MPA-100
RS-232 SYNCHRONOUS
ADAPTER CARD
User's Manual
INTERFACE CARDS FOR IBM PC/AT AND PS/2
QUATECH, INC.
5675 Hudson Industrial Parkway
Hudson, Ohio 44236
TEL: (330) 665-9000
FAX: (330) 665-9010
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Warranty Information
Quatech Inc. warrants the
MPA-100
to be free of defects for
one (1) year from the date of purchase. Quatech Inc. will repair or replace any adapter that
fails to perform under normal operating conditions and in accordance with the procedures
outlined in this document during the warranty period. Any damage that results from improper
installation, operation, or general misuse voids all warranty rights.
The authors have taken due care in the preparation of this document and any associated software
program(s). In no event will Quatech Inc. be liable for damages of any kind, incidental or
consequential, in regard to or arising out of the performance or form of the materials presented
herein and in the program(s) accompanying this document. No representation is made regarding
the suitability of this product for any particular purpose.
Quatech Inc. reserves the right to edit or append to this document or the product(s) to which it
refers at any time and without notice.
Please complete the following information and retain for your records. Have this information
available when requesting warranty service.
Date of purchase:
Model Number:
MPA-100
Product Description:
Single Channel RS-232 Synchronous
Communication ISA Adapter
Serial Number:
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The information contained in this document cannot be reproduced in any form without the
written consent of Quatech, Inc. Likewise, any software programs that might accompany this
document can be used only in accordance with any license agreement(s) between the purchaser
and Quatech, Inc. Quatech, Inc. reserves the right to change this documentation or the product to
which it refers at any time and without notice.
The authors have taken due care in the preparation of this document and every attempt has been
made to ensure its accuracy and completeness. In no event will Quatech, Inc. be liable for
damages of any kind, incidental or consequential, in regard to or arising out of the performance
or form of the materials presented in this document or any software programs that might
accompany this document.
Quatech, Inc. encourages feedback about this document. Please send any written comments to
the Technical Support department at the address listed on the cover page of this document.
Copyright ©2004 by
Quatech Inc.
5675 Hudson Industrial Parkway
Hudson, Ohio 44236
All rights reserved. Printed in the USA
Trademarks:
Quatech,, and Syncdrive are trademarks of Quatech Inc. Other product and company names are
registered trademarks or trademarks of their respective holders.
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Table of Contents
1. INTRODUCTION . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1-1 . .
2. HARDWARE INSTALLATION
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2-1 . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3-1 . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4-1 . .
3. ADDRESSING
4. INTERRUPTS
4-2
4.1 Using Terminal Count to Generate Interrupts . . . . . . . . . . . . . . . . . . . . . .
. .
5. JUMPER CONFIGURATIONS
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1 . .
5.1 DTE/DCE Configuration - J2, J11, & J12
. . . . . . . . . . . . . . . . . . . . . . . . . 5-1 . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-1 . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 5-2 . .
5.2 Interrupt Sharing Configuration - J4
5.3 Interrupt Level Selection - J5 & J6
5-3
5-3
5.4 Transmit DMA Selection - J8 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5.5 Receive DMA Selection - J9 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. .
. .
5.6 SYNCA to RLEN Control - J7
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-4 . .
6. SCC GENERAL INFORMATION
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 6-1 . .
6-2
6-5
7-6
6.1 Accessing the Registers . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.2 Baud Rate Generator Programming . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
6.3 SCC Data Encoding Methods . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. .
. .
. .
7. DIRECT MEMORY ACCESS
8. CONFIGURATION REGISTER
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 7-1 . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8-1 . .
9. COMMUNICATIONS REGISTER
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 9-1 . .
10. DTE/DCE CONFIGURATION
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 10-1 .
10-2
10-3
10.1 DTE Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
10.2 DCE Configuration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
.
.
11. EXTERNAL CONNECTIONS
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 11-6 .
12. DEFINITION OF INTERFACE SIGNALS
. . . . . . . . . . . . . . . . . . . . . . . . 12-1 .
13. SPECIFICATIONS
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 13-1 .
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1. INTRODUCTION
The Quatech MPA-100 is a single channel, synchronous RS-232 compatible serial
communication port for systems utilizing the architecture of the IBM AT personal computer or
compatible. Figure 1 depicts the layout of the MPA-100.
Figure 1 MPA-100 Board Layout
Quatech, Inc.
MPA-100
U16
U22
U9
U10
U11
U12
U13
U14
X1
U29
U4
U5
U6
U17
J11
J12
CN1
J7
U23
U18
U1
U2
U28
U19
U20
U7
J2
SW1
SW2
J8
J9
U8
J5
U15
U3
J4
U21
J6
The MPA-100 occupies an 8 byte block of I/O address space which may be located
anywhere within the available I/O address space in the system.
Communication on the MPA-100 is controlled by a serial communications controller,
hereafter referred to as the SCC (U17). The MPA-100 is compatible with several different types
of SCC, all of which can support asynchronous formats, byte-oriented protocols such as IBM
Bisync, and bit-oriented protocols such as HDLC and SDLC. The SCCs also offer internal
functions such as on-chip baud rate generators, and digital phase-lock loops (DPLL).
The MPA-100 also supports Direct Memory Access (DMA) and interrupts. DMA
channels 1 - 3 can be used for high data transfer rates. Interrupt levels 2-7, 10-12, and 14-15 are
available.
