Seven Steps to Successful Analog-to-Digital Signal Conversion

Technical Article
MS-2022
.
Seven Steps to Successful
Analog-to-Digital Signal
Conversion (Noise Calculation
for Proper Signal Conditioning)
by Reza Moghimi, Applications Engineering Manager,
Analog Devices, Inc.
IDEA IN BRIEF
0B
High precision applications require a well-designed low
noise analog front end to get the best SNR, which requires
an informed approach to choosing an ADC to fully and
accurately capture sensor signals. Support components
such as driver op amps and references are selected to
optimize overall circuit performance.
R
eal-world signals, such as vibration, temperature,
pressure, and light, require accurate signal
conditioning and signal conversion before further
data processing in the digital domain. In order to
overcome many challenges in today’s high precision
applications, a well-designed low noise analog front end is
needed to get the best SNR. Many systems cannot afford the
most expensive parts, nor can they afford the higher power
consumption of low noise parts. This article addresses
questions about designing a total solution using a noiseoptimized approach. This article presents a methodical
approach to the design of a gain block and ADC
combination, including an example that supports this
approach. Noise calculation and analysis is performed on
this circuit when conditioning low frequency (near dc)
signals.
Figure 1. Typical signal conditioning chain.
Follow these seven steps when designing an analog front
end:
1) Describe the electrical output of the sensor or section
preceding the gain block.
2) Calculate the ADC’s requirements.
3) Find the optimal ADC + voltage reference for the signal
conversion.
4) Find the maximum gain and define search criteria for
the op amp.
5) Find the optimal amplifier and design the gain block.
6) Check the total solution noise against the design target.
7) Run simulation and validate.
Step 1: Describe the electrical output of the sensor or
section preceding the gain block
Signals can come directly from the sensor or may have gone
through EMI and RFI filters prior to the gain block. In order
to design the gain block, one needs to know the ac and dc
characteristics of the signal and the available power supplies.
Knowing the signal’s characteristic and noise level provides
clues as to what input voltage range and noise levels we
might need when selecting an ADC. Let’s assume that we
have a sensor that outputs a 10 kHz signal with full-scale
amplitude of 250 mV p-p (88.2 mV rms) and 25 μV p-p
noise. Let’s additionally assume that we have a 5 V supply
available in our system. With this information we should be
able to calculate the signal-to-noise ratio at the ADC’s input
in step 2. To simplify data crunching and confusion, assume
that we design this solution for room temperature operation.
Step 2: Calculate the ADC’s requirement
What type of ADC, what sample rate, how many bits, and
what noise specification do we need? By knowing the input
signal amplitude and noise information from step 1, we can
calculate the signal-to-noise ratio (SNR) at the gain block’s
input. We need to pick an ADC that has better signal-tonoise ratio. Knowing the SNR will help us to calculate the
effective number of bits (ENOB) when choosing the ADC.
This relationship is shown in the following equations. Both
SNR and ENOB are always specified in any good ADC
data sheet. In this example, the required 86.8 dB SNR and
14.2-bit ENOB force us to choose a 16-bit analog-to-digital
converter. Additionally the Nyquist criterion states that the
sampling rate, fs, should be at least twice the maximum
incoming frequency, fin, so a 20 kSPS ADC would suffice.
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Next, we need to design an overall solution with a noise
density that does not exceed 416 nV/√Hz. This places the
noise of the signal conditioning circuit at 1/10 of the input
noise.
250 mV
The AD7685 16-bit PulSAR® ADC is selected from the list.
This converter has 90 dB SNR and 250 kSPS sample rate to
suit our requirements. The ADR421/ADR431 precision
XFET® voltage references are recommended for use with this
ADC. The 2.5 V input range exceeds our 250-mV p-p input
specification
SNR = 20 log(( 2 2 )) = 86.8 dB
25 uV / 6
ENOB =
Noise =
86.8 − 1.76
= 14.2 bits
6.02
25 uV
6
oversampling) will yield 16-bit noise performance. In our
example, this means a 12-bit ADC with 5.126 MHz sample
rate (20 kSPS × 256). Or, a 14-bit ADC oversampled by 42; or
1.28 MSPS might be better. These cost as much, however, as
the AD7685 16-bit, 250 kSPS ADC.
= 4.16 μV
ADC_Input_rms =
Step 3: Find the optimal ADC + voltage reference to do
the signal conversion
ADC_Noise_rms =
= 884 mV
884 mV
90
ADC_Noise_allowed =
= 27.95 μV
27.95 uV
Noise _ rms
=
1
125 kHz
f
2 sample
= 79 nV / Hz
The AD7685’s reference input has dynamic input
impedance, so it should be decoupled with minimal parasitic
inductances by placing a ceramic decoupling capacitor close
to the pins and connecting it with wide, low impedance
traces. A 22 μF ceramic chip capacitor will provide optimum
performance.
