NSC LMC1983

LMC1983
Digitally-Controlled Stereo Tone and Volume Circuit with
Three Selectable Stereo Inputs
General Description
The LMC1983 is a monolithic integrated circuit that provides
volume, balance, tone (bass and treble), loudness controls
and selection between three pairs of stereo inputs. These
functions are digitally controlled through a three-wire communication interface. There are two digital inputs for easy interface to other audio peripherals such as stereo decoders.
The LMC1983 is designed for line level input signals
(300 mV–2V) and has a maximum gain of −0.5 dB. Volume
is set at minimum and tone controls are flat when supply voltage is first applied.
Low noise and distortion result from using analog switches
and poly-silicon resistor networks in the signal path.
Additional tone control can be achieved using the LMC835
stereo 7-band graphic equalizer connected to the
LMC1983’s SELECT OUT/SELECT IN external processor
loop.
Features
n Low noise and distortion
n
n
n
n
n
n
n
n
n
n
n
Three pairs of stereo inputs
Loudness compensation
40 position 2 dB/step volume attenuator plus mute
Independent left and right volume controls
Low noise-suitable for use with DNR ® and Dolby ® noise
reduction
External processor loop
Signal handling suitable for compact discs
Pop-free switching
Serially programmable: INTERMETAL bus (IM) interface
6V to 12V single supply operation
28 Pin DIP or PLCC Package
Applications
n
n
n
n
n
Stereo television
Music reproduction systems
Sound reinforcement systems
Electronic music (MIDI)
Personal computer audio control
Block Diagram
DS011279-1
DNR ® is a registered trademark of National Semiconductor Corporation.
Dolby ® is a registered trademark of Dolby Labs.
© 1999 National Semiconductor Corporation
DS011279
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LMC1983 Digitally-Controlled Stereo Tone and Volume Circuit with Three Selectable Stereo
Inputs
August 1992
Absolute Maximum Ratings
(Notes 1,
Lead Temperature
N Package,
(Soldering, 10 Seconds)
V Package,
(Vapor Phase, 60 Seconds)
Infrared, (15 Seconds)
ESD Susceptability (Note 5)
2)
If Military/Aerospace specified devices are required,
please contact the National Semiconductor Sales Office/
Distributors for availability and specifications.
Supply Voltage (V+ − GND)
Voltage at any Pin
Input Current at any Pin
(Note 3)
Package Input Current (Note 3)
Power Dissipation (Note 4)
Junction Temperature
Storage Temperature
15V
GND − 0.2V to V+ + 0.2V
+260˚C
215˚C
220˚C
2 kV
Operating Ratings (Notes 1, 2)
5 mA
20 mA
500 mW
+125˚C
−65˚C to +150˚C
Temperature Range
LMC1983CIN, LMC1983CIV
Supply Voltage Range (V+ − V−)
TMIN ≤ TA ≤ TMAX
−40˚C ≤ TA ≤ +85˚C
6V to 12V
Electrical Characteristics
The following specifications apply for V+ = 9V, fIN = 1 kHz, input signal (300 mV) applied to INPUT 1, volume = 0 dB, bass =
0 dB, treble = 0 dB, and loudness is off unless otherwise specified. All limits apply for TA = TJ = +25˚C.