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2. HARDWARE INSTALLATION
If the default address and interrupt settings are sufficient, the MPA-100 can be quickly
installed and put to use. The factory default settings are listed below in Table 1.
Table 1 Default Resource Settings
Address
300 hex
Interrupt
IRQ 5
TxDMA
DMA/DRQ 3
RxDMA
DMA/DRQ 1
1. If the default settings are correct, skip to step 2, otherwise refer to chapters 3, 4, and
7 for detailed information on how to set the address, IRQ, and DMA levels.
2. Turn off the power of the computer system in which the MPA-100 is to be installed.
3. Remove the system cover according to the instructions provided by the computer
manufacturer.
4. Install the MPA-100 in any vacant expansion slot. The board should be secured by
installing the Option Retaining Bracket (ORB) screw.
5. Replace the system cover according to the instructions provided by the computer
manufacturer.
6. Attach and secure the cable connectors to the desired equipment.
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3. ADDRESSING
The MPA-100 occupies a continuous 8 byte block of I/O addresses. For example, if the
base address is set to 300H, then the MPA-100 will occupy address locations 300H-307H. The
base address of the MPA-100 may be set to any of the first 64 Kbytes (0 - FFFFH) of available
I/O address space through the settings of dip switches SW1 and SW2. SW1 allows the user to
select the higher address signals A15 - A8. SW2 allows the user to select the lower address
signals A7 - A3. The sixth position of SW2 is not used and can be ignored. Figure 2 shows some
examples of different base addresses.
Figure 2 Address switch selection examples
ON
ON
3
1
2
5
6
1
4
4
5
6
8
3
7
2
Base Address = 300H
O N
1
ON
6
1
3
7
2
2
4
5
8
3
4
5
6
Base Address = 3F8H
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The first four bytes, Base+0 through Base+3, of address space on the MPA-100 contain
the internal registers of the SCC. The next two locations Base+4 and Base+5 contain the
Communications Register and the Configuration Register. The last two address port locations
are reserved for future use. The entire address range of the MPA-100 is shown in Table 2.
Table 2 MPA-100 Address Assignments
Address
Base + 0
Base + 1
Base + 2
Base + 3
Base + 4
Base + 5
Base + 6
Base + 7
Register Description
SCC Data Port, Channel A
SCC Control Port, Channel A
SCC Data Port, Channel B
SCC Control Port, Channel B
Communications Register
Configuration Register
Reserved
Reserved
Information on the internal registers of the SCC can be found in Section 6. The two
onboard registers give the user additional options pertaining to DMA, interrupts and the
RS-232-D standard for communication. Information on the Configuration Register and the
Communications Register can be found in Section 8, and Section 9.
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4. INTERRUPTS
The MPA-100 supports eleven interrupt levels: IRQ2 -7, IRQ10 - 12, and IRQ14 - 15,
and selects which interrupt level is in use through jumper packs J5 and J6. The MPA-100 has
three interrupt sources: interrupt on terminal count, interrupt on test mode, and interrupt from the
SCC. The interrupt source is selected by bits D4 and D5 of the Configuration Register, see
Section 8 for details. Interrupts from the SCC can occur on a number of conditions, depending on
the configuration of the SCC’s internal register. The sources include interrupt on next character
received, interrupt on all characters received, interrupt on special condition, interrupt on transmit
buffer empty, and interrupt on External/Status (see the SCC Technical Manual for more
details). Jumper block J4 can be selected to provide for interrupt sharing on the MPA-100.
When using interrupts with the MPA-100, it is required that the application program have
an interrupt service routine (ISR). There are several things that an ISR must do to allow proper
system operation:
1. Do a software interrupt acknowledge to the SCC. This is accomplished by reading
the interrupt vector register, read register 2, in channel B of the SCC. The value
supplied by this read can also be used to vector to the appropriate part of the ISR.
2. Service the interrupt ( read the receiver buffer, write to the transmit buffer, etc.).
3. Write a Reset Highest Interrupt Under Service (IUS) command to the SCC. This is
done by writing a 0x38 to write register 0.
4. Check for any additional interrupts pending in the SCC and service them.
5. For applications running under DOS, a nonspecific End of Interrupt must be
submitted to the interrupt controller. For Interrupts 2-7 this is done by writing a 0x20
to port 0x20. For Interrupts 10-12,14 and 15 this is done by writing a 0x20 to 0x60,
then a 0x20 to 0x20 (Due to the interrupt controllers being cascaded). Note that this
should only be done if it is a requirement of the operating system being used.
For further information on these subjects or any others involving the SCC contact the
manufacturer of the SCC being used for a complete technical manual.
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4.1 Using Terminal Count to Generate Interrupts
The MPA-100 allows the option of generating an interrupt whenever the Terminal Count
(TC) signal is asserted. Terminal Count is an indicator generated by the system’s DMA
controller, which signals that the number of transfers programed into the DMA controller’s
transfer register have occurred. This board feature only works when theinterrupt sharing feature
is selected on jumper J4.
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5. JUMPER CONFIGURATIONS
The MPA-100 utilizes various jumper blocks which allow the user to customize their
hardware configuration. The following sections explain the function and setting of each of the
jumper blocks on the MPA-100.
5.1 DTE/DCE Configuration - J2, J11, & J12
The jumper packs J2, J11, and J12 control the DTE/DCE configuration of the MPA-100.
