SSM2161S Просмотр технического описания (PDF) - Analog Devices
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SSM2161S Datasheet PDF : 16 Pages
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SSM2160/SSM2161
present the attenuation and gain as two separate items, in fact,
the VCA can be operated smoothly from a gain condition to an
attenuation. The master and channel step sizes default to 1 dB
in the absence of external components. The step sizes can be
changed by the addition of external resistors if finer resolution is
desired.
Control Range vs. Step Size
Before adjusting step sizes from the standard 1 dB, consider the
effect on control range. The master control and the channel
control provide 1 dB step sizes, which may be modified by the
addition of external resistors. As the total number of steps is
unchanged, reduction of the step size results in less control
range. The range of the control is:
Range = Step Size (dB) × (Number of Levels Used)
Since the master volume control operates from a 7-bit word, its
DAC has 128 levels (including 0). The channel volume control
DAC is a 5-bit input, so there are 32 levels for volume control
(including 0). As can be seen in Figure 21, the practical control
range is set by the noise floor. It can be advantageous to reduce
the master step size to give finer steps from zero attenuation
down to the noise floor.
Reducing Master Step Size
To reduce the master step size, place a resistor, RM, between
MSTR SET and MSTR OUT. The master step size of the
master volume control will then become:
RM
= 1700 X MASTER
1 – X MASTER
where, XMASTER is the desired master control step size in
decibels. See Figure 22 for practical values of RM. Note that
the step size for the master control can only be adjusted to less
than 1 dB. No resistor is required for the default value of 1 dB
per step. For larger step sizes, use digital control. Noninteger
dB step sizes can be obtained by using digital control and a
reduced step size.
1.0
0.8
0.6
0.4
0.2
0
102
103
104
105
RMASTER
Figure 22. Master Step Size vs. RM
Example: Modifying Master Step Size to 0.5 dB
A master step size of 0.5 dB is desired for the master control,
while a 1 dB step size is adequate for the channel control. Using
the above equation or Figure 22, RM is found to be 1700 Ω and
is connected between MSTR SET and MSTR OUT. There
could be some variation from lot to lot, so applications requiring
precise step size should include a fixed plus a trimmer to span
the calculated value ± 25%. In this example, RC is not needed
as the default channel step size is already 1 dB. CH SET is left
floating. With this step size, the dynamic range of the master
control is:
DNR = 0.5 × 127 dB = 63.5 dB
In this configuration, the maximum master volume is 0 dB,
while the minimum volume is –63.5 dB. Since the channel
volume can still provide 0 dB to 31 dB of gain, the total system
gain can vary between –63.5 dB and 32 dB. Note that a 0 dB
command setting to the master control always results in unity
gain, regardless of the step size.
Channel Step Size
The channel DACs’ full-scale current is set by an internal
resistor to the V+. By shunting this resistor, the full-scale
current, and therefore the step size, will increase. No provisions
are available for reducing the channel step size. To increase the
channel step size, place a resistor, RC, from CH SET to V+.
Note that a 0 dB setting for a channel will always give unity
gain, regardless of how large or small the step size is. This is
true for both the master and channel volume controls.
1.5
1.4
1.3
1.2
1.1
1.0
101
102
103
RCHAN
Figure 23. Channel Step Size vs. RC
Example: Modifying Channel Step Size
A channel step size of 1.3 dB is desired. From Figure 23 we see
that a 40 Ω resistor (approximately) connected from CH SET to
V+ is required. As this varies from lot to lot, the exact value
should be determined empirically, or a fixed resistor plus
trimmer potentiometer should be used. Take care not to short
Pin 24 to Pin 1 as damage will result.
Muting
The SSM2160 offers master and channel muting. On power
up, the master mute is activated, thus preventing any transients
from entering the signal path and possibly overloading amplifi-
ers down the signal path. Mute is typically better than –95 dB
relative to a 0 dBu input. Due to design limitations, the individual
channel muting results in increased signal distortion in the
unmuted channels. Users should determine if this condition is
acceptable in the particular application.
REV. 0
–11–
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