AD8362ARUZ Analog Devices Inc, AD8362ARUZ Datasheet - Page 23
AD8362ARUZ
Manufacturer Part Number
AD8362ARUZ
Description
IC PWR DETECTOR 3.8GHZ 16-TSSOP
Manufacturer
Analog Devices Inc
Datasheet
1.AD8362-EVAL.pdf
(32 pages)
Specifications of AD8362ARUZ
Rf Type
Cellular, GSM, CDMA, TDMA, TETRA
Frequency
50Hz ~ 3.8GHz
Input Range
-52dBm ~ 8dBm
Accuracy
0.5dB
Voltage - Supply
4.5 V ~ 5.5 V
Current - Supply
20mA
Package / Case
16-TSSOP (0.173", 4.40mm Width)
Frequency Range
50Hz To 3.8GHz
Supply Current
20mA
Supply Voltage Range
4.5V To 5.5V
Rf Ic Case Style
TSSOP
No. Of Pins
16
Operating Temperature Range
-40°C To +85°C
Pin Count
16
Screening Level
Industrial
Package Type
TSSOP
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Lead Free Status / RoHS Status
Lead free / RoHS Compliant, Lead free / RoHS Compliant
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Moderately low resistance values should be used to minimize
scaling errors due to the 70 kΩ input resistance at the VSET
pin. This resistor string also loads the output, and it eventually
reduces the load-driving capabilities if very low values are used.
To calculate the resistor values, use
where:
S
R2' is the value of R2 in parallel with 70 kΩ.
For example, using R1 = 1.65 kΩ and R2 = 1.69 kΩ (R2' =
1.649 kΩ), the nominal slope is increased to 100 mV/dB.
Note, however, that doubling the slope in this manner reduces
the maximum input signal to approximately −10 dBm because
of the limited swing of VOUT (4.9 V with a 5 V power supply).
TEMPERATURE COMPENSATION AND REDUCTION
OF TRANSFER FUNCTION RIPPLE
The transfer function ripple and intercept drift of the AD8362
can be reduced using two techniques detailed in Figure 57.
CLPF is reduced from its nominal value. For broadband-
modulated input signals, this results in increased noise at
the output that is fed back to the VSET pin.
The noise contained in this signal causes the gain of the VGA
to fluctuate around a central point, moving the wiper of the
Gaussian Interpolator back and forth on the R-2R ladder.
Because the gain-control voltage is constantly moving across
at least one of taps of the Gaussian Interpolator, the relationship
between the rms signal strength of the VGA output and the
VGA control voltage becomes independent of the VGA gain
control ripple (see Figure 56). The signal being applied to the
squaring cell is now lightly AM modulated. However, this does
not change the peak-to-average ratio of the signal.
D
is the desired slope, expressed in mV/dB.
R1 = R2' (S
1nF
COMM
VPOS
1
ADDITIONAL PINS
OMITTED FOR CLARITY.
5V
AD8362
D
/50 − 1)
ACOM
0.1µF
1
VOUT
VSET
VREF
VTGT
CLPF
Figure 57. Temperature Compensation and Reduction of Transfer Function Ripple
440pF
1kΩ
1µF
3
2
AD8031
1
(15)
4
Rev. D | Page 23 of 32
5V
5
7
6
0.1µF
Because of the reduced filter capacitor, the rms voltage appearing
at the output of the error amplifier now contains significant
peak-to-peak noise. While it is critical to feed this signal back
to the VGA gain control input with the noise intact, the rms
voltage going to the external measurement node can be filtered
using a simple filter to yield a largely noise-free rms voltage.
The circuit shown in Figure 57 also incorporates a temperature
sensor that compensates temperature drift of the intercept.
Because the temperature drift varies with frequency, the amount
of compensation required must also be varied using R1 and R2.
These compensation techniques are discussed in more detail in
Application Note AN-653: Improving Temperature, Stability, and
Linearity of High Dynamic Range RMS RF Power Detectors.
Figure 56. Transfer Function and Linearity with Combined Ripple Reduction
V
TEMP
4.0
3.5
3.0
2.5
2.0
1.5
1.0
0.5
R1
R2
0
1
and Temperature Compensation Circuits, Frequency = 2.14 GHz,
–60
TMP36F
2
5
5V
–50
Single-Carrier W-CDMA, Test Model 1-64
0.1µF
ERROR (dB –40°C)
–40
V
V
V
FREQUENCY (MHz)
900
1900
2200
OUT
OUT
OUT
–30
(+25°C)
(–40°C)
(+85°C)
PIN (dBm)
V
OUT_COMP
–20
ERROR (dB +25°C)
ERROR (dB +85°C)
–10
R1 (kΩ)
1.02
1
1
0
10
R2 (kΩ)
25.5
82.5
19.1
AD8362
2
1
0
–1
–2
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