J2 determines the board setting (DTE or DCE) while the jumper packs J11 and J12 control the
routing of the signals to the DB-25 connector. All three jumper packs must be set exclusively to
either DTE or DCE for correct operation of the MPA-100.
Table 3 DTE/DCE Jumper Selections
DCE
DTE (Default)
J2
1-2
no connection
1-9, 2-10, 3-11, 4-12, 5-13,
6-14, 7-15, 8-16
1-2, 3-4, 5-6, 7-8, 9-10, 11-12,
13-14, 15-16
J11
J12
1-5, 2-6, 3-7, 4-8
1-2, 3-4, 5-6, 7-8
J11 and J12 may be configured for DTE by setting all jumpers vertical on the board and for DCE
by setting all jumpers horizontal on the board.
5.2 Interrupt Sharing Configuration - J4
J4 is a three pin jumper which determines the configuration for the interrupts. By
selecting pins 1 & 2, the user has the ability to share interrupts with other Quatech adapter cards.
The MPA-100 will drive the interrupt onto the bus only when an interrupt occurs. Otherwise, the
output is high impedance. If pins 2 & 3 of J4 are selected, then interrupts abide by the IBM
specification and cannot be shared. Table 4 summarizes the jumper block selections for J4.
Table 4 Jumper Block J4 Selections
Interrupt Function
Interrupt Sharing (Default)
No Interrupt sharing
Pins
1-2
2-3
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5.3 Interrupt Level Selection - J5 & J6
Jumper blocks J5 and J6 select the interrupt level that the MPA-100 utilizes. Interrupt
levels IRQ2 - IRQ7 reside on J5, while interrupt levels IRQ10 - IRQ12 and IRQ14 - IRQ15
reside on J6. Table 5 and Table 6 summarize the jumper block selections for J5 and J6. The
IRQ levels are also marked on the MPA-100 silkscreen for easy identification.
Table 5 Jumper block J5 selections.
Interrupt Level
IRQ2(9)
IRQ3
Pins
1-7
2-8
IRQ4
3-9
4-10
5-11
6-12
IRQ5 (Default)
IRQ6
IRQ7
Table 6 Jumper block J6 selections.
Interrupt Level
Pins
1-6
IRQ10
IRQ11
IRQ12
IRQ14
IRQ15
2-7
3-8
4-9
5-10
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5.4 Transmit DMA Selection - J8
J8 Selects the DMA channel to be used for Transmit DMA. Three channels (1 - 3) are
available on the MPA-100 for DMA. When selecting a DMA channel, both the DMA
acknowledge (DACK) and the DMA request (DRQ) for the appropriate channel need to be
selected. Table 7 summarizes the jumper block selections for J8.
Table 7 Jumper block J8 selections.
DMA Channel
Channel 1
Pins
1-7
2-8
Channel 2
3-9
4-10
5-11
6-12
Channel 3 (Default)
5.5 Receive DMA Selection - J9
J9 selects the DMA channel to be used for Receive DMA. Three channels (1 - 3) are
available on the MPA-100 for DMA. When selecting a DMA channel, both the DMA
acknowledge (DACK) and the DMA request (DRQ) for the appropriate channel need to be
selected. Table 8 summarizes the jumper block selections for J9.
Table 8 Jumper block J9 selections.
DMA Channel
Pins
1-7
Channel 1 (Default)
2-8
Channel 2
Channel 3
3-9
4-10
5-11
6-12
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NOTE:
Since it is illegal to perform DMA on transmit and receive on the
same DMA channel, jumper blocks J7 and J8 should never have the
same pins connected. This could result in damage to the system.
5.6 SYNCA to RLEN Control - J7
J7 controls the signal path from the RLEN bit in the Communications Register to the
SYNCA input to the SCC. If J7 is installed and the SCC is in external SYNC mode, setting the
RLEN bit high will assert the SYNCA pin. Note: the RLEN output is still affected when used to
control the SYNCA pin.
Table 9 Jumper J7 Selections
Function
SYNCA
Jumper J1
1-2
no connections
RLEN (Default)
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6. SCC GENERAL INFORMATION
The Serial Communications Controller (SCC) is a dual channel, multi-protocol data
communications peripheral. The MPA-100 provides a single channel for communications,
however, to provide full DMA capabilities with complete modem control line support, both
channels of the SCC can be utilized. The SCC can be software configured to satisfy a wide
variety of serial communications applications. Some of its protocol capabilities include:
1) Asynchronous Communications
; 5, 6, 7, or 8 bits per character
; 1, 1-1/2, or 2 stop bits
; Odd, even, or no parity
; Times 1, 16, 32, or 64 x clock modes
; Break generation and detection
; Parity, overrun and framing error detection
2) Byte-oriented Synchronous Communications
; Internal/external character synchronization
; 1 or 2 sync characters in separate registers
; Automatic Cyclic Redundancy Check (CRC) generation/detection
3) SDLC/HDLC (Bit Synchronous) Communications
; Abort sequence generation and checking
; Automatic zero insertion and deletion
; Automatic flag insertion between messages
; Address field recognition
; I-field residue handling
; CRC generation and detection
; SDLC loop mode with EOP recognition/loop entry and exit
4) NRZ, NRZI, or FM encoding/decoding
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6.1 Accessing the Registers
The mode of communication desired is established and monitored through the bit values
of the internal read and write registers. The register set of the SCC includes 16 write registers and
9 read registers. These registers only occupy four address locations, which start at the MPA-100's
physical base address that is configured via the on board switches. This and all other addresses
are referenced from this base address in the form Base + Offset. An example of this is Base + 1
for the SCC Control Port, Channel A.
