3.0 Circuit Descriptions
RS8953B/8953SPB
3.2 PCM Channel
HDSL Channel Unit
Figure 3-5 shows the phase relationship between TMSYNC and MSYNC
when TFRAME_LOC is equal to 0. Figure 3-6 illustrates the progression of
MSYNC with increasing bit and frame delays.
NOTE: MSYNC can optionally mark the start of every PCM frame (bit 0, all
frames) by setting MF_LEN equal to 1 frame per multiframe.
Figure 3-5. PCM Transmit Sync Timing
TCLK
TMSYNC
TFRAME_LOC=0, TMF_LOC=0
FRAME_LEN[X]
MSYNC
TSER
INSDAT
0
1
2
X
Sample PCM Bit 0 or F-bit, of Frame 0
NOTE(S): TCLK falling edge samples and rising edge outputs shown per TCLK_SEL = 00
Figure 3-6. PCM Transmit Data Timing
TMSYNC
TFRAME_LOC[M] = MSYNC Bit Delay
0 1 M
TMF_LOC[N] = MSYNC Frame Delay
0 1 N
MSYNC
FRAME_LEN[X] = PCM Frame Length
PCM
Bit
0
X
MF_LEN[Y] = PCM Multiframe Length
PCM
Frame
Frame 0
Frame Y
MF_CNT[Z] = Mframes per 6 ms period
Mframe 1
PCM
Mframe
Mframe 0
Mframe Z
3.2.1.1 Transmit
Synchronization
Alignment of transmit PCM data in relation to MSYNC determines whether PCM
and HDSL frames are synchronously mapped. The RS8953B does not examine
transmit data for T1, E1, or application framing patterns. Therefore, the system
must apply PCM data aligned to MSYNC when synchronous mapping is desired.
If the system applies PCM bit 0, frame 0 coincident with MSYNC, then the
transmit router guarantees that each PCM timeslot placed in the TFIFO will be
aligned and mapped into a specific HDSL payload byte. In addition, timeslots
from the first PCM frame are mapped to payload bytes in the first HDSL payload
block, and the start of a PCM multiframe is aligned with the start of an HDSL
frame.
3-6
Conexant
N8953BDSB