ADL5501AKSZ-R7 Analog Devices Inc, ADL5501AKSZ-R7 Datasheet - Page 22
ADL5501AKSZ-R7
Manufacturer Part Number
ADL5501AKSZ-R7
Description
IC DETECTOR RF/IF TRUPWR SC70-6
Manufacturer
Analog Devices Inc
Datasheet
1.ADL5501AKSZ-R7.pdf
(28 pages)
Specifications of ADL5501AKSZ-R7
Frequency
50MHz ~ 6GHz
Rf Type
General Purpose
Input Range
-18dBm ~ 6dBm
Accuracy
±1dB
Voltage - Supply
2.7 V ~ 5.5 V
Current - Supply
1.1mA
Package / Case
6-TSSOP, SC-88, SOT-363
Frequency Range
50MHz To 6GHz
Supply Current
1.1mA
Supply Voltage Range
2.7V To 5.5V
Rf Ic Case Style
SC-70
No. Of Pins
6
Operating Temperature Range
-40°C To +85°C
Ic Function
RMS Detector IC
Digital Ic Case Style
SC-70
Rohs Compliant
Yes
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
ADL5501AKSZ-R7TR
Available stocks
Company
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Manufacturer
Quantity
Price
Company:
Part Number:
ADL5501AKSZ-R7
Manufacturer:
ADI
Quantity:
3 065
Part Number:
ADL5501AKSZ-R7
Manufacturer:
ADI/亚德诺
Quantity:
20 000
ADL5501
DEVICE CALIBRATION AND ERROR CALCULATION
Because slope and intercept vary from device to device, board-
level calibration must be performed to achieve high accuracy.
In general, calibration is performed by applying two input power
levels to the ADL5501 and measuring the corresponding output
voltages. The calibration points are generally chosen to be within
the linear operating range of the device. The best-fit line is char-
acterized by calculating the conversion gain (or slope) and intercept
using the following equations:
where:
V
V
After gain and intercept are calculated, an equation can be
written that allows calculation of an (unknown) input power
based on the measured output voltage.
For an ideal (known) input power, the law conformance error of
the measured data can be calculated as
Figure 51 includes a plot of the error at 25°C, the temperature
at which the ADL5501 is calibrated. Note that the error is not
zero; this is because the ADL5501 does not perfectly follow the
ideal linear equation, even within its operating region. The
error at the calibration points is, however, equal to zero by
definition.
Figure 51 also includes error plots for the output voltage at
−40°C and +85°C. These error plots are calculated using the
gain and intercept at +25°C. This is consistent with calibra-
tion in a mass-production environment where calibration at
temperature is not practical.
IN
RMS
+85°C vs. +25°C Linear Reference, Frequency = 1900 MHz, Supply = 5.0 V
is the rms input voltage to RFIN.
Figure 51. Error from Linear Reference vs. Input at −40°C, +25°C, and
Gain = (V
Intercept = V
V
ERROR (dB) =
20 × log [(V
is the voltage output at VRMS.
IN
–1
–2
–3
= (V
3
2
1
0
–25
RMS
RMS2
–20
− Intercept)/Gain
RMS, MEASURED
RMS1
− V
–15
− (Gain × V
RMS1
)/(V
–10
− Intercept)/(Gain × V
–40°C
INPUT (dBm)
IN2
–5
− V
IN1
+85°C
)
IN1
)
0
+25°C
5
10
IN, IDEAL
15
)] (5)
Rev. B | Page 22 of 28
(2)
(3)
(4)
CALIBRATION FOR IMPROVED ACCURACY
Another way of presenting the error function of the ADL5501
is shown in Figure 52. In this case, the dB error at hot and cold
temperatures is calculated with respect to the transfer function
at ambient. This is a key difference in comparison to the previous
plots. Up until now, the errors were calculated with respect to
the ideal linear transfer function at ambient. When this alterna-
tive technique is used, the error at ambient becomes equal to
zero by definition (see Figure 52).
This plot is a useful tool for estimating temperature drift at a
particular power level with respect to the (nonideal) response at
ambient. The linearity and dynamic range tend to be improved
artificially with this type of plot because the ADL5501 does not
perfectly follow the ideal linear equation (especially outside of
its linear operating range). Achieving this level of accuracy in
an end application requires calibration at multiple points in the
operating range of the device.
In some applications, very high accuracy is required at just one
power level or over a reduced input range. For example, in a wire-
less transmitter, the accuracy of the high power amplifier (HPA)
is most critical at or close to full power. The ADL5501 offers a
tight error distribution in the high input power range, as shown
in Figure 52. The high accuracy range, centered around 9 dBm at
1900 MHz, offers 7 dB of ±0.1 dB detection error over temperature.
Multiple point calibration at ambient temperature in the reduced
range offers precise power measurement with near 0 dB error
from −40°C to +85°C.
The high accuracy range center varies over frequency. At
1900 MHz, the region is centered at approximately 9 dBm.
At higher frequencies, the high accuracy range is centered
at higher input powers (see Figure 13 through Figure 15 and
Figure 19 through Figure 21).
Figure 52. Error from +25°C Output Voltage at −40°C, +25°C, and +85°C
After Ambient Normalization, Frequency = 1900 MHz, Supply = 5.0 V
–1
–2
–3
3
2
1
0
–25
–20
–15
–10
–40°C
INPUT (dBm)
–5
+85°C
0
+25°C
5
10
15
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