AD7837/AD7847
REV. C
–10–
DIGITAL INPUT CODE N
A
0.6
1 4095
TOTAL POWER VARIATION – dB
358430722560204815361024512
0.5
0.4
0.3
0.2
0.1
0.0
Figure 19. Power Variation for Circuit in Figure 9
APPLYING THE AD7837/AD7847
General Ground Management
AC or transient voltages between the analog and digital grounds
i.e., between AGNDA/AGNDB and DGND can cause noise
injection into the analog output. The best method of ensuring
that both AGNDs and DGND are equal is to connect them
together at the AD7837/AD7847 on the circuit board. In more
complex systems where the AGND and DGND intertie is on the
backplane, it is recommended that two diodes be connected in
inverse parallel between the AGND and DGND pins (1N914 or
equivalent).
Power Supply Decoupling
In order to minimize noise it is recommended that the V
DD
and
the V
SS
lines on the AD7837/AD7847 be decoupled to DGND
using a 10 µF in parallel with a 0.1 µF ceramic capacitor.
Operation with Reduced Power Supply Voltages
The AD7837/AD7847 is specified for operation with V
DD
/V
SS
=
±15 V ± 5%. The part may be operated down to V
DD
/V
SS
=
±10 V without significant linearity degradation. See typical
performance graphs. The output amplifier however requires
approximately 3 V of headroom so the V
REF
input should not
approach within 3 V of either power supply voltages in order to
maintain accuracy.
MICROPROCESSOR INTERFACING–AD7847
Figures 20 to 22 show interfaces between the AD7847 and three
popular 16-bit microprocessor systems, the 8086, MC68000 and
the TMS320C10. In all interfaces, the AD7847 is memory-
mapped with a separate memory address for each DAC latch.
AD7847–8086 Interface
Figure 20 shows an interface between the AD7847 and the 8086
microprocessor. A single MOV instruction loads the 12-bit word
into the selected DAC latch and the output responds on the ris-
ing edge of WR.
ANALOG PANNING CIRCUIT
In audio applications it is often necessary to digitally “pan” or
split a single signal source into a two-channel signal while main-
taining the total power delivered to both channels constant. This
may be done very simply by feeding the signal into the V
REF
input of both DACs. The digital codes are chosen such that the
code applied to DAC B is the two's complement of that applied
to DAC A. In this way the signal may be panned between both
channels as the digital code is changed. The total power varia-
tion with this arrangement is 3 dB.
For applications which require more precise power control the
circuit shown in Figure 18 may be used. This circuit requires
the AD7837/AD7847, an AD712 dual op amp and eight equal
value resistors.
Again both channels are driven with two's complementary data.
The maximum power variation using this circuit is only 0.5 dBs.
V
OUTA
V
REFA
V
IN
RL
B
AD7837/
AD7847
1/2
AD712
R
R
R
R
RR
RR
1/2
AD712
RL
A
V
OUTB
V
OUTA
V
OUTB
V
REFB
Figure 18. Analog Panning Circuit
The voltage output expressions for the two channels are as
follows:
V
OUTA
= –V
IN
N
A
2
12
+ N
A
V
OUT B
= –V
IN
N
B
2
12
+ N
B
where N
A
= DAC A input code in decimal (1 ≤ N
A
≤ 4095)
and N
B
= DAC B input code in decimal (1 ≤ N
B
≤ 4095)
with N
B
= 2s complement of N
A
.
The two's complement relationship between N
A
and N
B
causes
N
B
to increase as N
A
decreases and vice versa.
Hence N
A
+ N
B
= 4096.
With N
A
= 2048, then N
B
= 2048 also; this gives the balanced
condition where the power is split equally between both chan-
nels. The total power variation as the signal is fully panned from
Channel B to Channel A is shown in Figure 19.