the
modulator IC.
Single sideband (SSB) and double
sideband (DSB) tests are sometimes used to evaluate modulator
performance. Figure 17, below,
shows the test equipment setup
that was used to create the SSB
The phase shift provided by the I
and Q signal generators must be
very close to 90 degrees and the
amplitude of the two signals must
be matched within a few millivolts
or results will not accurately re-
The I, Q signal generator must put
out low distortion signals or the
output spectrum will show high
harmonic levels that reflect the
performance of the signal generator, not the modulator.
HPMX-2003 Typical Sideband Performance Data
SSB: VIref = VQref = 2.5 V, VImod = VIref +1.25 sin (2π f t), VQmod = VQref + 1.25 cos (2π f t), f = 25 kHz
DSB: VIref = VQref = 2.5 V, VImod = VIref +1.25 cos (2π f t), VQmod = VQref + 1.25 cos (2π f t), f = 25 kHz
Symbol
Parameters and Test Conditions
Units
SSB
DSB
Lower Sideband Power Output
dBm
+3
0
LO Suppression
dBc
34
31
PUSB
Upper Sideband Power Output
dBm
-32
0
IM3
Third Order Intermodulation Products
dBm
NA
-34
PLSB
5
5
-5
-5
-15
-15
OUTPUT POWER (dBm)
OUTPUT POWER (dBm)
LOleak
-25
-35
-45
-55
-65
-75
899.9
-25
-35
-45
-55
-65
899.95
900
900.05
-75
899.9
900.1
899.95
FREQUENCY (MHz)
HP-8657B SYNTHESIZED SIGNAL GENERATOR
R
C
H
HPMX-2003/5
Q
LO
VER 1
HP-3245A UNIVERSAL SOURCE
OPT 001
DUAL OUTPUTS WITH 90 DEGREE
RELATIVE PHASE SHIFT
C
V CC
5V
C
C
OUT
SIN
DSB
I
900.05
900.1
Figure 16. Double Sideband Output Spectrum.
LO␣ =␣ -12␣ dBm at 900 MHz. The Test Setup is Shown
in␣ Figure 1 7.
Figure 15. Single Sideband Output Spectrum.
LO␣ =␣ -12␣ dBm at 900 MHz. The Test Setup is Shown
in␣ Figure␣ 1 7.
COS
900
FREQUENCY (MHz)
R
SSB
HP-8595A SPECTRUM ANALYZER
Figure 17. HPMX-2003 Single/Double Sideband Test Setup.
7-44
HP-6626A
SYSTEM DC
POWER SUPPLY
HPMX-2003 Using Offsets
to Improve LO Leakage
It is possible to improve on the
excellent performance of the
HPMX-2003 for applications that
are particularly sensitive to LO
leakage. The nature of the
improvement is best understood
by examining figures 18 and 19,
below.
This improvement is not very useful if it doesn’t hold up over frequency and temperature changes.
The lower curve in figure 18
shows how the offset-adjusted LO
leakage varies versus frequency.
Note that it remains below
-45␣ dBm over most of the frequency range shown. In the
20␣ MHz range centered at
900␣ MHz, the level is closer to
-55␣ dBm.
-20
-20
-35
-30
OUTPUT POWER (dBm)
OUTPUT POWER (dBm)
LO leakage results when normal
variations in the wafer fabrication
process cause small shifts in the
values of the modulator IC’s internal components. These random
variations create an effect equivalent to slight DC imbalances at the
input of each (I and Q) mixer. The
DC imbalances at the mixer inputs are multiplied by ± 1 at the
LO frequency and show up at the
output of the IC as LO leakage.
It is possible to externally apply
small DC signals to the I and Q inputs and exactly cancel the internally generated DC offsets. This
will result in sharply decreased
LO leakage at precisely the frequency and temperature where
the offsets were applied (see figure 18).
