Applications information – Rainbow Electronics ADC10664 User Manual

Applications Information

(Continued)

ic characteristics such as signal-to-noise ratio (SNR) and
total harmonic distortion (THD) are quantitative measures
of this capability

An A D converter’s AC performance can be measured us-
ing Fast Fourier Transform (FFT) methods A sinusoidal
waveform is applied to the A D converter’s input and the
transform is then performed on the digitized waveform The
resulting spectral plot might look like the ones shown in the
typical performance curves The large peak is the funda-
mental frequency and the noise and distortion components
(if any are present) are visible above and below the funda-
mental frequency Harmonic distortion components appear
at whole multiples of the input frequency Their amplitudes
are combined as the square root of the sum of the squares
and compared to the fundamental amplitude to yield the
THD specification Guaranteed limits for THD are given in
the table of Electrical Characteristics

Signal-to-noise ratio is the ratio of the amplitude at the fun-
damental frequency to the rms value at all other frequen-
cies excluding any harmonic distortion components Guar-
anteed limits are given in the Electrical Characteristics table
An alternative definition of signal-to-noise ratio includes the
distortion components along with the random noise to yield
a signal-to-noise-plus-distortion ration or S (N a D)

The THD and noise performance of the A D converter will
change with the frequency of the input signal with more
distortion and noise occurring at higher signal frequencies
One way of describing the A D’s performance as a function
of signal frequency is to make a plot of ‘‘effective bits’’ ver-

sus frequency An ideal A D converter with no linearity er-
rors or self-generated noise will have a signal-to-noise ratio
equal to (6 02n a 1 8) dB where n is the resolution in bits
of the A D converter A real A D converter will have some
amount of noise and distortion and the effective bits can be
found by

n (effective) e

S (N a D) (dB) b 1 8

6 02

where S (N a D) is the ratio of signal to noise and distor-
tion which can vary with frequency

As an example an ADC10662 with a 4 85 V

P-P

100 kHz

sine wave input signal will typically have a signal-to-noise-
plus-distortion ratio of 59 2 dB which is equivalent to 9 53
effective bits As the input frequency increases noise and
distortion gradually increase yielding a plot of effective bits
or S (N a D) as shown in the typical performance curves

8 0 SPEED ADJUST

The speed adjust pin is connected to an on-chip current
source that determines the converter’s internal timing By
connecting a resistor between the speed adjust pin and
ground as shown in

Figure 4

the internal programming cur-

rent is increased which reduces the conversion time The
ADC10662 and ADC10664 are specified and guaranteed for
operation with R

SA

e

14 0 kX (Mode 1) or R

SA

e

8 26k

(Mode 2) Smaller resistors will result in faster conversion
times but linearity will begin to degrade as R

SA

becomes

smaller (see curves)

13