Symbol
Parameter
Conditions
IS
Supply Current
VIN
Input Voltage
Clipping Level (1.0% THD),
THD
Total Harmonic Distortion
Left and Right channels;
Typical
Limit
Unit
(Note 6)
(Note 7)
(Limit)
15
25
mA (max)
2.3
2.0
Vrms (min)
0.008
0.1
% (max)
0.4
1.0
% (max)
0.5
1.0
% (max)
0.07
0.5
% (max)
Select Out (Pins 7, 22)
Output Pins 13, 16
VIN = 0.3 Vrms;
fIN = 100 Hz, 1 kHz, 10 kHz
VIN = 2.0 Vrms;
fIN = 100 Hz, 1 kHz
VIN = 2.0 Vrms;
fIN = 10 kHz
VIN = 0.5 Vrms; Bass and Treble
Tone Controls Set at Maximum
VIN = 0.3 Vrms; Volume
0.06
0.15
% (max)
Tone Controls Set at Maximum
VIN = 0.3 Vrms; between Any
2.0
4.0
mV (max)
Two Adjacent Control Settings
VIN = 0.3 Vrms;
18
20
mV (max)
Pins 7, 22, (470Ω to Ground at Input)
150
200
Ω (max)
Pins 13, 16
26
40
Ω (max)
AC Input Impedance
Pins 4, 5, 23, 24, 25
50
72
kΩ (max)
35
kΩ (min)
Volume Attenuator Range
Pins 13, 16; Volume
0.5
1.5
dB (max)
Attenuator at −20 dB, Bass and Treble
DC Shifts
All Mode and Input Positions
ROUT
RIN
AC Output Impedance
Attenuation at
0100010XXX000000 (0 dB)
0100010XXX101XXX (80 dB);
80
(Relative to Attenuation at
78
dB (min)
82
dB (max)
the 0 dB Setting)
Volume Step Size
All Volume Attenuation Settings from
0100010XXX101XXX (80 dB) to
0100010XXX000000 (0 dB) (Note 9)
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2
2.0
1.5
dB (min)
2.5
dB (min)
Electrical Characteristics
(Continued)
The following specifications apply for V+ = 9V, fIN = 1 kHz, input signal (300 mV) applied to INPUT 1, volume = 0 dB, bass =
0 dB, treble = 0 dB, and loudness is off unless otherwise specified. All limits apply for TA = TJ = +25˚C.
Symbol
Parameter
Conditions
Typical
Limit
Unit
(Note 6)
(Note 7)
(Limit)
± 0.1
± 1.5
dB (min)
± 2.0
dB (min)
105
86
dB (max)
± 12
dB (max)
± 0.1
± 10.0
± 14.0
± 1.5
2.0
1.5
dB (min)
2.5
dB (max)
dB (max)
± 0.1
± 10.0
± 14.0
± 1.5
2.0
1.5
dB (min)
2.5
dB (max)
± 0.1
± 1.0
dB (max)
11.5
13.5
dB (max)
All Volume Attenuation Settings from
Channel-to-Channel
0100010XXX100110 (76 dB) to
Tracking Error
0100010XXX000000 (0 dB)
from
0100010XXX101XXX (80 dB) to
0100010XXX100111 (78 dB)
Mute Attenuation
Bass Gain Range
VIN = 1.0 Vrms
fIN = 100 Hz, Pins 13, 16
Bass Step Size
fIN = 100 Hz, Pins 13, 16
fIN = 100 Hz, Pins 13, 16
Treble Gain Range
(Relative to Previous Level)
fIN = 10 kHz, Pins 13, 16
Bass Tracking Error
Treble Tracking Error
Treble Step Size
fIN = 10 kHz, Pins 13, 16
fIN = 10 kHz, Pins 13, 16
± 12
(Relative to Previous Level)
Frequency Response
Loudness
VIN Applied to Input 1 and Input 2;
fIN = 20 Hz − 20 kHz
dB (min)
dB (max)
dB (min)
dB (max)
(Relative to Signal Amplitude at 1 kHz)
Volume Attenuator = 40 dB, Loudness
on (See Figure 5 )
Gain at 100 Hz (Referenced
to Gain at 1 kHz)
9.5
dB (min)
8.5
dB (max)
Gain at 10 kHz (Referenced
6.5
to Gain at 1 kHz)
VIN = 1.0 Vrms, A Weighted,
Measured at 1 kHz, RS = 470Ω
4.5
dB (min)
Signal-to-Noise Ratio
95
90
dB (min)
Channel Balance
All Volume Settings
0.2
1.0
dB (max)
Channel Separation
Input Pins 4, 25: Output Pins 13, 16;
VIN = 1.0 Vrms (Note 8)
80
60
dB (min)
Input-Input Isolation
470Ω to AC Ground on Unused Input
V+ = 9 VDC; 200 mVrms, 100 Hz
Sinewave Applied to Pin 26
95
60
dB (min)
32
28
dB (min)
PSSR
Power Supply Rejection
Ratio
fCLK
Clock Frequency
VIN(1)
Logic “1” Input Voltage
5.0
1.0
MHz (max)