-50
-65
-80
-55
-35
-15
5
25
45
65
85
TEMPERATURE (°C)
Figure 18. LO Leakage vs. Frequency
Without DC Offsets (Upper Curve)
and LO Leakage vs. Frequency With
DC Offsets (Adjusted for Minimum LO
Leakage at 900 MHz). TA = 25°C, VCC =
5 V, VIref = VQref = 2.5 V, LO = -12 dBm.
-40
-50
-60
650
750
850
950
1050
1150
FREQUENCY (MHz)
Figure 19. LO Leakage With No DC
Offsets vs. Temperature (Upper
Curve) and LO Leakage With DC
Offsets (Adjusted for Minimum
Leakage at 25°C) vs. Temperature
(Lower Curve). Frequency = 900 MHz,
VCC = 5 V, VIref = VQref = 2.5 V,
LO␣ =␣ -12␣ dBm.
7-45
Figure 19 shows the performance
of the offset adjusted LO leakage
over temperature. Note that the
adjusted curve is at a level below
-50 dBm over most of the temperature range.
The net result of using
externally applied offsets with
the HPMX-2003 is that an LO
leakage level below -40 dBm
can typically be achieved over
both frequency and
temperature.
The magnitude of the required external offset varies randomly from
part to part and between the I and
Q mixers on any given IC. Offsets
can range from -56 mV to +56 mV.
External offsets may be applied
either by varying the average level
of the I and Q modulating signals,
or by varying the voltages at the
Iref and Qref pins of the modulator.
HPMX-2003 Modulation
Spectrum Diagrams
The modulation spectra are created by setting the function generator to the appropriate bit-clock
frequency. The pattern generator
is set to produce a pseudorandom
serial bit stream (n␣ = 20) that is
NRZ coded. The pseudorandom
bit stream which simulates the
serial data in a digital phone is fed
to the base-band processor that
splits it into a two bit parallel
Figure 20, below, shows the test
setup that was used to generate
the modulation spectrum diagrams that appear on the GSM,
JDC and NADC applications pages
of this data sheet. The major differences between the tests are
summarized in the table below.
stream (I and Q) and then filters
each according to the requirements of the digital telephone system being simulated. The I and Q
signals from the baseband filter
are then DC offset by 2.5 V using
the op-amp circuit. The output of
the modulator is monitored using
a spectrum analyzer.
System
Bit Clock Frequency
Baseband Filter
GSM
270 kHz
0.3 GMSK (HP 8657B)
900 MHz
JDC
42 kHz
α = 0.5 π/4 DQPSK (HP 8657D)
950 MHz
NADC
48.6 kHz
α = 0.35 π/4 DQPSK (HP 8657D)
835 MHz
1
H
R
Iref
VER 1
HPMX-2003/5
C
C
HP-8657B
SIGNAL GENERATOR
835-950 MHz
LO
C
HP-8563E
SPECTRUM ANALYZER
C
Q
R
C
OUT
2
Qref
5V
V CC
HP-3314A
FUNCTION
GENERATOR
Q + 2.5 V
π/4DQPSK Q INPUT
+5 V
•
•
–
+
Qref = 2.5 V
HP-3780A
PRBS GENERATOR
ALL R = 5 k
CLOCK
HP-8657B
OR
HP-8657D
BASEBAND
PROCESSOR
OP-AMP: TL-084
I CHANNEL IS IDENTICAL
DATA
I
Q
OP-AMP CIRCUIT
(SEE ABOVE)
I + 2.5 V TO 1
2.5 V TO I ref
Q + 2.5 V TO 2
2.5 V TO Q ref
Figure 20. Test Equipment Setup for Modulation Spectrum Diagrams.
7-46
Channel (LO) Frequency
HPMX-2003 GSM
Applications
The GSM System
GSM (Group Speciale Mobile)
commonly refers to the European
digital cellular telephone system
standard. Digital cellular phones
for the European market must
conform to this standard. The
GSM system is characterized by
200 kHz channel spacing and mobile to base transmit frequencies
of 890 - 915 MHz. The primary
modulation characteristics include 0.3 GMSK filtering of the I
and Q signals and 270 kbps transmission rate.
