AD7575 Ver la hoja de datos (PDF) - Analog Devices
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AD7575 Datasheet PDF : 12 Pages
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AD7575
CS
t1
t5
RD
t4
t2
BUSY
t3
DATA
HIGH
IMPEDANCE BUS
t7
OLD
DATA
t8
t3
HIGH IMPEDANCE
BUS
t7
NEW
DATA
HIGH IMPEDANCE
BUS
Figure 5. ROM Interface Timing Diagram
Figures 6 and 7 show connection diagrams for interfacing the
AD7575 in the ROM Interface mode. Figure 6 shows the
AD7575 interface to the 6502/6809 microprocessors while the
connection diagram for interfacing to the Z-80 is shown in
Figure 7.
As a result of its very fast interface timing, the AD7575 can also
be interfaced to the DSP processor, the TMS32010. The
AD7575 will (within specifications) interface to the TMS32010,
running at up to 18 MHz, but will typically work over the full
clock frequency range of the TMS32010. Figure 8 shows the
connection diagram for this interface. The AD7575 is mapped
at a port address. Conversion is initiated using an IN A, PA
instruction where PA is the decoded port address for the
AD7575. The conversion result is obtained from the part using
a second IN A, PA instruction, and the resultant data is placed
in the TMS32010 accumulator.
In many applications it is important that the signal sampling
occurs at exactly equal intervals to minimize errors due to sam-
pling uncertainty or jitter. The interfaces outlined previously
require that for sampling at equidistant intervals, the user must
count clock cycles or match software delays. This is especially
difficult in interrupt-driven systems where uncertainty in inter-
rupt servicing delays would require that the AD7575 have prior-
ity interrupt status and even then redundant software delays
may be necessary to equalize loop delays.
This problem can be overcome by using a real time clock to
control the starting of conversion. This can be derived from the
clock source used to drive the AD7575 CLK pin. Since the
sampling instant occurs three clock cycles after CS and RD go
LOW, the input signal sampling intervals are equidistant. The
resultant data is placed in a FIFO latch that can be accessed by
the microprocessor at its own rate whenever it requires the data.
This ensures that data is not READ from the AD7575 during a
conversion. If a data READ is performed during a conversion,
valid data from the previous conversion will be accessed, but the
conversion in progress may be interfered with and an incorrect
result is likely.
If CS and RD go LOW within 20 ns of a falling clock edge, the
AD7575 may or may not see that falling edge as the first of the
three falling clock edges to the sampling instant. In this case, the
sampling instant could vary by one clock period. If it is impor-
tant to know the exact sampling instant, CS and RD should not
go LOW within 20 ns of a falling clock edge.
A0–A15
6502/6809
R/W
2 OR E
ADDRESS BUS
+5V
ADDRESS
DECODE
EN
TP
CS AD7575*
RD
DB0–DB7
D0–D7
DATA BUS
*LINEAR CIRCUITRY OMITTED FOR CLARITY
Figure 6. AD7575 to 6502/6809 ROM Interface
Z–80
MREQ
RD
ADDRESS BUS
+5V
ADDRESS
DECODE
EN
TP
CS AD7575*
RD
DB7
DB0
DB7
DB0
DATA BUS
*LINEAR CIRCUITRY OMITTED FOR CLARITY
Figure 7. AD7575 to Z-80 ROM Interface
PA2
PA0
TMS32010
MEN
DEN
ADDRESS BUS
+5V
ADDRESS
DECODE
EN
TP
CS AD7575*
RD
DB7
DB0
D7
DATA BUS
D0
*LINEAR CIRCUITRY OMITTED FOR CLARITY
Figure 8. AD7575 to TMS32010 ROM Interface
–6–
REV. B
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