Low Power IQ Modulator for Digital Communications

Low Power IQ Modulator for Digital Communications
Bruce Hemp and Sunny Hsiao
IQ modulators are versatile building blocks for RF systems. The most common
application is generating RF signals for digital communication systems. This article
illustrates the modulation accuracy of the LTC5599 low power IQ modulator, and shows
by simple example how to integrate the device into a digital communication system.
MODULATOR APPLICATIONS
Figure 1. Test setup to measure basic modulation accuracy
LO
ROHDE & SCHWARZ SMJ 100A
450MHz, 0 dBm
BASEBAND IQ SIGNAL GENERATOR
ROHDE & SCHWARZ SMJ 100A
OR EQUIVALENT
DAC (14-BIT) + LPF
DAC (14-BIT) + LPF
I+
I−
Q+
Q−
LTC5599
RF OUT
−4 dBm RMS
LOW POWER
IQ MODULATOR
Virtually any type of RF modulation
can be generated with IQ modulation,
within the center frequency, bandwidth and accuracy capabilities of the
modulator device. Table 1 shows some
of the applications of the LTC5599.
MODULATION: 16-QAM, PRBS 9,
ROOT COSINE ALPHA 0.35, 30k SYM./SEC
VBIAS = 1.4V, IQ DRIVE = 1.1VP–P(DIFF),
CREST FACTOR 5.4dB
Table 1. Some possible applications for the LTC5599 low power IQ modulator.
APPLICATION
MOD STD
MODULATION TYPE (REFERENCE 1)
MAX RF BW
Digital wireless microphones
Proprietary
QPSK, 16/32/64-DAPSK, Star-QAM
200kHz
802.11af
OFDM: BPSK, QPSK, 16/64/256-QAM
Up to 4× 6MHz channels
DOCSIS
16-QAM
6MHz
Custom
Wide programmability range
—
—
AM, FM/PM, SSB, DSB-SC
—
TETRA
π/4-DQPSK, π/8-D8PSK, 4/16/64-QAM
25kHz to 150kHz
• Commercial
TETRAPOL
GMSK
10kHz, 12.5kHz
• Industrial
P-25
C4FM, CQPSK
6.25kHz to 12.5kHz
DMR
4FSK
6.25kHz, 12.5kHz
Wireless networking
• White-space radios
• Cognitive radio
CATV upstream
Military radios (portable, manpack)
Software defined radios (SDR)
Portable test equipment
Analog modulation
2-way radios
• Public safety
20 | November 2015 : LT Journal of Analog Innovation
design features
Figure 2. LTC5599 EVM measured using
lab-grade baseband and LO signal
generators. Note that the MER measures
over 49dB, basically “Broadcast Quality.”
MEASURED IQ VECTOR
MEASURED EYE DIAGRAM
MODULATION ACCURACY AND EVM
The error vector magnitude or EVM is
a measure of modulation accuracy in
digital radio communication systems.
Modulation accuracy is important because
any error on the modulated signal can
cause reception difficulty or excessive
occupied bandwidth. If left unchecked,
the receiver could exhibit excessive bit
errors, the effective receiver sensitivity
could be degraded or the transmit adjacent
channel power (ACP) can become elevated.
EVM VS TIME
An error vector is a vector in the I-Q plane
between the actual received or transmitted
symbol and the ideal reference symbol.
EVM is the ratio of the average of the error
vector power over the average ideal reference symbol vector power. It is frequently
expressed in either dB or percentage.
Figure 1 is a test setup example showing
the modulation accuracy attainable with
the LTC5599 low power direct quadrature
modulator. Figure 2 shows the results. In
this test, precision lab equipment generates
a 30k symbol/second 16-QAM baseband
(120kbps), and 450MHz LO input signal
to the modulator. A vector signal analyzer
(VSA) examines the modulator output.
In Figure 2, the EVM vs time results
show EVM uniformly low across all
symbols, while the error summary
shows EVM approximately 0.24% RMS,
and 0.6% peak. This is indeed excellent performance, shown by a modulation error ratio (MER) of 49.6dB.