Critical Performance
Parameters
GSM standards require that the
telephone exhibit RMS phase error ≤ 5° and peak phase error <20°.
The modulated output spectrum
of the phone must lie within a
“spectral mask” which defines
maximum allowable radiation levels into adjacent and alternate
The only external components required by this IC are four chip
capacitors. One capacitor is used
as a DC block on the input transmission line. The second capacitor (at pin 8) provides an AC
ground to one side of the differential LO input. The third and fourth
capacitors (at pins 1 and 16) are
for VCC bypass.
HPMX-2003 Performance
Typical RMS phase error level of
2° and typical peak levels of 8°
makes the HPMX-2003 an excellent choice for GSM applications.
The output spectrum falls easily
within the GSM spectral mask,
and the high power and simple
output configuration mean lower
components count, reduced size
and higher system efficiency.
The circuit board includes an inductive trace that can optionally
be used to minimize output VSWR
by placing a bypass capacitor at
various points along the inductive
line. Minimum VSWR for GSM
applications is achieved by placing the capacitor as shown in the
circle (inductance ≈2 nH).
Particulars of Use
Many of the GSM application
performance graphs shown in this
data sheet were created using the
test board shown in figure 21,
below.
Q
LO
VER. 1
C
R
V CC
5V
H
HPMX-2003/5
channels. Specifically, 200 kHz
from the channel center frequency
(f0), the output of the phone must
be at least 30 dB below the peak
output at f0. 400 kHz from f0 the
output must be 50-60 dB below
the peak output at f0 depending
upon the class of radio. Refer to
the GSM900 specifi-cations for
more detailed information.
C
C
C
OUT
I
R
Figure 21. HPMX-2003 GSM Test Board.
7-47
The IC has an internal blocking
capacitor so the output is a simple
50 Ω transmission line. An
enlarged scale layout of the test
board can be found on the last
page of this data sheet.
HPMX-2003 Typical Performance Data
0
GSM Applications
0
0
900
RF OUTPUT POWER (dBm)
-50
-50
-100
899
901
900
900
Figure 24. HPMX-2003 GSM
Modulation Spectrum at 85°C.
Figure 23. HPMX-2003 GSM
Modulation Spectrum at 25°C.
Figure 22. HPMX-2003 GSM
Modulation Spectrum at -40°C.
1.75:1
7
POWER >
1.5:1
6
1.25:1
5
< VSWR
0
OUTPUT POWER (dBm)
8
OUTPUT POWER (dBm)
2:1
0
-10
-20
-55 °C
-30
-20
85 °C
-40
-55 °C
-60
25 °C
25 °C
85 °C
1:1
880
890
900
910
920
4
930
-40
850
875
FREQUENCY (MHz)
925
-80
850
950
2
4
85 °C
0.5
-55 °C
0
-0.5
-25
-20
-15
-10
-5
0
LO INPUT POWER (dBm)
2
-55 °C
0
-2
85 °C
-4
-1
0
950
Figure 27. LO leakage vs. Frequency
and Temperature (With 25°C Offset
Adjustment), VCC = 5 V, LO = -12 dBm,
VIref = VQref = 2.5 V.
OUTPUT PHASE ERROR (DEGREES)
OUTPUT AMPLITUDE ERROR (dB)
4
925
FREQUENCY (MHz)
1
6
900
875
FREQUENCY (MHz)
8
OUTPUT POWER (dBm)
900
Figure 26. HPMX-2003 LO Leakage vs.
Frequency and Temperature (Without
Offset Adjustment), VCC = 5 V,
LO␣ =␣ -12 dBm, VImod = VQmod = VIref =
VQref = 2.5 V.