There are two register locations per SCC channel, a data port and a control port .
Accessing the internal SCC registers is a two step process that requires loading a register
pointer to perform the addressing to the correct data register. The first step is to write to the
control port the operation and address for the appropriate channel. The second step is to either
read data from or write data to the control port. The only exception to this rule is when accessing
the transmit and receive data buffers. These registers can be accessed with the two step process
described or with a single read or write to the data port. The following examples illustrate how
to access the internal registers of the SCC. Also, Table 10 describes the read registers and
Table 11 describes the write registers for each channel.
The MPA-100 has been designed to assure that all back to back access timing
requirements of the SCC are met without the need for any software timing control. The standard
of adding jmp $+2 between IO port accesses is not required when accessing the MPA-100.
Example 1: Enabling the transmitter on channel A.
mov
add
mov
out
mov
out
dx,base ; load base address
dx,ContA ; add control reg A offset (1)
al,05H ; write the register number
dx,al
al,08H ; write data to the register
dx,al
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Example 2: Monitoring the status of the transmit and receive buffers in RR0 of Channel A.
Register 0 is addressed by default if no register number is written to WR0 first.
mov
add
in
dx,base ; load base address
dx,ContA ; add control reg A offset (1)
ax,dx
; read the status
Example 3: Write data into the transmit buffer of channel A.
mov
out
dx,base ; load base address
dx,al ; write data in ax to buffer
Example 4: Read data from the receive buffer of channel A.
mov
in
dx,base ; load base address
al,dx ; write data in ax to buffer
Table 10 SCC read register description.
RR0
RR1
RR2
Transmit, Receive buffer statuses and external status
Special Receive Condition status, residue codes, error conditions
Modified Channel B interrupt vector and Unmodified Channel A
interrupt vector
RR3
Interrupt Pending bits
RR6
LSB of frame byte count register
MSB of frame byte count and FIFO status register
Receive buffer
RR7
RR8
RR10
RR12
RR13
RR15
Miscellaneous status parameters
Lower byte of baud rate time constant
Upper byte of baud rate time constant
External/Status interrupt information
The SCC can perform three basic forms of I/O operations: polling, interrupts, and block
transfer. Polling transfers data, without interrupts, by reading the status of RR0 and then reading
or writing data to the SCC buffers via CPU port accesses. Interrupts on the SCC can be sourced
from the receiver, the transmitter, or External/Status conditions. At the event of an interrupt,
Status can be determined, then data can be written to or read from the SCC via CPU port
accesses. For block transfer mode, DMA transfers accomplish data transfers from the SCC to
memory or from memory to the SCC, interrupting the CPU only when the Block is finished.
Further information on these subjects are found in Sections 4 and 7.
The SCC incorporates additional circuitry supporting serial communications. This
circuitry includes clocking options, baud rate generator (BRG), data encoding, and internal
loopback. The SCC may be programmed to select one of several sources to provide the transmit
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and receive clocks. These clocks can be programmed in WR11 to come from the RTXC pin, the
TRXC pin, the output of the BRG, or the transmit output of the DPLL. Programming of the
clocks should be done before enabling the receiver, transmitter, BRG, or DPLL.
Table 11 SCC write register description.
WR0
Command Register, Register Pointer, CRC initialization, resets for
various modes
WR1
WR2
WR3
WR4
Interrupt control, Wait/DMA request control
Interrupt vector
Receiver initialization and control
Transmit/Receive miscellaneous parameters and codes, clock rate,
stop bits, parity
WR5
WR6
WR7
WR7'
WR8
WR9
Transmitter initialization and control
Sync character (1st byte) or SDLC address field
Sync character (2nd byte) or SDLC Flag
Special HDLC Enhancement Register
Transmit buffer
Master interrupt control and reset
WR10 Miscellaneous transmitter/receiver control bits, NRZI, NRZ, FM
coding, CRC reset
WR11 Clock mode and source control
WR12 Lower byte of baud rate time constant
WR13 Lower byte of baud rate time constant
WR14 Miscellaneous control bits: baud rate generator, DPLL control, auto
echo
WR15 External/Status interrupt control
For more information regarding the SCC registers please refer to the manufacturer's
technical manual for the specific part being used.
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6.2 Baud Rate Generator Programming
The baud rate generator (hereafter referred to as the BRG) of the SCC consists of a 16-bit
down counter, two 8-bit time constant registers, and an output divide-by-two. The time constant
for the BRG is programmed into WR12 (least significant byte) and WR13 (most significant
byte). The equation relating the baud rate to the time constant is given below while Table 12
shows the time constants associated with a number of popular baud rates when using the standard
MPA-100 9.8304 MHz clock.
Clock_Frequency
2ꢀBaud_RateꢀClock_Mode
Baud_Const ꢀ
ꢁ 2
Where:
Clock_Frequency = crystal frequency of 9.8304MHz
Clock_Mode = value programmed in WR4
Baud_Rate = desired baud rate
Table 12 Time constants for common baud rates
Baud Rate
38400
Baud Constant (Hex)
007EH
00FEH
19200
9600
4800
2400
1200
600
01FEH
03FEH
07FEH
0FFEH
1FFEH
3FFEH
300
(for 9.8304 MHz Clock)
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6.3 SCC Data Encoding Methods
The SCC provides four different data encoding methods, selected by bits D6 and D5 in
WR10. These four include NRZ, NRZI, FM1 and FM0. The SCC also features a digital
phase-locked loop (DPLL) that can be programmed to operate in NRZI or FM modes. Also, the
SCC contains two features for diagnostic purposes, controlled by bits in WR14. They are local
loopback and auto echo.