The LTC5599 has internal trim registers
that facilitate fine adjustments of I and
ERROR SUMMARY
TEST CIRCUIT SHOWN IN FIGURE 1
DUT: LTC5599
REGISTERS[0…8] = [0X31, 84, 80, 80, 80, 10, 50, 06, 00]
FREQUENCY SET TO 450MHz; OTHERWISE ALL DEFAULTS
VSA: AGILENT 89441A, ANALYSIS SPAN = 100kHz
MEASURING FILTER: ROOT COSINE ALPHA 0.35
REFERENCE FILTER: RAISED COSINE
What’s an IQ Modulator?
An IQ modulator is a device that converts baseband
information into RF signals. Internally, two doublebalanced mixers are combined as shown below. By
modulating with both in-phase (I) and quadrature (Q)
inputs, any arbitrary output amplitude and phase can
be selected.
By targeting specific points in amplitude and phase,
high order modulation is created. Shown below is 16QAM. There are four possible I values, which decodes
into two bits. Likewise for the Q axis. So each symbol
can convey four bits of information.
I-CHANNEL
MODULATOR
INPUT
LO
INPUT
Q+
90°
COMBINER
Q-CHANNEL
MODULATOR
INPUT
I−
I+
Q−
Fundamental architecture of an IQ modulator
November 2015 : LT Journal of Analog Innovation | 21
Q DC offset, amplitude imbalance, and
quadrature phase imbalance to further
optimize modulation accuracy—results are
even better if trim registers are adjusted.
In many ways, this test demonstrates the
best-case capabilities of the modulator
without optimization: baseband bandwidth is large, DAC accuracy and resolution are superb and digital filtering is
nearly ideal.1 While these test results are
useful for measuring the true performance
of the modulator, practical low power
wireless implementations necessitate
some compromises, as discussed below.
DRIVING FROM PROGRAMMABLE
LOGIC OR AN FPGA
Figure 3. Transmit exciter block diagram. (Full schematic is in Figure 4.)
LO
0 dBm
Many FPGAs and programmable devices
support digital filter block (DFB) functionality, an essential building block for
digital communications. Raw transmit
data is readily IQ mapped and digitally
filtered. Figure 3 shows an example
of how a device such as the Cypress
PSoC 5LP can be utilized to drive IQ
modulators such as the LTC5599.
MCU WITH
PROGRAMMABLE LOGIC
DFB
DFB
DAC
8-BIT
DAC
8-BIT
I
I
LT6238
I
SINGLE ENDED
TO DIFF
Q
Q
VOCM = 1.4V
MODULATION:
16-QAM, PRBS 9,
ROOT COSINE ALPHA 0.35,
30k SYM./SEC
LTC5599
LC
RECONSTRUCT
FILTERS
LOW POWER
IQ MODULATOR
RF OUT
−4 dBm RMS
Q
5th ORDER BESSEL
FULL SCHEMATIC IN FIGURE 4
OCCUPIED BW = 40.5kHz
Figure 4. Driving an IQ modulator with programmable logic and DACs. The passive Bessel filter attenuates DAC images and provides lowest RF output noise floor,
while imposing negligible symbol error vector.
