Peak Power Meters for Crest Factor and Scalar Measurements

Peak Power Meters for Crest Factor and Scalar Measurements
Application Note
Peak Power Meters for Crest Factor and Scalar Measurements
Using Broadband OFDM Signals
Vitali Penso
Applications Engineer, Boonton Electronics
Abstract
In this application note we highlight how broadband LTE and WiFi power amplifier (PA) performance can be characterized using Boonton’s high performance USB
peak power meter. Figure of merit measurements like input and output crest factor
can be performed to characterize amplifier compression using highly dynamic and
broadband LTE & WiFi signals. With the use of a directional coupler the USB peak
power meter is transformed to make scalar-like measurements such as gain and
return loss.
Crest Factor and Scalar Like Measurements
Using Modulated Broadband Signals for Power
Amplifiers
A critical component of a base station is the power amplifier (PA).
Over the past two decades the PA has experienced monumental
changes in its architecture and performance. Two significant improvements have been in power-added efficiency & bandwidth.
Fifteen years ago a 2G basestation PA housed in a ground base
station cabinet would output 5 MHz multi carrier CDMA signals
at 40W; running at 5% efficiency it would generate 760 Watts of
heat, taking up a significant amount of space, power and cooling
resources and costing thousands of dollars. Today’s 4G amplifiers
using Doherty architecture with predistortion has improved the efficiency of an amplifier to over 35%, significantly reducing the size
and enabling integration of the PA with the transceiver and the
duplexer into a remote radio head (RRH) placed near the antenna.
The other significant improvement has been in PA bandwidth. Today’s RRHs are deployed in systems where the carriers are placed
anywhere in a 70 MHz (or wider) frequency band. Measuring and
characterizing the performance of the wideband PA requires test
equipment that supports the bandwidths used in today’s deployments. In this application note we show how using Boonton’s high
performance peak power meters with directional couplers enables
the designer to make input, output and reflected power measurements; facilitating scalar analyzer like measurements such as gain
and input return loss using multi-carrier, wide bandwidth (>100
MHz) test signals as opposed to narrowband CW. The statistical analysis tool of the peak power meter provides insight into the
amplifier compression by measuring and comparing crest factor of
input and output signals of the PA using wideband 4G signals while
monitoring both peak and average power.
Measuring PA Compression & Crest Factor
In an ideal world the PA output signal is an amplified version of
the input signal; input power plotted vs output power produces
a straight linear line, where the slope of the line is 1. In reality
however, as the PA is driven harder, at a certain point the output
will not increase as much as the input power; at this point the amplifier is in its non-linear region or is in compression. In the non-linear region the PA generates intermodulation products (Figure
2a.) which cause emission of spurious power into adjacent channels. Aside from effecting adjacent channels, non-linearity also
degrades EVM of the desired signal which causes loss of signal
quality. In wireless communication systems modulation schemes
such as CDMA (2G), WCDMA (3G), QAM and OFDM (4G-LTE) the
signal is highly dynamic where 10 dB crest factor or peak to average power ratio (PAPR) is not unusual. When the amplifier goes
into compression driven by a CDMA or OFDM modulated wideband
signal, rare occurring peaks get compressed first; so when an amplifier is in 0.2 dB average power compression, its peak can be compressed by 1.0 dB or more. For example, a PA with 40 dB gain, 0
dBm average input signal with a crest factor of 10 dB (peak 10
dBm) would output 39.8 dBm average power but the peak power
would be clipped at 49 dBm (crest factor 9.2 dB). While average
(true RMS) power meters measure the average power of the signal,
they lack the bandwidth to capture the peaks, whereas Boonton’s
55 series USB peak power meter in a dual channel configuration
can accurately measure both input and output average and peak
power in real-time. With statistical analysis capability the 55 series can display the statistical distribution of the signal power level relative to its average power in a format called complementary
cumulative distribution function (CCDF). CCDF can give significant
insight into the behavior of the PA as it is driven harder into saturation by measuring changes is in PAR and crest factor of the input
and output signals simultaneously and providing a graphical view
of the compression of the amplifier in real-time (Figure 2b).
0
PA-OUT
-10
PA-IN
-20
-30
-40
-50
-80 -60 -40 -20
Figure 1. RRH Base station
Applcation Note
0
20
40
60
80
Figure 2a. Spectral regrowth (IMD) in multi-carrier LTE signals. Red trace is PA OUT,
blue PA IN
Peak Power Meters for Crest Factor and Scalar Measurements Using Broadband OFDM Signals
2
CH1 / PA OUT
CH2 / PA IN
100.0
10.0
1.0
(%)
0.1
Before measurements can be taken a basic calibration procedure
is required at the frequencies in which the amplifier is going to be
tested; all unused ports of the coupler need to be terminated with
50 ohms while making measurements.