Figure 25. HPMX-2003 Output VSWR
and Power vs. Frequency, VCC = 5 V,
LO␣ = -12 dBm, VImod = VQmod = 3.75 V,
Unbalanced, VIref = VQref = 2.5 V,
TA␣ =␣ 25 °C.
901
FREQUENCY (MHz)
FREQUENCY (MHz)
FREQUENCY (MHz)
OUTPUT VSWR
-50
-100
899
901
OUTPUT POWER (dBm)
-100
899
RES BW = 3 kHz
VBW = 30 Hz
SWP = 60.0 SEC.
RES BW = 3 kHz
VBW = 30 Hz
SWP = 60.0 SEC.
RF OUTPUT POWER (dBm)
RF OUTPUT POWER (dBm)
RES BW = 3 kHz
VBW = 30 Hz
SWP = 60.0 SEC.
0
90
180
270
360
INPUT PHASE (DEGREES)
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 30. HPMX-2003 Vector Phase
Error vs. Input Phase and
Temperature at 900 MHz, VCC = 5 V,
LO = -12 dBm, Unbalanced, VIref = VQref
= 2.5 V.
Note: Modulation spectrum test conditions as follows: VCC = 5 V, LO = -12 dBm at 900 MHz, VImod = VQmod = 2.5 Vp-p, unbalanced, average
level = 2.5 V, VIref = VQref = 2.5 V, bit clock rate: 270 kHz, baseband filter: α = 0.3 GMSK.
Figure 28. HPMX-2003 Power Output
vs. LO Input Power at 900 MHz, VCC =
5␣ V, VImod = VQmod = 3.75 V, Unbalanced,
VIref = VQref = 2.5 V, TA = 25°C.
Figure 29. HPMX-2003 Vector
Amplitude Error vs. Input Phase and
Temperature at 900 MHz, VCC = 5 V,
LO␣ = -12 dBm, VIref = VQref = 2.5 V.
7-48
HPMX-2003 NADC
Applications
The NADC System
NADC (North American Digital
Cellular) commonly refers to the
digital sections of the IS-55
cellular telephone system standard. Dual mode (FM/TDMA)
cellular phones for the North
American market must conform
to this standard. The NADC
system is characterized by 30 kHz
channel spacing and mobile to
base transmit frequencies of 824 849 MHz. The primary modulation
characteristics include π/4 DQPSK
filtering of the I and Q signals and
48.6 kbps transmission rate.
Critical Performance
Parameters
System specifications require that
the telephone exhibit RMS modulation error under 12% in the digital mode. The modulated output
spectrum of the phone must lie
within a “spectral mask” which
defines maximum allowable radiation levels into adjacent and alternate channels. Specifically, total
R
V CC
H
5V
MR
HPMX-2003/5
Particulars of Use
Many of the NADC application
performance graphs shown in this
data sheet were created using the
test board shown in figure 31,
below.
C
C
C
OUT
I
HPMX-2003 Performance
The typical RMS modulation error
level of 4% makes the HPMX-2003
an excellent choice for NADC
applications. The output falls
easily within the NADC spectral
requirements, and the high power
and simple output configuration
mean lower components count,
reduced size and higher system
efficiency.
Q
LO
VER. 1
power radiated into the either adjacent channel must be at least
26␣ dB below the mean output
power. Total power radiated into
either alternate channel must be
at least 45 dB below the mean output power. Refer to the IS-55
specifications for more detailed
information.
C
R
Figure 31. HPMX-2003 NADC Test Board.
7-49
The only external components required by this IC are four chip
capacitors. One capacitor is used
as a DC block on the input transmission line. The second capacitor (at pin 8) provides an AC
ground to one side of the differential LO input. The third and fourth
capacitors (at pins 1 and 16) are
for VCC bypass.
The circuit board includes an inductive trace that can optionally
be used to minimize output VSWR
by placing a bypass capacitor at
various points along the inductive
line. Minimum VSWR for NADC
applications is achieved by placing the capacitor as shown in the
circle (inductance ≈ 6 nH).
