Z85C3010PSG Zilog, Z85C3010PSG Datasheet - Page 96
Z85C3010PSG
Manufacturer Part Number
Z85C3010PSG
Description
IC 10MHZ Z8500 CMOS SCC 40-DIP
Manufacturer
Zilog
Series
SCCr
Specifications of Z85C3010PSG
Processor Type
Z80
Features
Error Detection and Multiprotocol Support
Speed
10MHz
Voltage
5V
Mounting Type
Through Hole
Package / Case
40-DIP (0.620", 15.75mm)
Cpu Speed
8MHz
Digital Ic Case Style
DIP
No. Of Pins
40
Supply Voltage Range
5V
Operating Temperature Range
0°C To +70°C
Svhc
No SVHC (18-Jun-2010)
Base Number
85
Rohs Compliant
Yes
Clock Frequency
10MHz
Lead Free Status / RoHS Status
Lead free / RoHS Compliant
Other names
269-3934
Z85C3010PSG
Z85C3010PSG
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UM010901-0601
near the end of the frame to allow the correct transmission
of the CRC.
In this paragraph the term “completely sent” means shifted
out of the Transmit Shift register, not shifted out of the zero
inserter, which is an additional five bit times of delay. In
SDLC mode, if the transmitter is disabled during transmis-
sion of a character, that character will be “completely sent.”
This applies to both data and flags. However, if the trans-
mitter is disabled during the transmission of the CRC, the
16-bit transmission will be completed, but the remaining
bits are from the Flag register rather than the remainder of
the CRC.
The initialization sequence for the transmitter in SDLC
mode is:
1. WR4 selects the mode.
2. WR10 modifies it if necessary.
3. WR7 programs the flag.
4. WR3 and WR5 selects the various options.
At this point the other registers should be initialized as nec-
essary. When all of this is complete, the transmitter may be
enabled by setting bit D3 of WR5 to 1. Now that the trans-
mitter is enabled, the CRC generator may be initialized by
issuing the Reset Tx CRC Generator command in WR0.
4.4.1.1 Modem Control signals related to SDLC
Transmit
There are two modem control signals associated with the
transmitter provided by the SCC. The /RTS pin is a simple
output that carries the inverted state of the RTS bit (D1) in
WR5. The /CTS pin is ordinarily a simple input to the CTS
bit in RR0. However, if Auto Enables mode is selected, this
pin becomes an enable for the transmitter. If Auto Enables
is on and the /CTS pin is High, the transmitter is disabled.
The transmitter is enabled if the /CTS pin is Low.
4.4.1.2 ESCC Enhancements for SDLC Transmit
The ESCC has the following enhancements available in
the SDLC mode of operation which can reduce CPU over-
head dramatically. These features are:
Deeper Transmit FIFO (Four Bytes)
CRC takes priority over the data
Auto EOM Reset (WR7' bit D1)
Auto Tx Flag (WR7' bit D0)
Auto RTS Deactivation (WR7' bit D2)
TxD pin forced High after closing flag in NRZI mode
Deeper Transmit FIFO: The ESCC has a four byte deep
Transmit FIFO, where the NMOS/CMOS version has a
one byte deep transmit buffer. To maximize the system’s
performance, there are two modes of operation for the
transmit interrupt and DMA request, which are pro-
grammed by bit D5 of WR7'.
The ESCC sets WR7' bit D5 to 1 following a hardware or
software reset. This is done to provide maximum compat-
ibility with existing SCC designs. In this mode, the ESCC
generates the transmit buffer empty interrupt and DMA
transmit request when the Transmit FIFO is completely
empty. Interrupt driven systems can maximize efficiency
by writing four bytes for each entry into the Transmit Inter-
rupt Service Routine (TISR), filling the Transmit FIFO with-
out having to check any status bits. Since the TBE status
bit is set if the entry location of the FIFO is empty, this bit
can be tested at any time if more data is written. Applica-
tions
NMOS/CMOS version can test the TBE bit in the TISR af-
ter each data write to determine if more data can be writ-
ten. This allows a system with an ESCC to minimize the
number of transmit interrupts, but not overflow SCC sys-
tems. DMA driven systems originally designed for the SCC
can use this mode to reassert the DMA request for more
data after the first byte written to the FIFO is loaded to the
Transmit Shift register. Consequently, any subsequent re-
assertion allows the DMA sufficient time to detect the High-
to-Low edge.
If WR7' D5 is reset to 0, the transmit buffer empty interrupt
and DMA request are generated when the entry location of
the FIFO is empty. Therefore, if more than one byte is re-
quired to fill the entry location of the FIFO, the ESCC gen-
erates interrupts or DMA requests until the entry location
of the FIFO is filled. The transmit DMA request pin (either
/WAIT//REQ or /DTR//REQ) goes inactive after each data
transfer, then goes active again and, consequently, gener-
ates a High-to-Low edge for each byte. Edge triggered
DMA should be enabled before the transmit DMA function
is enabled in the ESCC to guarantee that the ESCC does
not generate the edge before the DMA is ready.
CRC takes priority over data: On the NMOS/CMOS
version, the data has higher priority over CRC data. Writ-
ing data before the Tx interrupt, after loading the closing
flag into the Transmit Shift register, terminates the packet
illegally. In this case, CRC byte(s) are replaced with Flag
or Sync patterns, followed by the data written. On the ES-
CC, CRC has priority over the data. Consequently, after
the Underrun/EOM (End of message) interrupt occurs,
the ESCC accepts the data for the next packet without
fear of collapsing the packet. On the ESCC, if data was
written during the time period described above, the TBE
bit (bit D2 of RR0) is NOT set; even if the 2nd TxIP is
guaranteed to set when the flag/sync pattern is loaded
into the Transmit Shift register (Section 2.4.8). For the
detailed timing on this, refer to Figures 2-17 and 2-18.
requiring
software
SCC™/ESCC™ User’s Manual
Data Communication Modes
compatibility
with
4-21
the
4
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