For further information on these subjects or any others involving the SCC contact the
manufacturer of the SCC being used for a complete technical manual.
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7. DIRECT MEMORY ACCESS
Direct Memory Access (DMA) is a way of transferring data on the ISA bus directly to
and from memory, resulting in high data transfer rates with very low CPU overhead. The ISA bus
DMA channel(s) to be used are selected through jumper packs J6 and J7. The sources for these
requests originate from the SCC and can be programmed for a variety of DMA modes. These
modes include DMA request on transmit, DMA request on receive, and DMA request on both
transmit and receive.
For DMA request on transmit, the DMA controller should be programmed first for an 8
bit read transfer on the desired channel, but not yet enabled. Then the SCC should be
programmed for DMA request on transmit on the desired DMA source. The sources for DMA
request on transmit are either the W/REQA pin (pin 10) of channel A or the DTR/REQA pin (pin
16) of channel A. The source is then determined by bit D0 of the Configuration Register. After
programming the SCC for DMA, DMA on the MPA-100 should be enabled by setting bit D2 of
the Configuration Register. Next, the DMA on the SCC should be enabled, and finally, the DMA
channel should be unmasked. The DMA controller will write the data in memory to the SCC.
When the transmit buffer of the SCC becomes empty, a DMA request will be generated and the
data will be transferred.
For DMA request on receive, the DMA controller should be programmed first for an 8 bit
write transfer on the desired channel, but not yet enabled. Next, the SCC should be programmed
for DMA request on receive on the desired DMA source. The two sources for DMA request on
receive are either the W/REQA pin (pin 10) of channel A or the W/REQB pin (pin 30) of channel
B. The source is then determined by bit D1 on the Configuration Register. After programming
the SCC for DMA, one should enable the DMA on the MPA-100 by setting bit D3 of the
Configuration Register. Then, the DMA on the SCC should be enabled, and finally the DMA
controller should be enabled. When a character enters the receive buffer of the SCC, a DMA
request is generated. The DMA controller then writes the data from the SCC into memory.
Programming for DMA request on both transmit and receive is simply a combination of
the two. There are three possible configurations that can be used, depending on the sources
selected. The first configuration available uses the W/REQA pin of channel A for DMA request
on receive, and the DTR/REQA pin of channel A for DMA request on transmit. This is done by
setting bit D0 and clearing bit D1 of the Configuration Register. The second configuration uses
the DTR/REQA pin for DMA request on transmit, and the W/REQB pin for DMA request on
receive. This is done by setting both D0 and D1 of the Configuration Register. The third
configuration uses the W/REQA pin of channel A for DMA request on transmit, and the
W/REQB pin of channel B for DMA request on receive. This is done by clearing bit D0 and
setting bit D1 of the Configuration Register. Figure 3 shows a block diagram of the DMA
circuitry on the MPA-100.
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When using the channel A DTR/REQ pin for transmit DMA the SCC must be
programmed so that the request release timing of this pin is identical to the WAIT/REQ
timing. This is done by setting bit D4 of write register 7 prime.
NOTE:
Even though the W/REQA pin can be used for both DMA transmit
and DMA receive, obviously it cannot be used for both
simultaneously. Therefore, bits D0 and D1 of the Configuration
Register should never be cleared at the same time while bits D2 and
D3 are both set. This situation may result in damage to the system.
Figure 3 Block Diagram of DMA on MPA-100
J8
J9
W/REQA
DMATRQ
DMARRQ
DTR/REQA
W/REQB
SCC
PAL
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8. CONFIGURATION REGISTER
The MPA-100 is equipped with an onboard register used for configuring information
such as DMA enables, DMA sources, interrupt enables, and interrupt sources. Below is a detailed
description of the Configuration Register. The address of this register is Base+5. Table 13
details the bit definitions of the Configuration Register.
Table 13 Configuration Register - Read/Write
D7
0
D6
0
D5
D4
D3
D2
D1
D0
INTS1 INTS0 DMREN DMTEN RXSRC TXSRC
D7-D6 - Reserved, always 0.
D5-D4 - INTS1, INTS0, INTERRUPT SOURCE AND ENABLE BITS:
These two bits determine the source of the interrupt. The three
options are
interrupt on terminal count (INTTC), interrupt from the SCC (INTSCC), and interrupt on Test
Mode (INTTM). When the source is set, that interrupt becomes enabled. Below is the mapping
for these bits.
Table 14 Interrupt Sources
INTS1
INTS0
Interrupt
Interrupts Disabled
INTTC
0
0
1
1
0
1
0
1
INTSCC
INTTM
D3 - DMREN, RECEIVE DMA ENABLE:
When set (logic 1), the signal from the SCC’s receive DMA source is passed on to the
selected ISA bus DRQ. When cleared (logic 0), the SCC cannot drive the receive request signal
onto the ISA bus DRQ.
D2 -DMTEN, TRANSMIT DMA ENABLE:
When set (logic 1), the signal from the SCC’s transmit DMA source is passed on to the
selected ISA bus DRQ. When cleared (logic 0), the SCC cannot drive the transmit request signal
onto the ISA bus DRQ.