The IC has an internal blocking
capacitor so the output is a simple
50 Ω transmission line. An enlarged scale layout of the test
board can be found on the last
page of this data sheet.
HPMX-2003 Typical Performance Data
0
NADC Applications
0
0
RF OUTPUT POWER (dBm)
-50
-50
-100
-100
835.00
835.15
835.00
FREQUENCY (MHz)
Figure 32. HPMX-2003 NADC
Modulation Spectrum at -40°C.
1.75:1
7
POWER >
1.5:1
6
1.25:1
5
835.15
834.85
Figure 33. HPMX-2003 NADC
Modulation Spectrum at 25°C.
Figure 34. HPMX-2003 NADC
Modulation Spectrum at 85°C.
0
0
-10
-20
-55 °C
-30
25 °C
-20
85 °C
-40
-55 °C
-60
+25 °C
85 °C
830
4
860
845
-40
810
820
FREQUENCY (MHz)
830
840
850
4
2
0.25
0
-0.25
85 °C
-0.5
0
-20
-15
-10
-5
LO INPUT POWER (dBm)
Figure 38. HPMX-2003 Power Output
vs. LO Input Power at 900 MHz, VCC =
5 V, LO = -12 dBm, VImod = VQmod = 3.75
V, Unbalanced, VIref = VQref = 2.5 V, TA =
25°C.
0
850
860
5
OUTPUT PHASE ERROR (DEGREES)
OUTPUT AMPLITUDE ERROR (dB)
6
840
FREQUENCY (MHz)
-55 °C
8
830
Figure 37. LO Leakage vs. Frequency
and Temperature (With 25°C Offset
Adjustment), VCC = 5 V, LO = -12 dBm,
VIref = VQref = 2.5 V.
0.5
-25
820
FREQUENCY (MHz)
10
OUTPUT POWER (dBm)
-80
810
860
Figure 36. HPMX-2003 LO Leakage vs.
Frequency and Temperature (Without
Offset Adjustment), VCC = 5 V, LO
=␣ -12␣ dBm, VImod = VQmod = VIref = VQref =
2.5 V.
Figure 35. HPMX-2003 Output VSWR
and Power vs. Frequency, VCC = 5 V,
LO␣ = -12 dBm, VImod = VQmod = 3.75 V,
Unbalanced, VIref = VQref = 2.5 V,
TA␣ =␣ 25 °C.
835.15
FREQUENCY (MHz)
< VSWR
1:1
815
835.00
FREQUENCY (MHz)
OUTPUT POWER (dBm)
8
OUTPUT POWER (dBm)
2:1
-50
-100
834.85
OUTPUT POWER (dBm)
834.85
OUTPUT VSWR
RES BW = 3 kHz
VBW = 30 Hz
SWP = 9.00 SEC.
RES BW = 3 kHz
VBW = 30 Hz
SWP = 9.00 SEC.
RF OUTPUT POWER (dBm)
RF OUTPUT POWER (dBm)
RES BW = 3 kHz
VBW = 30 Hz
SWP = 9.00 SEC.
2.5
85 °C
0
-55 °C
-2.5
-5
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 39. HPMX-2003 Vector
Amplitude Error vs. Input Phase and
Temperature at 900 MHz, VCC = 5 V, LO
= -12 dBm, VIref = VQref = 2.5 V.
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 40. HPMX-2003 Vector Phase
Error vs. Input Phase and
Temperature at 900 MHz, VCC = 5 V, LO
= -12 dBm, Unbalanced, VIref = VQref =
2.5 V.
Note: Modulation spectrum test conditions as follows: LO = -12 dBm at 835 MHz, VI = VQ = 2.5 Vp-p, unbalanced, average level = 2.5 V, VIref
= VQref = 2.5 V, bit clock rate: 48.6 kHz, baseband filter: α = 0.35, π/4 DQPSK, VCC = 5 V.
