AD8361ARM Analog Devices Inc, AD8361ARM Datasheet - Page 16

IC PWR DETECTOR 2.5GHZ 8-MSOP

AD8361ARM

Manufacturer Part Number
AD8361ARM
Description
IC PWR DETECTOR 2.5GHZ 8-MSOP
Manufacturer
Analog Devices Inc
Datasheet

Specifications of AD8361ARM

Rf Type
Cellular, CDMA, W-CDMA
Rohs Status
RoHS non-compliant
Frequency
100MHz ~ 2.5GHz
Input Range
0 ~ 700mV
Accuracy
±0.25dB
Voltage - Supply
2.7 V ~ 5.5 V
Current - Supply
1.1mA
Package / Case
8-TSSOP, 8-MSOP (0.118", 3.00mm Width)
Frequency Range
100MHz To 2.5GHz
Supply Current
1.1mA
Supply Voltage Range
2.7V To 5.5V
Rf Ic Case Style
MSOP
No. Of Pins
8
Operating Temperature Range
-40°C To +85°C
Pin Count
8
Screening Level
Industrial
Package Type
MSOP
Lead Free Status / Rohs Status
Not Compliant

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AD8361
Output Drive Capability and Buffering
The AD8361 is capable of sourcing an output current of
approximately 3 mA. If additional current is required, a simple
buffering circuit can be used as shown in Figure 51. Similar
circuits can be used to increase or decrease the nominal
conversion gain of 7.5 V/V rms (Figure 49 and Figure 50). In
Figure 50, the AD8031 buffers a resistive divider to give a slope
of 3.75 V/V rms. In Figure 49, the op amp’s gain of two increases
the slope to 15 V/V rms. Using other resistor values, the slope
can be changed to an arbitrary value. The AD8031 rail-to-rail
op amp, used in these example, can swing from 50 mV to 4.95 V
on a single 5 V supply and operate at supply voltages down to
2.7 V. If high output current is required (>10 mA), the AD8051,
which also has rail-to- rail capability, can be used down to a
supply voltage of 3 V. It can deliver up to 45 mA of output
current.
0.01µF
0.01µF
Figure 50. Output Buffering Options, Slope of 3.75 V/V rms
Figure 51. Output Buffering Options, Slope of 7.5 V/V rms
Figure 49. Output Buffering Options, Slope of 15 V/V rms
COMM PWDN
COMM PWDN
0.01µF
AD8361
AD8361
COMM PWDN
VPOS
VPOS
AD8361
VPOS
100pF
100pF
VOUT
VOUT
100pF
VOUT
5kΩ
5kΩ
AD8031
AD8031
5kΩ
AD8031
10kΩ
5kΩ
0.01µF
0.01µF
0.01µF
3.75V/V rms
7.5V/V rms
15V/V rms
5V
5V
5V
Rev. C | Page 16 of 24
OUTPUT REFERENCE TEMPERATURE DRIFT
COMPENSATION
The error due to low temperature drift of the AD8361 can be
reduced if the temperature is known. Many systems incorporate
a temperature sensor; the output of the sensor is typically
digitized, facilitating a software correction. Using this
information, only a two-point calibration at ambient is required.
The output voltage of the AD8361 at ambient (25°C) can be
expressed by the equation
where GAIN is the conversion gain in V/V rms and V
extrapolated output voltage for an input level of 0 V. GAIN and
V
calculated at ambient using a simple two-point calibration by
measuring the output voltages for two specific input levels.
Calibration at roughly 35 mV rms (−16 dBm) and 250 mV rms
(+1 dBm) is recommended for maximum linear dynamic range.
However, alternative levels and ranges can be chosen to suit the
application. GAIN and V
equations
Both GAIN and V
of V
This can be seen by inserting data from Figure 18 and Figure 21
(intercept drift and conversion gain) into the equation for V
These plots are consistent with Figure 14 and Figure 15, which
show that the error due to temperature drift decreases with
increasing input level. This results from the offset error having a
diminishing influence with increasing level on the overall
measurement error.
From Figure 18, the average intercept drift is 0.43 mV/°C from
−40°C to +25°C and 0.17 mV/°C from +25°C to +85°C. For a
less rigorous compensation scheme, the average drift over the
complete temperature range can be calculated as
With the drift of V
V
OS
OUT
(also referred to as intercept and output reference) can be
OS
V
V
GAIN
DRIFT
= ( GAIN × V
OUT
OS
has a bigger influence on the error relative to the output.
=
=
V
=
VOS
(
OUT1
GAIN
(
V
(
/ V
OUT2
V
IN2
°
OS
IN
(
C
OS
×
GAIN
) + V
drift over temperature. However, the drift
)
V
included, the equation for V
=
V
V
IN
⎜ ⎜
OUT1
IN1
)
OS
0.010
OS
+
×
+
are then calculated using the
V
ς
+ DRIFT
)
85
ΟΣ
IN1
°
V
C
)
(
(
VOS
0.028
40
°
× (TEMP − 25° C )
C
V
)
)
⎟ ⎟
=
0.000304
OUT
becomes
OS
is the
/ V
°
OUT
C
.

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