Pins 1, 27, 28 (IM Bus)
1.3
2.0
V (min)
Pins 2, 3
2.9
5.5
V (min)
0.8
V (max)
3.5
V (max)
VIN(0)
Logic “0” Input Voltage
Pins 1, 27, 28 (IM Bus)
0.4
Pins 2, 3
1.2
VOUT(1)
Logic “1” Output Voltage
Pin 28 (IM Bus)
VOUT(0)
Logic “0” Output Voltage
Pin 28 (IM Bus)
0.4
2.0
V (min)
0.8
V (max)
Note 1: Absolute Maximum Ratings indicate limits beyond which damage to the deivce may occur. Operating Ratings indicate conditions for which the device is functional, but do not guarantee specific performance limits. For guaranteed specifications and test conditions, see the Electrical Characteristics. The guaranteed specifications apply only for the test conditions listed. Some performance characteristics may degrade when the device is not operated under the listed test conditions.
Note 2: All voltages are specified with respect to ground.
Note 3: When the input voltage (VIN) at any pin exceeds the power supply voltages (VIN < V− or VIN > V+) the absolute value of the current at that pin should be
limited to 5 mA or less. The 20 mA package input current limits the number of pins that can exceed the power supply voltages with 5 mA current limit to four.
Note 4: The maximum power dissipation must be derated at elevated temperatures and is dictated by TJMAX, θJA, and the ambient temperature TA. The maximum
allowable power dissipation is PD = (TJMAX − TA)/θJA or the number given in the Absolute Maximum Ratings, whichever is lower. For the LMC1983CIN, TJMAX =
+125˚C, and the typical junction-to-ambient thermal resistance, when board mounted, is 67˚C/W.
3
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Electrical Characteristics
(Continued)
Note 5: Human body model; 100 pF discharged through a 1.5 kΩ resistor.
Note 6: Typicals are at TJ = +25˚C and represent the most likely parametric norm.
Note 7: Limits are guaranteed to National’s AOQL (Average Outgoing Quality Level).
Note 8: The Input-Input Isolation is tested by driving one input and measuring the output when the undriven input are selected.
Note 9: The Volume Step Size is defined as the change in attenuation between any two adjacent volume attenuation settings. The nominal Volume Step Size is 2 dB.
Typical Performance Characteristics
Supply Current
vs Supply Voltage
Output Voltage
vs Supply Voltage
DS011279-11
THD vs
Load Impedance
THD vs
Load Impedance
DS011279-12
CCIR Output Noise
vs Volume Setting
DS011279-14
THD vs VIN
(VOUT Constant)
DS011279-13
Channel Separation
vs Frequency
DS011279-15
DS011279-16
Mute Gain
vs Frequency
THD vs Frequency
DS011279-18
DS011279-17
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DS011279-19
4
Typical Performance Characteristics
Tone Control Response
with Equal Bass and
Treble Control Settings
(Continued)
Loudness Response
vs Frequency
Select Input Impedance
vs Frequency
DS011279-21
DS011279-22
DS011279-20
Connection Diagram
DS011279-2
Top View
Order Number LMC1983CIN
See NS Package Number N28B
DS011279-10
Top View
Order Number LMC1983CIV
See NS Package Number V28A
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Pin Description
CLK (1)
The INTERMETAL (IM) Bus clock is
applied to the CLOCK pin. This input
accepts a TTL or CMOS level signal.
The input is used to clock the DATA
signal. A data bit must be valid on the
rising clock edge.