7-50
HPMX-2003 JDC
Applications
cally, 50 kHz from the channel
center frequency (f0), the output
of the phone must be at least
45␣ dB below the peak output at f 0.
100 kHz from f0, the output must
be at least 60 dB below the peak
output at f0. Refer to the JDC
specifications for more detailed
information.
The JDC System
JDC (Japan Digital Cellular) commonly refers to the Japanese digital cellular telephone system
standard. Digital cellular phones
for the Japanese market must
conform to this standard. The JDC
system is characterized by 25 kHz
channel spacing and mobile to
base transmit frequencies of 940 –
960 MHz. The primary modulation
characteristics include π/4 DQPSK
filtering of the I and Q signals and
42 kbps transmission rate.
Critical Performance
Parameters
JDC standards require that the
telephone exhibit RMS modulation error ≤ 12.5%. The modulated
output spectrum of the phone
must lie within a “spectral mask”
which defines maximum allowable radiation levels into adjacent
and alternate channels. Specifi-
The circuit board includes an inductive trace that can optionally
be used to minimize output VSWR
by placing a bypass capacitor at
various points along the inductive
line. Minimum VSWR for JDC
applications is achieved by placing the capacitor as shown in the
circle (inductance ≈ 0 nH).
Particulars of Use
Many of the JDC application performance graphs shown in this
data sheet were created using the
test board shown in figure 41,below.
The IC has an internal blocking
capacitor so the output is a simple
50 Ω transmission line. An enlarged scale layout of this board
can be found on the last page of
this data sheet.
Q
C
R
V CC
5V
H
HPMX-2003/5
HPMX-2003 Performance
The typical RMS modulation error
level of 4% makes the HPMX-2003
an excellent choice for JDC applications. The output spectrum falls
easily within the JDC spectral
mask, and the high power and
simple output configuration mean
lower components count, reduced
size and higher system efficiency.
LO
VER. 1
C
C
C
OUT
I
The only external components
required by this IC are four chip
capacitors. One capacitor is used
as a DC block on the input transmission line. The second capacitor (at pin 8) provides an AC
ground to one side of the differential LO input. The third and fourth
capacitors (at pins 1 and 16) are
for VCC bypass.
R
Figure 41. HPMX-2003 JDC Test Board.
7-51
JDC Applications
HPMX-2003 Typical Performance Data
0
0
0
950.00
RF OUTPUT POWER (dBm)
RF OUTPUT POWER (dBm)
-50
-100
949.875
950.125
950.00
FREQUENCY (MHz)
FREQUENCY (MHz)
1.75:1
7
POWER >
1.5:1
6
1.25:1
5
0
-10
-20
-55 °C
-30
< VSWR
940
950.125
Figure 44. HPMX-2003 JDC
Modulation Spectrum at 85°C.
0
OUTPUT POWER (dBm)
8
OUTPUT POWER (dBm)
OUTPUT VSWR
2:1
950.00
FREQUENCY (MHz)
Figure 43. HPMX-2003 JDC
Modulation Spectrum at 25°C.
Figure 42. HPMX-2003 JDC
Modulation Spectrum at -40°C.
1:1
920
-50
-100
949.875
950.125
OUTPUT POWER (dBm)
RF OUTPUT POWER (dBm)
-50
-100
949.875
RES BW = 3 kHz
VBW = 30 Hz
SWP = 7.50 SEC.
RES BW = 3 kHz
VBW = 30 Hz
SWP = 7.50 SEC.
RES BW = 3 kHz
VBW = 30 Hz
SWP = 7.50 SEC.
-10
-20
-55 °C
-30
25 °C
25 °C
960
85 °C
85 °C
4
980
-40
920
960
940
-40
920
980
960
940
980
FREQUENCY (MHz)
FREQUENCY (MHz)
FREQUENCY (MHz)
Figure 46. HPMX-2003 LO Leakage vs.