Figure 2. Typical ADC selection table.
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2 2
10 20
Having a set of search criteria on hand, there are many ways
to find the ADC that can fit the requirements. One of the
easiest ways to find a 16-bit ADC is to use the search tool on
the manufacturer’s site. By entering resolution and sample
rate, a number of choices are suggested.
Many 16-bit ADCs specify 14.5 bits of ENOB. If you would
like to have better noise performance, use oversampling to
push the ENOB up to 16 bits (n-bit improvement is obtained
from 4n oversampling). With oversampling, one could use a
lower resolution ADC: a 12-bit ADC oversampled by 256 (44
2. 5 V
May 2011 | Page 2 of 5
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MS-2022
Step 4: Find the maximum gain and define search
criteria for the op amp
Knowing the input voltage range of the ADC will help us in
designing the gain block. To maximize our dynamic range,
we need to take the highest gain possible with the given
input signal and ADC’s input range. This means that we can
design our gain blocks to have a gain of 10 for the example
on hand.
Vin = 250 mVpp
How much noise is allowed at the input of the opamp?
Remember that we need to design an overall solution whose
noise density does not exceed 416 nV/rt-Hz. We should
design a gain block that has much lower noise floor, say by a
factor of 10 since we gain up by 10. This will ensure that
noise from amplifier is much less than the noise floor of the
sensor. To calculate the noise margin, we can roughly
assume that the noise at the input of the op amp is the total
noise of the op amp plus the noise of the ADC.
VRTI = 416 nV /10 = 41.6 nV/ Hz
ADC _ input _ range = 2.5 V
ADCnoise _ RTI = 79 nV /10 = 7.9 nV/ Hz
Opamp _ Gain = 10
Opampnoise _ RTI allowed = (41.6 nV)2 − (7.9 nV)2
BW = 1 Hz − 10 kHz
Although the AD7685 is easy to drive, the driver amplifier
needs to meet certain requirements. For example, the noise
generated by the driver amplifier needs to be kept as low
as possible to preserve the SNR and transition noise
performance of the AD7685, but remember that the gain
block amplifies both signal and noise together. To keep the
noise at the same level before and after the gain block, we
need to select an amplifier and components that have much
lower noise. The driver should also have THD performance
commensurate with the AD7685 and must settle a full-scale
step onto the ADC’s capacitor array at a 16-bit level
(0.0015%). The noise coming from the amplifier can be
further filtered by an external filter.
= 40.8 nV/ Hz
Step 5: Find the best amplifier and design the gain block
The first order of op amp selection after knowing the input
signal bandwidth is to pick an op amp that has an acceptable
gain-bandwidth product (GBWP) and that can process this
signal with minimum amount of dc and ac errors. To get the
best gain bandwidth product, the signal bandwidth, noise
gain, and gain error are required. These terms are all defined
below. As a guide, pick an amplifier that has gain bandwidth
greater than 100 times the input signal BW if you want to
keep the gain error below 0.1%. Additionally, we need an
amplifier that settles quickly and has good drive capability.
Remember that our noise budget requires the overall noise
VCC
V2 +
5V
U6
–
R3
1.47kΩ
AVDD DVDD
3
U5
V+
2
6
OEN
VOUT
R4
14.7Ω
CLOCK
V–
C3
0.47µF
AD8641
VINB
REF_IN
REF_OUT
REF_GND
VCC
250mV p-p
V5 +
2.5V
VIN
R1
1.47kΩ
R2
13.3kΩ
VINA
U7
VS
V1
CF
0.47nF
ADR421
GND
–
OUT
C4
10nF
AD7685
MSB
MSB
BIT2
BIT3
BIT4
BIT5
BIT6
BIT7
BIT8
BIT9
BIT10
BIT11
BIT12
BIT13
BIT14
BIT15
BIT16
OTR
AGND
Figure 3. Complete solution.
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Technical Article
at the input of the op amp to be less than 40.8 nV/√Hz, while
the ADC specifies 7.9 nV/√Hz. To summarize the search
criteria for the op amp: UGBW > 1 MHz, single 5 V supply,
good voltage noise, current noise, and THD specs, low dc
errors not to degrade ADC’s specs.
Noise _ Gain = 1 +
We can calculate the total noise at the input of the op amp
and make sure that it is less than the 41.6 nV/√Hz as we had
planned.
VRTI _ Produced _ by _ amplifier = 29.3 nV/ Hz
R2
R1
VRTI _ Produced _ by _ ADC = 7.9 nV/ Hz
Total _ design _ noise _ achieved
BW = 1.57 f closed _ loop _ BW
= (29.3 nV)2 + (7.9 nV)2
Noise _@_ Vout = NoiseRTI × Noise _ Gain
= 30.5 nV/ Hz
Using a similar approach to the ADC search, the AD8641 is
picked for our example. The AD8641 low power, precision
JFET input amplifiers feature extremely low input bias
current and rail-to-rail output that can operate with supplies
of 5 V to 26 V. Its relevant specs are stated in the table below.