DIGITAL INPUT
Internally tied high to V+ through a
1 & 2 (2, 3)
30 kΩ pull-up resistor, these inputs allow a peripheral device to place any
single-bit, active low digital information
onto the IM Bus. It is then sent out to
the controlling device through the
DATA pin. Examples of such information could include indication of the
presence of a Second Audio Program
(SAP) or an FM stereo carrier.
INPUTS 1, 2 & 3
These are the LMC1983’s three stereo
(4, 25; 5, 24; 6, 23) input pairs.
SELECT OUT
The selected INPUT signal is available
(7, 22)
at this output. This feature allows external signal processors such as noise
reduction or graphic equalizers to be
used. This output can typically sink
1 mA. These pins should be capacitively coupled to pins 8 and 21, respectively, if no external processor is
used.
SELECT IN
These are the inputs that an external
(8, 21)
signal processor uses to return a signal to the LMC1983. These pins
should be capacitively coupled to pins
7 and 22, respectively, if no external
processor is used.
TONE IN
These are the inputs to the tone con(9, 20)
trol amplifier. See the Application Information section titled “Tone Control Response”.
TONE OUT
Tone control amplifier output. See the
(10, 19)
Application Information section titled
“Tone Control Response”.
OP AMP
These outputs are used with external
OUT (11, 18)
tone control capacitors. Internally, this
output is applied to the volume attenuators.
LOUDNESS
The output signal on these pins is a
(12, 17)
voltage taken from the volume attenuator’s −40 dB tap point. An external
R–C network is connected to these
pins.
The output signal from these pins
MAIN
drives a stereo power amplifier. The
OUTPUT
output can typically sink 1 mA.
(13, 16)
BYPASS (14)
A 10 µF capacitor is connected be-
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GROUND (15)
V+ (26)
ID (27)
DATA (28)
tween this pin and ground to provide
an AC ground for the internal
half-supply voltage reference.
This pin is connected to analog
ground.
This is the power supply connection.
The LMC1983 is operational with supply voltages from 6V to 12V. This pin
should be bypassed to ground through
a 1.0 µF capacitor.
This is the IDENTITY digital input that,
when low, signals the LMC1983 to receive, from a controlling device, a device address (40H–47H), present on
the DATA line.
This is the serial data input for communications sent by a controller. The controller must have open drain outputs
used with external pull-up resistors.
The data rate has a maximum frequency of 1 MHz. The LMC1983 requires 16 bits of data to control or
change a function: the first 8 bits select
the LMC1983 and one of eight functions. The final eight bits set the function to a desired value. The data must
be valid on the rising edge of the
CLOCK input signal.
General Information
The LMC1983 is a CMOS/bipolar building block intended for
high fidelity audio signal processing. It is designed for line
level inputs signals (300 mV − 2V) and has a maximum gain
of −0.5 dB. While the LMC1983 is manufactured with CMOS
processing, NPN transistors are used to build low noise op
amps. The combination of CMOS switches, bipolar op amps,
and poly-silicon resistors make it possible to achieve an order of magnitude quality improvement over other bipolar circuits that use analog multipliers to accomplish gain adjustment. Internal circuits set the volume to minimum, tone
controls to flat, the mute to on, and all other functions off
when power is first applied. Individual left and right volume
controls are software programmed to achieve the stereo balance function. Figure 1 shows the connection diagram of a
typical LMC1983 application.
The LMC1983 has internal decoding logic that allows a microprocessor (µP) or microcontroller (µC) to communicate directly to the audio control circuitry through an INTERMETAL
(IM) Bus interface. This three-wire interface consists of a
bi-directional DATA line, a Clock (CLK) input line, and an
Identity (ID) line. Address and function selection data (8 bits)
are serially shifted from the controller to the LMC1983. This
is followed by 8 bits of function value data. Data present in
the internal shift register is latched and the instruction is
executed.