VCC
MCU WITH
PROGRAMMABLE
LOGIC
UNMODULATED LO INPUT
0 dBm
VCC
VREF
1.74k
0.10µF
2.49k
VCC
133Ω
470µH
Vcc
I CH. DAC
0~1.024V
FULL-SCALE
1.47k
+1.4V
U2
LT6238
27nF
2.49k
2.49k
13nF
10nF
2.2nF
220µH
4.7nF
1nF
1nF
RL(I)
267Ω
VCC VCTRL EN
+1.4V
U2
133Ω
470µH
27nF
LT6238
GAIN SCALING
AND DC SHIFT
BBMI
SINGLE-ENDED
TO DIFFERENTIAL
DRIVER
VREF
1.74k
2.49k
133Ω
DAC LC RECONSTRUCTION FILTER
1.47k
+1.4V
U2
2.49k
LT6238
+1.4V
VOLTAGE
OUTPUT
DAC
VREF
2.49k
U2
LT6238
SPI
MASTER
2.49k
0.10µF
27nF
10nF
RF
2.2nF
SDI
SCLK
CSB
GNDRF
1.5nF
220µH
13nF
4.7nF
1nF
470µH
27nF
220µH
10nF
2.2nF
MODULATED
RF OUTPUT
RL(Q)
267Ω
133Ω
BESSEL RESPONSE, −3dB @ 50kHz
−0.7dB @ 20kHz
−44dB @ 220kHz
INDUCTORS: COILCRAFT DS1608C SERIES, OR EQUIVALENT
SPI BUS SETS MODULATOR CENTER FREQUENCY
22 | November 2015 : LT Journal of Analog Innovation
U3
LTC5599
BBPQ
1.82k
+1.4V
SDO
BBMQ
470µH
Q CH. DAC
0~1.024V
FULL-SCALE
LOL
TEMP
2.2nF
BBPI
U1
CY8C58LP
LOC
TTCK
220µH
10nF
39nH
15pF
VCC = 3.3V
10µF
GND
SPI BUS
54mA
design features
Digital interpolation is used to increase
the DAC clock frequency, and hence the
DAC image frequencies. This lowers the
filter order requirement of the LC reconstruct filter, which serves to attenuate DAC
images to acceptable levels, while minimizing phase error and wideband noise.
Figure 4 shows the complete circuit. The
differential baseband drive to the modulator, as opposed to single-ended baseband
drive, offers the highest RF output power
and lowest EVM. The LTC6238 low noise
amplifier, U2, converts the DAC singleended I and Q outputs to differential.2
Input amplifier U2 gain is designed to scale
the DAC out voltage range to the modulator input voltage range, after the 2:1 attenuation effect of filter terminating resistors
RL(I) and RL(Q) is taken into account. The
input amplifier U2 is also designed to
supply the required input common mode
voltage for the IQ modulator—important
for maintaining proper modulator
DC operating point and linearity.
Classical LC filter synthesis methods
are used for the DAC reconstruction
lowpass filter (LPF) design. Some of the
filter shunt capacitance is implemented
as common mode capacitors to ground.
This also reduces common mode noise,
which can find its way to the modulator output. If active filters are used here,
the final filter stage before the modulator should be a passive LC roofing filter
for lowest broadband RF noise floor.
Table 2, Figure 5 and Figure 6 show the
performance results. In this case, EVM
is limited by the digital accuracy of the
baseband waveforms, here determined by
MEASURED IQ VECTOR
EVM VS TIME
MEASURED EYE DIAGRAM
ERROR SUMMARY
Figure 5. EVM measurement detail. Two IC devices replace the lab signal generator. It’s not perfect, but is
usually ‘good enough.’
the number of U1 FIR filter taps (63), and
by the DAC resolution (eight bits). For
this reason, EVM does not substantially
improve when IQ modulator impairments are adjusted out, as shown in
Table 2. For lower EVM, use more FIR
filter taps and higher resolution DACs.
When comparing the results shown in
Figures 2 and 5, we see the price paid
for replacing a high grade lab signal
generator with a circuit composed of
programmable logic and op amp filters.
EVM increased from 0.24% RMS to 0.8%
RMS. The increased EVM is primarily due
to the fact that the waveforms generated
by the programmable logic IC are not as
accurate as the lab instrument. Such is
the case in a real world implementation,
but Figure 5 shows a fairly decent eye
diagram, and a summary measurement
that shows the modulation accuracy
is sufficient for most applications.
In Figure 6 we see the output spectrum is quite clean. The amplitude of
the DAC image spurs, relative to the
desired signal, is estimated by sin(x)/x,
where x = πf/fCLK , plus attenuation
afforded by the DAC LC reconstruct
filter. For lowest adjacent channel
power, a long FIR filter (many taps) is
essential, as is a low phase noise LO.
Table 2. EVM performance. Even with a 63-tap FIR filter design and 8-bit dual-DACs, the 0.8% RMS EVM achievement is entirely adequate for most applications.