Frequency and Temperature (Without
Offset Adjustment), VCC = 5 V,
LO␣ =␣ -12 dBm, VImod = VQmod = VIref =
VQref = 2.5 V.
Figure 45. HPMX-2003 Output VSWR
and Power vs. Frequency, VCC = 5 V,
LO␣ = -12 dBm, VImod = VQmod = 3.75 V,
Unbalanced, VIref = VQref = 2.5 V,
TA␣ =␣ 25 °C.
1
6
4
2
6
85 °C
OUTPUT PHASE ERROR (dB)
OUTPUT AMPLITUDE ERROR (dB)
8
OUTPUT POWER (dBm)
Figure 47. LO Leakage vs. Frequency
and Temperature (With 25°C Offset
Adjustment), VCC = 5 V, LO = -12 dBm,
VIref = VQref = 2.5 V.
0.5
85 °C
0
-55 °C
-0.5
-1
0
-25
-20
-15
-10
-5
0
LO INPUT POWER (dBm)
Figure 48. HPMX-2003 Power Output
vs. LO Input Power at 950 MHz, VCC =
5 V, VImod = VQmod = 3.75 V, Unbalanced,
VIref = VQref = 2.5 V, TA = 25°C.
3
0
-55 °C
-3
-6
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 49. HPMX-2003 Vector
Amplitude Error vs. Input Phase and
Temperature at 950 MHz, VCC = 5 V, LO
= -12 dBm, Unbalanced, VIref = VQref =
2.5 V.
0
90
180
270
360
INPUT PHASE (DEGREES)
Figure 50. HPMX-2003 Vector Phase
Error vs. Input Phase and
Temperature at 950 MHz, VCC = 5 V, LO
= -12 dBm, Unbalanced, VIref = VQref =
2.5 V.
Note: Modulation spectrum test conditions as follows: LO = -12 dBm at 950 MHz, VImod = VQmod = 2.5 Vp-p, unbalanced, average level = 2.5
V, VIref = VQref = 2.5 V, bit clock rate: 42 kHz, baseband filter: α = 0.5, π/4 DQPSK, VCC = 5 V.
7-52
HPMX-2003
Part Number Ordering Information
Part Number
Option
No. of Devices
Reel Size
25 min.
tube
1000
7"
HPMX-2003
HPMX-2003
T10
HPMX-2003 Test Board Layout
Package Dimensions
SO-16 Package
1000 pF
9.80 (0.385)
10.00 (0.394)
+5 V
1000 pF
OPTIONAL INDUCTOR
16 15 14 13 12 11 10 9
4.60 (0.181)
5.20 (0.205)
PIN:
1 2
3.80 (0.150)
4.00 (0.158)
3
4
5
6
7
1.27 TYP.
(0.050)
16
2
15
3
14
4
13
Qref
5
12
I ref
Qmod
6
11
Imod
7
10
8
9
8
0.10 (0.004)
0.20 (0.008)
0.45 (0.018)
0.56 (0.022)
1
5.80 (0.228)
6.20 (0.244)
0.35 (0.014)
0.45 (0.018)
1000 pF
LOin+
LOin–
1.35 (0.053)
1.75 (0.069)
0.15 (0.007)
0.254 (0.010)
RFout
DO NOT CONNECT
1000 pF
4.60 (0.181)
5.20 (0.205)
8°
0°
0.64 (0.025)
0.77 (0.030)
Finished board size: 1.5" x 1" x 1/32" Material: 1/32"
epoxy/fiberglass, 1 oz. copper, both sides, tin/lead
coating, both sides.
Note: white “+” marks indicate drilling locations for plated-through via
holes to the groundplane on the bottom side of the board.
NOTE: DIMENSIONS ARE IN MILLIMETERS (INCHES).
F
U
o
A
C
E
A
J
D
C
P
7-53
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