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General Information
(Continued)
DS011279-3
FIGURE 1. Typical Application
Application Information
The output signal at pins 7 and 22 can be used to drive exteral audio processing circuits such as noise reduction
(LM1894–DNR or Dolby) or graphic equalizers (LMC835). It
is important that if any noise reduction is used it be placed
ahead of any tone controls or equalizers in the external circuit path to preserve the frequency spectrum of the selected
input signal. Otherwise, any frequency equalization could
prevent the proper operation of the noise reduction circuit. If
no external processor is used, a capacitor should be used to
couple the SELECT OUT signals directly to pins 8 and 21,
respectively.
INPUT SELECTOR
The LMC1983’s input selector and mode control are shown
in Figure 2. The input selector selects one of three stereo
signal sources or a mute function with typical attenuation of
100 dB. The selected signals are then sent to a mode control
matrix. As shown in Table 1, the matrix provides normal stereo or can direct any given channel to both LEFT or RIGHT
SELECT OUTPUTs. The third matrix mode is normal stereo.
The control matrix output is buffered and appears on each
channel’s respective SELECT OUT pin (7, 22). Switching
noise is kept to a minimum when mute is selected by using
a 50 kΩ bias resistor.
Noise performance is optimized through the use of emitter
followers in the mode control matrix’s output. Internal 50 kΩ
resistors are connected to each input selector pin to provide
the proper bias point for the emitter follower buffers. Each internal 50 kΩ bias resistor is connected to a common
half-supply (V+/2) source. This produces a voltage at pins 7
and 22 (SELECT OUT) that is 1.4V below V+/2 (typically
3.1V with V+ = 9V). Since a DC voltage is present at the input pins (4, 5, 6, 23, 24, and 25), input signals should be AC
coupled through a 1 µF capacitor.
MINIMUM LOAD IMPEDANCE
The LMC1983 employs emitter-followers to buffer the selected stereo channels. The buffered signals are available at
pins 7 and 22 (SELECT OUT). The SELECT OUT buffers operate with a typical bias current of 1 mA.
The Electrical Specifications table lists a maximum input signal of 2.0 Vrms (2.8 Vpeak) for 1% THD at the SELECT OUT
pins. This distortion level is achieved when the minimum AC
load impedance seen by the SELECT OUT pins is 2.5 kΩ
(2.5V/1 mA). Using lower load impedances results in clipping
7
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Application Information
The SELECT IN pins have an input impedance that varies
with the BASS and TREBLE control settings. The input impedance is 100 kΩ at DC and 19 kΩ at 1 kHz when the controls are set at 0 dB. Minimum input impedance of 30.4 kΩ at
DC and 16 kΩ at 1 kHz occurs when maximum boost is selected. At 10 kHz the minimum input impedance, with the
tone controls flat, is 6.8 kΩ and, with the tone controls at
maximum boost, is 2.5 kΩ.
(Continued)
at lower output levels. If the load impedance is DC-coupled,
an increased quiescent current can flow. Latch-up may occur
if the total emitter current exceeds 5 mA. Thus, maximum
output voltage can be increased and much lower distortion
levels can be achieved using load impedances of at least
25 kΩ.
INPUT IMPEDANCE
The input impedance of pins 4, 5, 6, 23, 24 and 25 is defined
by internal bias resistors and is typically 50 kΩ.
