AM79Q02JC AMD (ADVANCED MICRO DEVICES), AM79Q02JC Datasheet - Page 35
AM79Q02JC
Manufacturer Part Number
AM79Q02JC
Description
Manufacturer
AMD (ADVANCED MICRO DEVICES)
Datasheet
1.AM79Q02JC.pdf
(64 pages)
Specifications of AM79Q02JC
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During this test, the VIN input is ignored and the VOUT
output is connected to VREF.
Speech Coding
The A/D and D/A conversion follows either the A-law
o r t h e µ - l a w s t a n d a r d a s d e f i n e d i n I T U - T
Recommendation G.711. A-law or µ-law operation is
programmed using MPI Commands 24 and 25.
Alternate bit inversion is performed as part of the A-law
coding. The QSLAC device provides linear code as an
option on both the transmit and receive sides of the
device. Linear code is selected using MPI Commands
24 and 25. Two successive time slots are required for
linear code operation. The linear code is a 16-bit two’s-
complement number which appears sign bit first on the
PCM highway. Linear code occupies two time slots.
Signaling on the PCM Highway
If the SMODE bit is set in the Configuration register,
each data point occupies two consecutive time slots.
The first time slot contains A-law or -law data and the
second time slot will have the following information:
Bit 7 of the signaling byte will appear immediately after
bit 0 of the data byte. A-law or -law Companded state
must be specified in order to put signaling information
on the PCM highway. The signaling time slot remains
active, even when the channel is deactivated.
Robbed-Bit Signaling Compatibility
The QSLAC device supports robbed bit signaling
compatibility. Robbed bit signaling allows periodic use
of the least significant bit (LSB) of the receive path
PCM data to be used to carry signaling information. In
this scheme, separate circuitry within the line card or
system intercepts this bit out of the PCM data stream
and uses this bit to control signaling functions within
the system. The QSLAC device does not perform any
processing of any of the robbed bits during this
operation; it simply allows for the robbed bit presence
by performing the LSB substitution.
If the RBE bit is set, then the robbed-bit signaling
compatibility mode is enabled. Robbed-bit signaling is
Bit 7:
Bit 6:
Bits 5–3: Reserved
Bit 2:
Bits 1–0: Reserved
Debounced CD1 bit (usually hookswitch)
CD2 bit or CD1B bit
CFAIL
SLAC Products
only available in the -law companding mode of the
device. Also, only the receive (digital-to-analog) path is
involved. There is no change of operation to the transmit
path and PCM data coming out of the QSLAC device will
always contain complete PCM byte data for each time
slot, regardless of robbed-bit signaling selection.
In the absence of actual PCM data for the affected time
slots, there is an uncertainty of the legitimate value of
this bit to accurately reconstruct the analog signal.
This bit can always be assumed to be a 1 or 0; hence,
the reconstructed signal is correct half the time.
However, the other half of the time, there is an
unacceptable reconstruction error of a significance
equal to the value weighting of the LSB. To reduce this
error and provide compatibility with the robbed bit
signaling scheme, when in the robbed-bit signaling
mode, the QSLAC device ignores the LSB of each
received PCM byte and replace its value in the
expander with a value of half the LSB’s weight. This
then guarantees the reconstruction is in error by only
half this LSB weight. In the expander, the eight bits of
the companded PCM byte are expanded into linear
PCM data of several more bits within the internal signal
processing path of the device. Therefore, accuracy is
not limited to the weight of the LSB, and a weight of
half this value is realizable.
When this robbed-bit mode is selected, not every
frame contains bits for signaling, and therefore not
every byte requires its LSB substituted with the half-
LSB weight. This substitution only occurs for valid
PCM time slots within frames for which this robbed bit
has been designated. To determine which time slots
are affected, the device monitors the frame sync (FS)
pulse. The current frame is a robbed-bit frame and this
half-LSB value is used only when this criteria is met:
The frame sync pulse is sampled on the falling edge of
PCLK. As shown in Figure 13, if the above criteria is
met, and if FS is high for two consecutive falling edges
of PCLK then low for the third falling edge, it is
considered a robbed-bit frame. Otherwise, it is a
normal frame.
The RBE bit is set, and
The device is in the -law companding mode, and
The current frame sync pulse (FS) is two PCLK
cycles long, and
The previous frame sync pulse (FS) was not two
PCLK cycles long.
35
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