Freescale Semiconductor PowerQUICC MPC870, Справочное руководство

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Serial Communications Controllers
MPC885 PowerQUICC Family Reference Manual, Rev. 2
Freescale Semiconductor 21-5
19, 20 TRX,
TTX
Transparent receiver/transmitter. The receiver, transmitter, or both can use totally transparent
operation, regardless of GSMR_L[MODE]. For example, to configure the transmitter as a UART and
the receiver for totally transparent operation, set MODE = 0b0100 (UART), TTX = 0, and TRX = 1.
0 Normal operation
1 The receiver/transmitter uses totally transparent mode, regardless of the protocol chosen in
GSMR_L[MODE].
For full-duplex totally transparent operation, set both TTX and TRX.
Note that an SCC cannot operate half in Ethernet or serial ATM mode and half in transparent mode.
For example, if MODE = 0b1100 (Ethernet), erratic operation occurs unless TTX = TRX.
21, 22 CDP,
CTSP
CD/CTS pulse. If the SCC is used in the TSA and is programmed in transparent mode, set CTSP
and refer to
Section 28.3.2, “Synchronization and the TSA,” for options on programming CDP.
0 Normal operation (envelope mode). CD/CTS should envelope the frame. Negating CD/CTS
during reception causes a CD/CTS lost error.
1 Pulse mode. Synchronization occurs when CD/CTS is asserted; further CD/CTS transitions do
not affect reception.
23, 24 CDS,
CTSS
CD/CTS sampling. Determine synchronization characteristics of CD and CTS. If the SCC is in
transparent mode and is used in the TSA, CDS and CTSS must be set. Also, CDS and CTSS must
be set for loopback testing in transparent mode.
0 CD/CTS is assumed to be asynchronous with data. It is internally synchronized by the SCC, then
data is received (CD) or sent (CTS) after several clock delays.
1 CD/CTS is assumed to be synchronous with data, which speeds up operation. CD or CTS must
transition while the Rx/Tx clock is low, at which time, the transfer begins. Useful for connecting
MPC885 in transparent mode since the RTS of one MPC885 can connect directly to the CD/CTS
of another.
25 TFL Transmit FIFO length
0 Normal operation. SCC2–SCC4 Tx FIFOs are 16 bytes each.
1 The Tx FIFO is 1 byte. This option is used with character-oriented protocols, such as UART, to
ensure a minimum FIFO latency at the expense of performance.
26 RFW Rx FIFO width
0 Receive FIFO is 32 bits wide for maximum performance; the Rx FIFO is 16 bytes for
SCC2–SCC4. Data is not normally written to receive buffers until at least 32 bits are received.
This configuration is required for HDLC-type protocols and Ethernet and is recommended for
high-performance transparent protocols.
1 Low-latency operation. The receive FIFO is 8 bits wide, reducing the Rx FIFO to a quarter its
normal size. This allows data to be written to the buffer as soon as a character is received, instead
of waiting to receive 32 bits. This configuration must be chosen for character-oriented protocols,
such as UART. It can also be used for low-performance, low-latency, transparent operation.
However, it must not be used with HDLC, HDLC Bus, AppleTalk, or Ethernet because it causes
erratic behavior.
27 TXSY Transmitter synchronized to the receiver. Intended for X.21 applications where the transmitted data
must begin an exact multiple of 8-bit periods after the received data arrives.
0 No synchronization between receiver and transmitter (default).
1 The transmit bit stream is synchronized to the receiver. Additionally, if RSYN = 1, transmission in
totally transparent mode does not occur until the receiver synchronizes with the bit stream and
CTS is asserted to the SCC. Assuming CTS is asserted, transmission begins 8 clocks after the
receiver starts receiving data.
Table 21-2. GSMR_H Field Descriptions (continued)
Bits Name Description