DS011279-4
FIGURE 2. Input and Mode Select Circuitry
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Application Information
(Continued)
TABLE 1. IM Bus Programming Codes for LMC1983
Address
Function
Data
Input Select + Mute
XXXXXX00
INPUT1
XXXXXX01
INPUT2
XXXXXX10
INPUT3
(A7–A0)
01000000
Selected
01000001
Loudness
01000010
Bass
01000011
01000100
01000101
01000110
01000111
Function
Treble
Left Volume
Right Volume
Mode Select
Read Digital Input 1
XXXXXX11
MUTE
XXXXXXX0
Loudness OFF
XXXXXXX1
Loudness ON
XXXX0000
−12 dB
XXXX0011
−6 dB
XXXX0110
FLAT
XXXX1001
+6 dB
XXXX11XX
+12 dB
XXXX0000
−12 dB
XXXX0011
−6 dB
XXXX0110
FLAT
XXXX1001
+6 dB
XXXX11XX
+12 dB
XX000000
0 dB
XX010100
−40 dB
XX101XXX
−80 dB
XX11XXXX
−80 dB
XX000000
0 dB
XX010100
−40 dB
XX101XXX
−80 dB
XX11XXXX
−80 dB
XXXXX100
Left Mono
XXXXX101
Stereo
XXXXX11X
Right Mono
D0 = Digital Input 1
D1 = Digital Input 2
XXXXXXD1D0
or
Digital Input 2
on IM Bus
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Application Information
C3 and C2 sets the mid-frequency gain. Symmetrical tone
response is achieved when C2 = C3. However, with
C2 = 2(C3) and the tone controls set to “flat”, the frequency
response will be flat at 20 Hz and 20 kHz, and +6 dB at
1 kHz.
(Continued)
EXTERNAL SIGNAL PROCESSING
The SELECT OUT pins (7 and 22) enable greater system
design flexibility by providing a means to implement an external processing loop. This loop can be used for noise reduction circuits such as DNR (LM1894) or multi-band
graphic equalizers (LMC835). If both are used, it is important
to ensure that the noise reduction circuitry precede the
equalization circuits. Failure to do so results in improper operation of the noise reduction circuits. The system shown in
Figure 3 utilizes the external loop to include DNR and a
multi-band equalizer.
The frequency where a tone control begins to deviate from a
flat response is referred to as the turn-over frequency. With
C = C2 = C3, the LMC1983’s treble turn-over frequency is
nominally
The bass turn-over frequency is nominally
TONE CONTROL RESPONSE
Bass and treble tone controls are included in the LMC1983.
The tone controls use just two external capacitors for each
stereo channel. Each has a corner frequency determined by
the value of C2 and C3 (see Figure 4 ) and internal resistors
in the feedback loop of the internal tone amplifier. The
maximum-boost or cut is determined by the data sent to the
LMC1983 (see Table 1).
The typical tone control response shown in Typical Performance Curves were generated with C2 = C3 = 0.0082 µF
and show the response for each step. When modifying the
tone control response it is important to note that the ratio of
when maximum boost is chosen. The inflection points (the
frequencies where the boost or cut is within 3 dB of the final
value) are for treble and bass
DS011279-5
FIGURE 3. System Block Diagram Utilizing the External Processing Loop (One Channel Shown)
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Application Information
The LMC1983’s loudness function uses external components R1, R2, C4 and C5, as shown in Figure 5, to select the
frequencies where bass and treble boost begin. The amount
of boost is dependent on the volume attenuator’s setting.
The loudness characteristic, with the volume attenuator set
at 40 dB, has a transfer function of
(Continued)
The external components R1 and C4 can be eliminated and
pin 11(18) left open if bass boost is the only desired loudness
characteristic.
DS011279-6
FIGURE 4. The Tone Control Amplifier
Increasing the values of C2 and C3 decreases the turnover
and inflection frequencies: i.e., the Tone Control Response
Curves shown in Typical Performance Curves will shift left
when C2 and C3 are increased and shift right when C2 and
C3 are decreased. With C2 = C3 = 0.0082, 2 dB steps are
achieved at 100 Hz and 10 kHz. Changing C2 and C3 to
0.01 µF shifts the 2 dB per step frequency to 72 Hz and
8.3 kHz. If the tone control capacitors’ size is decreased
these frequencies will increase. With C2 = C3 = 0.0068 µF
the 2 dB steps take place at 130 Hz and 11.2 kHz.
DS011279-7
FIGURE 5. Loudness Control Circuit
SERIAL DATA COMMUNICATION
The LMC1983 uses the INTERMETAL serial bus (IM Bus)
standard. Serial data information is sent to the LMC1983
over a three wire IM Bus consisting of Clock (CLK), Data
(DATA), and Identity (ID). The DATA line is bidirectional and
the CLK and ID lines are unidirectional from the microprocessor or micontroller to the LMC1983. The LMC1983’s bidirectional capability is accomplished by using an open drain
output on the DATA line and an external 1 kΩ pull-up resistor.