TX FIR FILTER
DESIGN
INTERPOLATION
FACTOR
SYMBOL RATE
(ksps)
DATA RATE
(kbps)
63-tap RRC,
α = 0.35
8
30
120
EVM
(% RMS)
EVM
(% PEAK)
NOTES
0.8
2.0
LTC5599 Unadjusted (MER = 39.1dB)
0.8
1.8
LTC5599 Adjusted (MER = 39.8dB)
November 2015 : LT Journal of Analog Innovation | 23
Linear Technology’s LTC5599 IQ modulator is a versatile
RF building block, offering low power consumption,
high performance, wide frequency range and unique
optimization capabilities. It simplifies radio transmitter
design without sacrificing performance or efficiency.
Table 3. Output noise density levels off at
approximately 17dB over kTB.
0
−10
−20
AMPLITUDE (dBm)
Figure 6. Output spectrum.
In this design, the closest
image spurs are about 70dB
down, reasonably good for
most systems. Modulator
RMS output power measures
−4dBm. Harmonic filtering is
still required.
−30
RBW = 5kHz
DAC IMAGE SPURS, −70dBc:
−25dB FROM (sin x)/x
+ −45dB FROM LPF
−70dB TOTAL
−40
−50
−60
−70
FREQUENCY OFFSET
(MHz)
RF OUTPUT NOISE
DENSITY (dBM/Hz)
+6
−156.7
+10
−156.8
+20
−156.8
−80
−90
−100
449.5
450
FREQUENCY (MHz)
Higher frequency span sweeps show
no visible spurious products except
for the harmonics of the carrier,
which must be filtered as usual.
Low output noise floor is also important
in many cases, such as when a transmitter
and receiver are duplexed or co-located,
when high PA gain is used, or when
multiple transmitters run simultaneously.
Table 3 shows the measured output
noise density for the system of Figure 3,
while transmitting at a modulated carrier
frequency of 460MHz. The low U2 op amp
noise, combined with the 5th order roll-off
of the LC reconstruct filter, keeps the baseband noise contribution as low as possible.
450.5
Total current consumption at 3.3V
measures 96m A, as summarized in Table 4.
The majority of the DC power is consumed
by U1, the programmable logic device,
for which each DFB is specified to typically consume 21.8m A at the 67MHz
clock frequency of this application.3 In
summary, the DFBs account for 81% of
the digital power consumption. Clearly
the key to reduced current consumption for the digital section is optimization of the DFB architecture, which is
beyond the scope of this article.4
Linear Technology’s LTC5599 IQ modulator is a versatile RF building block,
offering low power consumption, high
performance, wide frequency range
and unique optimization capabilities. It
simplifies radio transmitter design without
sacrificing performance or efficiency. n
Notes
1Test
equipment FIR filters are synthesized in software,
so hundreds or thousands of filter taps are feasible and
preferred, since signal quality is most important, and
delay is inconsequential. In contrast, a real-time wireless
application typically requires trade-offs between filter
delay and EVM/ACP.
2For
lower symbol rate applications, the LTC1992 low
power fully differential input/output amplifier/driver could
also be used for this purpose, offering improved DC
accuracy and lower DC power consumption in exchange
for a higher transmit noise floor within the channel passband.
3In
Table 4. Total power consumption
STAGE
DESCRIPTION
ICC (mA)
POWER (mW)
U1
CY8C58LP Programmable System on Chip
54
178
U2
LT6238 Quad Op Amp
13
43
U3
LTC5599 Low Power IQ Modulator
29
96
Total:
96
317
24 | November 2015 : LT Journal of Analog Innovation
CONCLUSION
this example, the minimum DFB clock frequency =
30kHz symbol rate • 8x interpolation • 63 FIR filter taps
• 2 cycles for multiply and accumulate (MAC) • 2 cycles
for arithmetic logic (ALU) = 60.5MHz.
4DFBs
that are faster and more highly optimized are available from Altera and Xilinx.
References
1“Digital
Modulation in Communications Systems –
An Introduction,” Application Note 1298, Keysight
Technologies