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D1 -RXSRC, RECEIVE DMA SOURCE:
When set (logic 1), this bit allows the source for Receive DMA to come from the
W/REQB pin of channel B on the SCC. When cleared (logic 0), the source for Receive DMA
comes from the W/REQA pin of channel A on the SCC.
D0 -TXSRC, TRANSMIT DMA SOURCE:
When set (logic 1), this bit allows the source for Transmit DMA to come from the
DTR/REQA pin of channel A on the SCC. When cleared (logic 0), the source for Transmit DMA
comes from the W/REQA pin of channel A of the SCC.
NOTE:
Even though the W/REQA pin can be used for both DMA transmit
and DMA receive, obviously it cannot be used for both
simultaneously. Therefore, bits D0 and D1 of the Configuration
Register should never be cleared at the same time while bits D2 and
D3 are both set. This situation may result in damage to the system.
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9. COMMUNICATIONS REGISTER
The MPA-100 is equipped with an onboard Communications Register which gives the
user options pertaining to the clocks and testing. The user can specify the source and type of
clock to be transmitted or received. Test mode bits pertain only to the DTE versions and can be
ignored if using a DCE configured MPA-100. The address of this register is Base+4. Table 15
and the descriptions that follow detail the Communications Register.
NOTE:
The Local Loopback Test and the Remote Loopback Test cannot be
performed simultaneously. Thus, bits D5 and D4 of the
Communications Register should not be set (logic 1) simultaneously.
Table 15 Communications Register - Read/Write
D7
D6
0
D5
D4
D3
D2
D1
0
D0
0
TM ST
LLEN RLEN RCKEN TCKEN
D7 -TEST MODE STATUS:
This bit can read the status of the Test Mode signal on a MPA-100
configured as
DTE, allowing the user to monitor this signal without generating any interrupts.
D6 - Reserved, always 0.
D5 -LOCAL LOOPBACK ENABLE:
When set (logic 1), this bit allows the DTE to test the functionality of the DTE/DCE
interface and the transmit and receive sections of the local DCE. When cleared (logic 0), no
testing occurs. This can also be used as a general purpose output.
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D4 -REMOTE LOOPBACK ENABLE:
When set (logic 1), this bit allows the DTE to test the transmission path up to and through
the remote DCE to the DTE interface and the similar return transmission path. When cleared
(logic 0), no testing occurs. If jumper J7 is in place the Remote Loopback is also used to control
the Sync input of the Channel A data receiver. This is useful in situations where it is desired to
receive unformatted serial data.
D3 -RECEIVE CLOCK ENABLE (DCE only):
When set (logic 1), this bit allows the DCE to transmit its Receive Clock (RCLK). When
cleared (logic 0), the DCE receives RCLK. Since a DTE can only receive RCLK, writing to this
bit has no effect on a DTE.
D2 -TRANSMIT CLOCK ENABLE (DTE only):
When set (logic 1), this bit allows the DTE to transmit its Transmit Clock (TCLK). When
cleared (logic 0), the DTE receives TCLK. Since a DCE can only transmit its TCLK, writing to
this bit has no effect on a DCE.
D1 RESERVED:
This bit should always be programmed to 0.
D0 RESERVED:
This bit should always be programmed to 0.
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10. DTE/DCE CONFIGURATION
As indicated earlier in this manual, the MPA-100 can be configured as either a Data
Terminal Equipment (DTE) or a Data Communications Equipment (DCE) device. The
differences between these configurations include signal definitions, connector pin out, and
clocking options. In order to simplify matters, an in depth description of each configuration is
provided in the next two sections.
NOTE:
Because the connector used for the DCE configuration is the same
one as is used for the DTE configuration the MPA-100 does not have a
true DCE implementation. The DCE configuration is provided to allow
the head-to-head connection of two MPA-100 boards (one configured
DTE and the other DCE).
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10.1 DTE Configuration
The MPA-100 is configured as a DTE device by correctly setting jumper packs J2, J11
and J12. See Section 5, Table 3 for this configuration information.
The control signals the DTE can generate are Request To Send (RTS) and Data Terminal
Ready (DTR). It can receive the signals Carrier Detect (CD), Clear To Send (CTS), and Data Set
Ready (DSR). All the control signals are handled through channel A of the SCC, with the
exception of the DSR signal, which is received on the DCDB pin (pin 21) on channel B.
Depending on TCKEN (bit D2 of the Communications Register), the DTE can either
transmit its Transmit Clock (TCLK) from the TRXCA pin (pin 14) of the SCC, or receive its
TCLK on the same pin. RCKEN (bit D3 of the Communications Register) is always deasserted
on a DTE configured MPA-100; therefore the DTE can receive its Receive Clock (RCLK) on the
RTXC pins (pin 12 & 28) of the SCC but, as per the EIA-232D specification, the DTE cannot
transmit its receive clock. For clarity, the DTE clock configuration is shown in Figure 4.
Figure 4 DTE Clock Configuration
RXCLK (DCE)
RTXCA
(RCLK)
RTXCB
RCKEN
TXCLK (DTE)
TXCLK (DCE)
TRXCA
(TCLK)
TCKEN
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The testing signals the DTE can generate are the Local Loopback Test (LL) and the
Remote Loopback Test (RL). These signals are generated from the onboard Communications
Register. When a Test Mode (TM) condition is received, an interrupt can be generated on the
DTE. Table 16 summarizes the signals on the DTE.
