THEORY OF OPERATION
The block diagram of the microwave I-Q Vector Modulator is shown in Figure 1. An RF signal incident on a 3 dB quadrature hybrid is divided into two equal outputs, with a 90° phase difference between them. The in-phase, or 0°, channel is designated the I channel and the Quadrature, or 90°, channel is designated the Q channel. Each signal passes through a biphase modulator which sets the 0° or 180° state and the attenuation level for both the I and Q paths. The outputs of the I and Q path are combined to yield the resultant vector which may fall anywhere within the bounded area shown in Figure 2. Any signal applied to the I/Q Vector Modulator can be shifted in phase and adjusted in amplitude by applying the following relationships:
- Let the desired attenuation level = X dB and the desired phase shift = θ° (with respect to 0 dB and 0° reference states).
- The normalized output voltage magnitude is given by: ? V ? = 10?(x/20).
- The values of the I and Q attenuator control inputs are then expressed as:
I = V cos θ
and
Q = V sin θ
Figure 3 shows the nominal value of I and Q vs. either digital word (Series 71) or analog voltage (Series 72). Thus, to achieve an attenuation level of 3 dB with a phase offset of 112.5° (with respect to 0 dB and 0° reference states) the values of I and Q can be calculated as follows:
V = 10–(3/20) = 0.707
I = 0.707 cos (112.5°) =–0.027
Q = 0.707 sin (112.5°) =+0.65
From Figure 3, the control inputs to yield the desired amplitude and phase are approximately:
Analog Units (72 Series) |
Digital Units (71 Series) |
I = 5.78 volts |
100101000000 |
Q = 2.84 volts |
010010001011 |
While these values for I and Q will yield an output signal whose amplitude and phase are close to the nominal values over the entire operating frequency range of the vector modulator, the use of an iterative measurement procedure will determine the I and Q inputs which exactly define the desired parameter at any selected frequency.
PERFORMANCE CHARACTERISTICS
PARAMETER |
SPECIFICATION |
OPERATING FREQUENCY RANGE |
2.0 - 18.0 GHz |
Band 1 |
2 - 6 GHz |
Band 2 |
6 - 18 GHz |
Band Switching Speed,max |
250 nanoseconds |
INSERTION LOSS (MAX) |
16 dB |
VSWR (MAX) |
2.2:1 |
POWER HANDLING CAPABILITY |
Without performance degradation |
+20 dBm |
Survival |
1 W |
ABSOLUTE INSERTION PHASE ACCURACY VS. FREQUENCY (MAX) |
±15o (in each band) |
VARIATION OF PHASE VS. TEMPERATURE (MAX) |
±0.1 deg./ oC |
ATTENUATION RANGE (MIN) |
20 dB |
VARIATION OF AMPLITUDE VS. TEMPERATURE (MAX) |
0.02 dB/ oC |
RESPONSE TIME (MAX) |
1.0 µsec |
POWER SUPPLY |
+5 V ±2% @ 200 mA, max.
+12 to +15V @ 150 mA, max.
-5.2 V ±2% @ 400 mA, max.
-12 to -15V @ 150 mA, max |
MONOTONICITY |
GUARANTEED |
Control INPUT |
12 BIT TTL FOR BOTH I & Q INPUTS |
CONNECTORS |
RF Input/output |
SMA Female, 2X |
Control/Power |
Cannon DC-37P or Equivalent |
TEMPERATURE RANGE |
Operating |
-55 oC to +85 oC |
Storage |
-65 oC to +125 oC |
ACCESSORY FURNISHED
Mating power/control connector |
AVAILABLE OPTIONS
OPTION No. |
DESCRIPTION |
G09 |
Guaranteed to meet Environmental Ratings |
G12 |
RoHS Compliant |
G18 |
REACH Compliant |
DIMENSIONS AND WEIGHT
Dimensions are stated in inches (mm). Tolerances, unless otherwise indicated: .XX ±.02; .XXX ±.008
J3 PIN FUNCTION |
PIN |
FUNCTION |
PIN |
FUNCTION |
|
|
19 |
Q-9 |
1 |
I-5 |
20 |
I-4 |
2 |
I-6
|
21 |
I-7 |
3 |
I-8 |
22 |
I-3 |
4 |
I-9 |
23 |
I-2 |
5 |
I-10 |
24 |
I-1 (LSB) |
6 |
I-11 |
25 |
I-12 (MSB |
7 |
BAND 1 (notes 1 & 2) |
26 |
N/C |
8 |
+12 to +15V |
27 |
+5V ±2% |
9 |
GND |
28 |
GND |
10 |
GND |
29 |
BAND 1 (notes 1 & 2) |
11 |
-12 to -15V |
30 |
-5.2V ±2% |
12 |
Q-3 |
31 |
BAND 2 (notes 1 & 2) |
13 |
Q-2 |
32 |
Q-4 |
14 |
Q-1 (LSB) |
33 |
BAND 2 (notes 1 & 2) |
15 |
Q-5 |
34 |
N.C. |
16 |
Q-6 |
35 |
Q-12 (MSB) |
17 |
Q-7 |
36 |
Q-11 |
18 |
Q-8 |
37 |
Q-10 |
|
NOTES:
- BAND SELECT: Band 1 (2 to 6 GHz) - Apply TTL 0 to Pin 7 or Pin 29; Band 2 (6 to 18 GHz) - Apply TTL 0 to Pin 31 or Pin 33
- With no band selected, there will be maximum Isolation between J1 and J2