AD7884AN データシートの表示(PDF) - Analog Devices
部品番号
コンポーネント説明
一致するリスト
AD7884AN Datasheet PDF : 16 Pages
| |||
AD7884/AD7885
If the noise in the converter is too high for an application, it can
be reduced by oversampling and digital filtering. This involves
sampling the input at higher than the required word rate and
then averaging to arrive at the final result. The very fast conver-
sion time of the AD7884/AD7885 makes it very suitable for
oversampling. For example, if the required input bandwidth is
40 kHz, the AD7884/AD7885 could be oversampled by a factor
of 2. This yields a 3 dB improvement in the effective SNR per-
formance. The noise performance in the ± 5 volt input range is
now effectively 85 µV rms and the resultant spread of codes for
2500 conversions will be four. This is shown in Figure 15.
1500
1000
500
16
15
14
13
12
11
10
0
20
40
60
80
FREQUENCY – kHz
Figure 17. Effective Number of Bits vs. Frequency
The effective number of bits for a device can be calculated from
its measured SNR. Figure 17 shows a typical plot of effective
number of bits versus frequency for the AD7884. The sampling
frequency is 166 kHz.
0
(X – 1) (X) (X + 1) (X + 2)
CODE
Figure 15. Histogram of 2500 Conversions of a DC Input
Using a ×2 Oversampling Ratio
Dynamic Performance
With a combined conversion and acquisition time of 6 µs, the
AD7884/AD7885 is ideal for wide bandwidth signal processing
applications. Signal to (Noise + Distortion), Total Harmonic
Distortion, Peak Harmonic or Spurious Noise and Intermodula-
tion Distortion are all specified. Figure 16 shows a typical
FFT plot of a 1.8 kHz, ± 5 V input after being digitized by the
AD7884/AD7885.
0
f IN = 1.8kHz, ± 5V SINE WAVE
fSAMPLE = 163kHz
–30
SNR = 87dB
THD = –95dB
–60
–90
–120
MICROPROCESSOR INTERFACING
The AD7884/AD7885 is designed on a high speed process
which results in very fast interfacing timing (Data Access Time
of 57 ns max). The AD7884 has a full 16-bit parallel bus, and
the AD7885 has an 8-bit wide bus. The AD7884, with its paral-
lel interface, is suited to 16-bit parallel machines whereas the
AD7885, with its byte interface, is suited to 8-bit machines.
Some examples of typical interface configurations follow.
AD7884 to MC68000 Interface
Figure 18 shows a general interface diagram for the MC68000,
16-bit microprocessor to the AD7884. In Figure 18, conversion
is initiated by bringing CSA low (i.e., writing to the appropriate
address). This allows the processor to maintain control over the
complete conversion process. In some cases it may be more
desirable to control conversion independent from the processor.
This can be done by using an external sampling timer.
A23 – A1
ADDRESS BUS
MC68000
DTACK
AS
R/W
D15 – D0
ADDRESS
DECODE LOGIC
CSB CSA
DATA BUS
AD7884
CONVST
CS
RD
DB15 – DB0
–150
2048 POINT FFT
Figure 16. AD7884/AD7885 FFT Plot
Effective Number of Bits
The formula for SNR (see Terminology section) is related to
the resolution or number of bits in the converter. Rewriting the
formula, below, gives a measure of performance expressed in
effective number of bits (N).
N = (SNR – 1.76)/6.02
Figure 18. AD7884 to MC68000 Interface
Once conversion has been started, the processor must wait until
it is completed before reading the result. There are two ways of
ensuring this. The first way is to simply use a software delay to
wait for 6.5 µs before bringing CS and RD low to read the data.
REV. C
–11–
Share Link: 