Table 16 DTE Signals
Signal
RTS
CTS
DTR
DSR
CD
Received
Generated
X
SCC Pin or Register Bit
RTSA pin of SCC
X
CTSA pin of SCC
X
X
DTR/REQA of SCC
DCDB pin of SCC
X
X
X
X
DCDA pin of SCC
TxCLK
RxCLK
LL
TRXCA pin of SCC
RTXC pins of SCC
Bit D5 of Comm Reg
Bit D4 of Comm Reg
INTM or Bit D7 of Comm Reg
X
X
RL
TM
X
10.2 DCE Configuration
The MPA-100 is configured as a DCE device by correctly setting the jumper packs J2,
J11 and J12. See Section 5, Table 3 for this configuration information. It is noted that because
the connector used for the DCE configuration is the same one used for the DTE configuration the
MPA-100 does not have a true DCE implementation. However, the pin out is correct for a one to
one wired connection with a DTE.
The RS232C standard defines each signal with respect to the DTE. The difference
between the DTE and DCE signals is that, with the exception of a few control signals, the pins
used for signal transmission on the DTE are used for signal reception on the DCE and vice versa.
For example, pin 2 of the DCE connector is received data, yet the corresponding DTE signal is
the transmitted data. This correspondence allows the user to connect a DTE device to a DCE
device and perform communication without the use of any customized cable or adapter.
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Control signals the DCE can generate are the Clear to Send (CTS), Carrier Detect (CD),
and Data Set Ready (DSR). It can receive the signals Data Terminal Ready (DTR) and Ready to
Send (RTS). All the control signals are handled through channel A of the SCC, with the
exception of the CD signal, which is generated on the DTR/REQB pin (pin 24) of the SCC.
Depending on RCKEN (bit D3 of the Communications Register), the DCE can either
transmit its Receive Clock (RCLK) from the TRXCB pin (pin 26) of the SCC, or receive its
Receive Clock on the RTXC pins (pins 12 and 28) of the SCC. TCKEN (bit D2 of the
Communications Register) is always asserted on a DTE configured MPA-100; therefore the DCE
can transmit its Transmit Clock (TCLK) from the TRXCA pin (pin 14) but, as per the EIA-232D
specification, the DCE cannot receive its Transmit Clock. For clarity, the DCE clock
configuration is shown in Figure 5.
Figure 5 DCE Clock Configuration
TXCLK (DTE)
TXCLK (DCE)
RTXCA
(RCLK)
RTXCB
TRXCB
RCKEN
TRXCA
(TCLK)
RXCLK (DCE)
The test mode signals for the DCE configuration are the same those for the DTE
configuration. These signals are Local Loopback Test (LL) and Remote Loopback Test (RL) for
outputs and Test Mode (TM) for input.
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Table 17 DCE Signals
Signal
RTS
CTS
DTR
DSR
CD
Received
Generated
X
SCC Pin or Register Bit
CTSA pin of SCC
X
RTSA pin of SCC
X
DCDA of SCC
X
X
X
X
X
X
DTR/REQA pin of SCC
DTR/REQB pin of SCC
TRXCA pin of SCC
TxCLK
RxCLK
LL
X
X
RTXC/TRXCB pin of SCC
Bit D5 of Comm. Reg
Bit D4 of Comm Reg
INTM or Bit D7 of Comm Reg
RL
TM
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11. EXTERNAL CONNECTIONS
The MPA-100 is designed to meet the RS-232 standard through a D-25 connector. The
MPA-100 uses a D-25 short body male connector (labeled CN1) for both the DTE and DCE
configurations. Jumper blocks J2, J11, and J12 configure the connector pin out. Table 18 and
Table 19 display the pin out definitions for both configurations while Figure 6 and Figure 7
illustrate the pin-outs for each of the configurations. The definitions of the interchange circuits
according to the RS-232-D standard can be found in Section 12.