The LMC1983 responds to address values from 01000000
(40H) through 01000111 (47H). The addresses select one of
the eight available functions (see Table 1). The IM Bus’ lines
have a logic high standby state when using TTL logic levels.
As shown in Figure 6, data transmission is initiated by low
levels on CLK and ID. Next, eight address bits are sent. This
address information includes the code to select one of the
LMC1983’s desired functions. Each address bit is clocked in
on the rising edge of CLK. The ID line is taken high after the
eight bits of address data are received by the LMC1983.
LOUDNESS
The human ear has less sensitivity to high and low frequencies relative to its sensitivity to mid-range frequencies between 2 kHz and 6 kHz for any given acoustic level. The low
and high frequency sensitivity decreases faster than the sensitivity to the mid-range frequencies as the acoustic level
drops. The LMC1983’s loudness function can be used to
help compensate for the decreased sensitivity by boosting
the gain at low and high frequencies as the volume control
attenuation increases (see the curve labeled “Gain vs Frequency with Loudness Active”).
DS011279-8
FIGURE 6. LMC1983’s INTERMETAL Serial Bus Timing
Table 1 also details the serial data structure, range, and bit
assignments that sets each function’s operating point. The
volume and tone controls’ function control data binarily increments from zero to maximum as the function’s operating
point changes from 80 dB attenuation to 0 dB attenuation
(volume) or −12 dB to +12 dB (tone controls). Note that not
all data bits are needed by each function. The extra bits
shown as “X”s (“don’t cares”) are position holders and have
The controlling system continues toggling the CLK line eight
more times. Data that determines the selected function’s operating point is written into, or single bit information on DIGITAL INPUT 1 or DIGITAL INPUT 2 is read from, the
LMC1983. Finally, the end of transmission is signaled by
pulsing the ID line low for a minimum of 3 µs. The transmitted function data is latched and the function changes to its
new setting.
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Application Information
DIGITAL I/O
(Continued)
The LMC1983’s two Digital Input pins, 2 and 3, provide
single-bit communication between a peripheral device and
the controller over the IM Bus. Each pin has an internal
30 kΩ pull-up resistor. Therefore, these pins should be connected to open collector/drain outputs. The type of information that could be received on these lines and retrieved by a
controller include FM stereo pilot indication, power on/off,
Secondary Audio Program (SAP), etc.
According to Table 1, the logic state of DIGITAL INPUT 1 and
DIGITAL INPUT 2 is latched and can be retrieved over the IM
Bus using the read command (47H). The single-bit information sent on the IM Bus is active low since these lines are internally pulled high.
no affect on a respective control. They are necessary to
properly position the data in the LMC1983’s internal data
shift register. Unexpected results may take place if these bits
are not sent.
The LMC1983’s internal data shift register can handle either
a 16-bit word or two 8-bit serial data transmissions. It is the
final 8 bits of data received before the ID line goes high that
are used as the LMC1983 selection and function addresses.
The final eight bits after the ID line returns high are used to
change a function’s operating point. CLK must be stopped
when the final 8 data bits are received. The data stored in the
internal data latch remains unchanged until the ID is pulsed,
signifying the end of data transmission. When ID is pulsed,
the new data in the data shift register is latched into the data
latch and the selected function takes on a new operating
point.
A complete description and more information concerning the
IM Bus is given in the appendix of ITT’s CCU2000
datasheet.
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Physical Dimensions
inches (millimeters) unless otherwise noted
Order Number LMC1983CIN
NS Package Number N28B
Order Number LMC1983CIV
NS Package Number V28A
13
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LMC1983 Digitally-Controlled Stereo Tone and Volume Circuit with Three Selectable Stereo
Inputs
Notes
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