We can configure the op amp in a noninverting
configuration with the component values shown in the table.
To integrate the total noise over the entire bandwidth, we can
see that the total noise at the input of the ADC over the
filter’s bandwidth is 3.05 μV, which is less than the 4.16 μV
requirement of our design. The low frequency noise (1/f) is
ignored in this case since the corner frequency of the AD8641 is
below 100 Hz.
VRTI _ Produced _ by _ amplifier _ ckt _ over _ 10kHz
All active and passive components generate noise of their
own, so it is important to choose components that do not
degrade performance. As an example, it is wasteful to buy a
low noise op amp and surround it with large resistors.
Remember that a 1-kΩ resistor has 4 nV of noise.
= 2.93 μV
VRTI _ Produced _ by _ ADC _ noise _ over _ 10kHz
= 780 nV
As mentioned earlier, an optional RC filter can be used
between the ADC and this gain block, which should help in
narrowing BW and improving SNR.
Total _ design _ at _ input _ over _ 10kHz
= (2.93 μV)2 + (780 nV)2 = 3.04 μV / Hz
Table 1. Component values for complete
solution shown in Figure 3
Component
R1
R2
R3
En
In
Cf
Total _ noise _ at _ ADC _ input _ over _ 10kHz
= 30.4 uV
Value
1.47 kΩ
13.3 kΩ
1.47 kΩ
28.5 nV/√Hz
50 fA/√Hz
0.47 nF
Step 6: Check total solution noise against your design
targets
Maintaining a good signal-to-noise ratio requires paying
attention to the noise of every element in the signal path and
good PCB layout. Avoid running digital lines under any
ADC because these couple noise onto the die, unless a
ground plane under the ADC is used as a shield. Fast
switching signals, such as CNV or clocks, should never run
near analog signal paths. Crossover of digital and analog
signals should be avoided.
It is extremely important to have a good understanding of all
the error sources in the designed circuit. In order to achieve
the best SNR, we need to write out the overall noise equation
for the above solution. This is shown in the equation below.
NoiseRTI = BW Vn2 + 4 KTR1[
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R2 2
R1 × R2 2
R1 2
] + In+ 2 R32 + In−2[
] + 4 KTR2[
]
R2 + R1
R1 + R2
R1 + R2
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Step 7: Run simulation and validate
Summary
Using PSpice Macro-models, downloadable from the ADI
site, can be a good starting point for validation of any circuit
design. A quick simulation shows the signal bandwidth
for which we designed our solution. Figure 4 shows the
response before and after the optional RC filter at the input
of the AD7685.
With today's low power, cost conscious designs, many
systems cannot afford the most expensive parts, nor can they
afford the higher power consumption of low noise parts. To
attain the lowest noise floor and best performance from
signal conditioning circuitry, designers must understand
component level noise sources. Maintaining a good signalto-noise ratio requires attention to the noise of every
element in the signal path. By following the above steps, one
can successfully condition a small analog signal and convert
it using a very high resolution ADC.
REFERENCES
1. Application Note AN-202, An IC Amplifier User’s Guide
to Decoupling, Grounding, and Making Things Go Right
for a Change. Analog Devices.
Figure 4. Bandwidth simulation of circuit in Figure 3.
As shown in Figure 5, the total output noise over the 10 kHz
bandwidth is close to 31 μV rms. This is less than the design
target of 41 μV rms. Bench prototypes needs to be built, and
the whole solution has to get validated before full
production.
2. Application Note AN-347, How to Exclude InterferenceType Noise, What to Do and Why to Do It—A Rational
Approach. Analog Devices.
3. Barrow, J., and A. Paul Brokaw. 1989. “Grounding for
Low- and High-Frequency Circuits,” Analog Dialogue.
(23-3) Analog Devices.
4. Seminar: Noise Optimization in Sensor Signal
Conditioning Circuits, Part 1.
5. Seminar: Noise Optimization in Sensor Signal
Conditioning Circuits, Part 2.
RESOURCES
Figure 5. Simulation for noise response of circuit in Figure 3.
For online seminars on this and related subjects, visit
www.analog.com/seminars.
Products Mentioned in This Article
Product
AD7685
AD8641
Description
16-Bit, 250 kSPS PulSAR® ADC in MSOP/QFN
Low Power, Rail-to-Rail Output Precision JFET Amp
One Technology Way • P.O. Box 9106 • Norwood, MA 02062-9106, U.S.A.
Tel: 781.329.4700 • Fax: 781.461.3113 • www.analog.com
Trademarks and registered trademarks are the property of their
respective owners.
T09517-0-5/11(0)
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