LMV221SDX National Semiconductor, LMV221SDX Datasheet - Page 19

LMV221SDX

Manufacturer Part Number

LMV221SDX

Description

Manufacturer

National Semiconductor

Datasheet

1.LMV221SDX.pdf (32 pages)

Specifications of LMV221SDX

Operating Temperature (min)

-40C

Operating Temperature (max)

85C

Operating Temperature Classification

Industrial

Mounting

Surface Mount

Pin Count

Package Type

LLP EP

Lead Free Status / RoHS Status

Not Compliant

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Figure 1 shows two different representations of the detector

transfer function. In both graphs the input power along the

horizontal axis is displayed in dBm, since most applications

specify power accuracy requirements in dBm (or dB). The

figure on the left shows a convex detector transfer function,

while the transfer function on the right hand side is linear (in

dB). The slope of the detector transfer function — i.e. the de-

tector conversion gain – is of key importance for the impact

of the quantization error on the total measurement error. If the

detector transfer function slope is low, a change, ΔP, in the

input power results only in a small change of the detector out-

put voltage, such that the quantization error will be relatively

large. On the other hand, if the detector transfer function slope

is high, the output voltage change for the same input power

change will be large, such that the quantization error is small.

The transfer function on the left has a very low slope at low

input power levels, resulting in a relatively large quantization

error. Therefore, to achieve accurate power measurement in

this region, a high-resolution ADC is required. On the other

hand, for high input power levels the quantization error will be

very small due to the steep slope of the curve in this region.

For accurate power measurement in this region, a much lower

ADC resolution is sufficient. The curve on the right has a con-

stant slope over the power range of interest, such that the

required ADC resolution for a certain measurement accuracy

is constant. For this reason, the LOG-linear curve on the right

will generally lead to the lowest ADC resolution requirements

for certain power measurement accuracy.

1.1.2 Types of RF Power Detectors

Three different detector types are distinguished based on the

four characteristics previously discussed:

•

These three types of detectors are discussed in the following

sections. Advantages and disadvantages will be presented

for each type.

Diode Detector

A diode is one of the simplest types of RF detectors. As de-

picted in Figure 2, the diode converts the RF input voltage into

Diode Detector

(Root) Mean Square Detector

Logarithmic Detector

FIGURE 1. Convex Detector Transfer Function (a) and Linear Transfer Function (b)

(a)

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a rectified current. This unidirectional current charges the ca-

pacitor. The RC time constant of the resistor and the capacitor

determines the amount of filtering applied to the rectified (de-

tected) signal.

The advantages and disadvantages can be summarized as

follows:

•

(Root) Mean Square Detector

This type of detector is particularly suited for the power mea-

surements of RF modulated signals that exhibits large peak

to average power ratio variations. This is because its opera-

The temperature stability of the diode detectors is

generally very good, since they contain only one

semiconductor device that operates at RF frequencies.

The dynamic range of diode detectors is poor. The

conversion gain from the RF input power to the output

voltage quickly drops to very low levels when the input

power decreases. Typically a dynamic range of 20 – 25 dB

can be realized with this type of detector.

The response of diode detectors is waveform dependent.

As a consequence of this dependency its output voltage

for e.g. a 0 dBm WCDMA signal is different than for a

0 dBm unmodulated carrier. This is due to the fact that the

diode measures peak power instead of average power.

The relation between peak power and average power is

dependent on the wave shape.

The transfer shape of diode detectors puts high

requirements on the resolution of the ADC that reads their

output voltage. Especially at low input power levels a very

high ADC resolution is required to achieve sufficient power

measurement accuracy (See Figure 1, left side).

FIGURE 2. Diode Detector

(b)

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LMV221SDX National Semiconductor, LMV221SDX Datasheet - Page 19

LMV221SDX

Specifications of LMV221SDX

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