ADADC85S12 Ver la hoja de datos (PDF) - Analog Devices
Número de pieza
componentes Descripción
Fabricante
ADADC85S12 Datasheet PDF : 12 Pages
| |||
AD ADC84/AD ADC85
CLOCK RATE CONTROL ALTERNATE
CONNECTIONS
If adjustment of the CLOCK RATE is desired for faster conver-
sion speeds, the CLOCK RATE CONTROL may be connected
to an external multiturn trim potentiometer with a TCR of
±100 ppm/°C or less as shown in Figure 14 and Figure 15. If the
potentiometer is connected to –15 V, conversion time can be
increased as shown in Figure 5. If these adjustments are used,
delete the connections shown in Table 2 for Pin 17. See Figure 2
for nonlinearity error versus conversion speed and Figure 5 for
the effect of the control voltage on clock speed.
Figure 14. 12-Bit Clock Rate Control Optional Fine Adjust
significant bits in one byte and the 4 LSBs in the high nibble of
another byte. The data now represents the fractional binary
number relating the analog signal to the full-scale voltage. An
advantage to this organization is that the most-significant eight
bits can be read by the processor as a coarse indication of the
true signal value. The full 12-bit word can then be read only
when all 12 bits are needed. This allows faster and more
efficient control of a process.
Figure 16 shows a typical connection of 8085-type bus, using a
left-justified data format for unipolar inputs. Status polling is
optional, and can be read simultaneously with the 4LSBs. If it is
desired to right-justify the data, pins 1 through 12 of the
ADADC84/AD ADC85 should be reversed, as well as the
connections to the data bus high and low byte address signals.
When dealing with bipolar inputs (±5V, ±10V ranges), using the
MSB directly yields a complementary offset binary-coded
output. If complementary twos complement coding is desired, it
can be produced be substituting MSB (Pin 13) for the MSB.
This facilitates the arithmetic operation which are subsequently
performed on the ADC output data.
Figure 15. 8-Bit Clock Rate Control Optional Fine Adjust
MICROPROCESSOR INTERFACING
The fast conversion times of the AD ADC84/AD ADC85
suggests several methods of interface to microprocessors. In
systems where the ADC is used for high sampling rates on a
single signal which is to be digitally processed, CPU-controlled
conversion may be inefficient due to the slow cycle times of
most microprocessors. It is generally preferable to perform
conversions independently, inserting the resultant digital data
directly into memory. This can be done using direct memory
access (DMA), which is totally transparent to the CPU. Interface
to user-designed DMA hardware is facilitated by the guaranteed
data validity on the falling edge of the EOC signal.
Clearly, 12 bits of data must be broken up for interface to a 8-bit
wide data bus. There are two possible formats: right-justified
and left-justified. In a right-justified system, the least significant
8 bits occupy one byte and the four MSBs reside in the low
nibble of another byte. This format is useful when the data from
the ADC is being treated as a binary number between 0 and
4095. The left-justified format supplies the eight most-
Figure 16. AD ADC84/AD ADC85 – 8085A Interface Connections
Rev. B | Page 10 of 12
Share Link: 