AD8362ARUZ Analog Devices Inc, AD8362ARUZ Datasheet - Page 24
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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AD8362
TEMPERATURE COMPENSATION AT VARIOUS WiMAX FREQUENCIES UP TO 3.8 GHz
The AD8362 is ideally suited for measuring WiMAX type
signals because crest factor changes in the modulation scheme
have very little affect on the accuracy of the measurement.
However, at higher frequencies, the AD8362 drifts more over
temperature often making temperature compensation necessary.
Temperature compensation is possible because the part-to-part
variation over temperature is small, and temperature change
only causes a shift in the AD8362’s intercept. Typically, users
choose to compensate for temperature changes digitally. How-
ever, temperature compensation is possible using an analog
temperature sensor. Because the drift of the output voltage is
due mainly to intercept shift, the whole transfer function tends
to drop with increasing temperature, while the slope remains
quite stable. This makes the temperature drift independent of
input level. Compensating the drift based on a particular
input level (for example, −15 dBm), holds up well over the
dynamic range.
Figure 59 through Figure 63 show these results. The compensa-
tion is simple and relies on the
sensor driving one side of the resistor divider as the AD8362
drives the other side. The output is at the junction of the two
resistors (see Figure 58). At 25°C, TMP36 has an output voltage
of 750 mV and a temperature coefficient of 10 mV/°C. As the
temperature increases, the voltage from the AD8362 drops and
the voltage from the TMP36 rises. R1 and R2 are chosen so the
voltage at the center of the resistor divider remains steady over
temperature. In practice, R2 is much larger than R1 so that the
output voltage from the circuit is close to the voltage of the V
pin. The resistor ratio R2/R1 is determined by the temperature
drift of the AD8362 at the frequency of interest. To calculate the
values of R1 and R2, first calculate the drift at a particular input
level, −15 dBm in this case. To do this, calculate the average
drift over the temperature range from 25°C to 85°C. Using the
following equation, the average drift in dB/°C is obtained.
In this example, the drift of the AD8362 from 25°C to 85°C is
−2.07 dB and the temperature delta is 60°C, which results in
−0.0345 dB/°C drift. This temperature drift in dB/°C is con-
verted to mV/°C through multiplication by the logarithmic slope
(51 mV/dB at 2350 MHz). The result is −1.76 mV/°C. The
following equation calculates the values of R1 and R2:
dB/
R2
R1
°
=
C
AD8362
=
Δ
Temperatur
10
dB
Drift
Error
mV/
°
(mV/
C
e
°
TMP36
C)
precision temperature
(16)
(17)
Rev. D | Page 24 of 32
OUT
Table 5 shows the resultant values for R2 and R1 for frequen-
cies ranging from 2350 MHz to 3650 MHz. Figure 59 through
Figure 63 show the performance over temperature for the
AD8362 with temperature compensation at frequencies across
the WiMAX band. The compensation factor chosen optimizes
temperature drift in the 25°C to 85°C range. This can be altered
depending on the temperature requirements for the application.
Table 5. Recommended Resistor Values for Temperature
Compensation at Various Frequencies
Freq.
(MHz)
2350
2600
2800
3450
3650
4.7nH
2.7nH
Figure 58. AD8362 with Temperature Compensation Circuit
1nF
Average
Drift @
−15 dBm
(dB/°C)
−0.0345
−0.0440
−0.0486
−0.0531
−0.0571
1nF
VTGT
INHI
INLO
AD8362
VOUT
VSET
CLPF
VREF
Slope
(mV/dB)
51
51.45
51.68
51.61
51.73
0.1µF
R1
V
Average
Drift @
−15 dBm
(mV/°C)
−1.7600
−2.2639
−2.5102
−2.7402
−2.9544
OUT
R2
V
TEMP
1
R1
(kΩ)
4.99
4.99
4.99
4.99
4.99
TMP36F
5V
2
5
0.1µF
R2
(kΩ)
28
22.1
20
18.2
16.9
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