L1: Loss from LTE Generator output to the FWD port of the bi-directional coupler.
0.01
0.001
L2: Loss from LTE Generator output to the power amplifier input.
0.0001
0.0 1.0 2.0 3.0 4.0 5.0 6.0 7.0 8.0 9.0 10.0
(dBr)
Figure 2b. CCDF curve shows % of time the signal is above its average power (Pavg).
For example PA IN is 4.8 dB above Pavg 10% of the time. Example of a dual channel
power meter monitoring amplifier compression – input green, compressed output
red.
Performing Scalar Analyzer Like Measurements – Gain & Input Return Loss
L3: Loss from amplifier output to the 40 dB attenuator output.
L4: Loss from amplifier input into the REV port of the bi-directional
coupler.
Once the losses are measured, input, output and reflected power
measurements can be made:
P1: Power reading at FWD port of the bidirectional coupler.
PA input power = P1+L1-L2.
Figure 3. shows a typical PA test set-up using peak power meters
and a bidirectional coupler to make scalar analyzer like measurements such as gain and return loss. The input power is measured
coupling off the input signal to the amplifier by using a bi-directional coupler. The reflected power from the input of the amplifier can be measured using the reverse coupling port of the same
bi-directional coupler. Since the typical average power rating of a
power meter is about +20 dBm, the output of the PA is attenuated
to protect the power sensor while making output power measurements. It is important to note that the bi-directional coupler needs
to have excellent directivity.
P2: Power measured at the 40 dB attenuator output.
PA output power = P2+L3.
P3: Power measured at REV port of the bidirectional coupler.
PA input reflected power = P3+L4.
Figure 3. Amplifier test set-up using peak power meters
Application Note
Peak Power Meters for Crest Factor and Scalar Measurements Using Broadband OFDM Signals 3
The input, output and reflected power measurements can be
used to compute gain (S21) and input return loss (S11).
PA Gain(dB) = PA output power(dBm)– PA input power (dBm)
PA input return loss(dB) = PA input power(dBm) – PA input reflected power(dBm)
For example average input power of 0 dBm and output power
of 46 dBm would mean 46 dB gain and average reflected power
of -10 dBm would be 10 dB input return loss. Making the measurements in statistical mode provides average power and peak
power of all three measurements (input, output and reflected
power). Reading average and peak power simultaneously allows
monitoring amplifier compression and making crest factor measurements that were described previously.
Conclusion
In scalar analyzer-like configuration, three peak power sensors,
like average power sensors, can measure input, output and reflected power of the amplifier, enabling average power gain and
return loss measurements. Measuring peak power as well as the
average power is something average power sensors cannot do
and differentiates peak power sensors in RF Power Amplifier
characterization. As the input power is increased and the amplifier starts going into compression at the rear peaks, its peak
power gain drops much faster than its average power gain;
making crest factor a figure of merit in characterizing amplifier performance. However, not all peak power meters can handle
today’s wide bandwidth signals for crest factor measurements.
The ability to measure average and peak power of wideband
multi-carrier LTE as well as 802.11ac signals makes the Boonton
55 series USB peak power sensor ideal for highly accurate crest
factor measurements.
Boonton Peak Power Meter Solutions
Measuring peak power & crest factor of multi-carrier LTE signals
(70+ MHz) as well as 802.11ac Wifi signals (160 MHz) requires
wide bandwidth peak power meters. Boonton’s 55006 USB peak
power sensor with 195 MHz video bandwidth can handle the
challenging LTE and WiFi 802.11ac signals. 55006 GUI supports
up to 8 channel measurements which is more than what is covered in this application note for scalar-like measurements. In statistical mode with sampling speed of 100 million points (samples) per second, crest factor measurements converge rapidly.
While the high performance of the sensor makes it well suited for
R&D, 100,000 triggered measurements per second also makes it
the fastest sensor to use in manufacturing. Affordability allows
quality engineers to use the same model sensor used in R&D in
verification. The small form factor enables field engineers to use
the same R&D equipment in the field for measurements that correlate well with the lab measurements.
55 Series USB Peak Power Sensor
Wireless Telecom Group Inc.
25 Eastmans Rd
Parsippany, NJ
United States
Tel:
+1 973 386 9696
Fax:
+1 973 386 9191
www.boonton.com
Follow us on:
WTGinnovation
Wireless Telecom Group
blog.wtcom.com
WTGinnovation
B/AN/0515/EN
Note: Specifications, terms and conditions
are subject to change without prior notice.
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