Table 18 DTE Connector Pin Definitions
PIN
1
2
SIGNAL
CGND
TXD
RECEIVED GENERATED
SOURCE
-
-
-
X
TXDA on SCC
3
RXD
X
RXDA on SCC
4
5
6
7
RTS
CTS
DSR
DGND
CD
X
-
RTSA on SCC
CTSA on SCC
DCDB on SCC
-
X
X
-
X
8
DCDA on SCC
9
N/C
-
-
-
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
N/C
RXCLK (DTE)
N/C
N/C
N/C
TXCLK (DCE)
N/C
RXCLK (DCE)
LL
-
-
-
N/A
-
-
-
X
-
N/A
N/A
-
-
-
-
-
-
TRXCB on SCC
-
TRXCA on SCC
D5 of COMM REG
-
X
X
-
X
X
-
N/C
DTR
RL
N/C
-
-
DTR/REQA on SCC
D4 of COMM REG
-
-
TRXCA on SCC
D7 of COMM REG
-
-
N/C
TXCLK (DTE)
TEST MODE
-
X
X
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Table 19 DCE Connector Pin Definitions
PIN
1
2
SIGNAL
CGND
TXD
RECEIVED GENERATED
SOURCE
-
-
-
X
RXDA on SCC
3
RXD
X
TXDA on SCC
4
5
6
7
RTS
CTS
DSR
DGND
CD
X
-
CTSA on SCC
RTSA on SCC
DTR/REQA on SCC
-
X
X
-
X
8
DTR/REQB on SCC
9
N/C
-
-
-
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
N/C
RXCLK (DTE)
N/C
N/C
N/C
TXCLK (DCE)
N/C
RXCLK (DCE)
LL
-
-
-
N/A
-
-
-
X
-
N/A
N/A
-
-
-
-
-
-
TRXCA on SCC
-
RTXC pins on SCC
D5 of COMM REG
-
X
X
-
N/C
DTR
RL
N/C
-
X
-
DCDB on SCC
D4 of COMM REG
-
-
RTXC pins on SCC
D7 of COMM REG
X
-
-
-
-
N/C
TXCLK (DTE)
TEST MODE
X
X
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Figure 6 MPA-100 DTE Output Connector Configuration
N/C 13
25 Test Mode (Output)
24 TxCLK (DTE)
23 N/C
22 N/C
21 RLBK (Output)
20 DTR
N/C 12
RxCLK (DTE) 11
N/C 10
N/C 9
CD 8
DGND 7
19 N/C
DSR 6
CTS 5
RTS 4
18 LLBK (Output)
17 RxCLK (DCE)
16 N/C
15 TxCLK (DCE)
14 N/C
RxD 3
TxD 2
CGND 1
Figure 7 MPA-100 DCE Output Connector Configuration
CGND 1
RxD 2
14 N/C
15 TxCLK (DCE)
TxD 3
16 N/C
17 RxCLK (DCE)
CTS
4
RTS 5
DTR 6
18 LLBK (Output)
19 N/C
DGND 7
CD 8
20 DSR
21 RLBK (Output)
N/C 9
N/C 10
22 N/C
23 N/C
RxCLK (DTE) 11
N/C 12
24 TxCLK (DTE)
25 TestMode (Input)
N/C 13
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12. DEFINITION OF INTERFACE SIGNALS
CIRCUIT AB - Signal Ground
; CONNECTOR NOTATION: DGND
; DIRECTION: Not applicable
This conductor directly connects the DTE circuit ground to the DCE circuit ground.
CIRCUIT CC - DCE Ready (Data Set Ready)
; CONNECTOR NOTATION: DSR
; DIRECTION: From DCE
This signal indicates the status of the local DCE by reporting to the DTE device that a
communication channel has been established.
CIRCUIT BA - Transmitted Data
; CONNECTOR NOTATION: TXD
; DIRECTION: To DCE
This signal transfers the data generated by the DTE through the
communication channel to one or more remote DCE data stations.
CIRCUIT BB - Received Data
; CONNECTOR NOTATION: RXD
; DIRECTION: From DCE
This signal transfers the data generated by the DCE, in response to data channel line
signals received from a remote DTE data station, to the DTE.
CIRCUIT DA - Transmit Signal Element Timing (TxCLK- DTE Source)
; CONNECTOR NOTATION: TXCLK (DTE)
; DIRECTION: To DCE
This signal, generated by the DTE, provides the DCE with element timing information pertaining
to the data transmitted by the DTE. The DCE can use this information for its received data.
CIRCUIT DB -Transmit Signal Element Timing (TxClk - DCE Source)
; CONNECTOR NOTATION:TXCLK (DCE)
; DIRECTION: From DCE
This signal, generated by the DCE, provides the DTE with element timing information
pertaining to the data transmitted to the DCE. The DCE can use this information for its received
data.
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CIRCUIT DD -Receiver Signal Element Timing(RxClk - DCE Source)
; CONNECTOR NOTATION: RXCLK (DCE)
; DIRECTION: From DCE
This signal, generated by the DCE, provides the DTE with element timing information
pertaining to the data transmitted by the DCE. The DTE can use this information for its received
data.
CIRCUIT CA - Request To Send
; CONNECTOR NOTATION: RTS
; DIRECTION: To DCE
This signal controls the data channel transmit function of the local DCE and, on a
half-duplex channel, the direction of the data transmission of the local DCE.
CIRCUIT CB - Clear To Send
; CONNECTOR NOTATION: CTS
; DIRECTION: From DCE
This signal indicates to the DTE whether the DCE is conditioned to
transmit data on the communication channel.
CIRCUIT CF - Received Line Signal Detector (CARRIER DETECT)
; CONNECTOR NOTATION: CD
; DIRECTION: From DCE
This signal indicates to the DTE whether the DCE is conditioned to
receive
data from the communication channel, but does not indicate the relative quality of the data
signals being received.
CIRCUIT CD - DTE Ready (Data Terminal Ready)
; CONNECTOR NOTATION: DTR
; DIRECTION: To DCE
This signal controls the switching of the DCE to the communication
DTE will generate this signal to prepare the DCE to be connected to or removed from the
communication channel.
channel. The
CIRCUIT LL - Local Loopback
; CONNECTOR NOTATION: LLBK
; DIRECTION: To DCE
This signal provides a means whereby a DTE may check the
functioning of the DTE/DCE interface and the transmit and receive sections of the local DCE.
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CIRCUIT RL - Remote Loopback
; CONNECTOR NOTATION: RLBK
; DIRECTION: To DCE
This signal provides a means whereby a DTE or a facility test center may check the
transmission path up to and through the remote DCE to the DTE interface and the similar return
transmission path.
CIRCUIT TM - Test Mode
; CONNECTOR NOTATION: TEST MODE
; DIRECTION: From DCE
This signal indicates to the DTE that the DCE is in a test condition. The DCE generates
this signal when it has received a local loopback or remote loopback signal from the DTE.
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13. SPECIFICATIONS
Bus interface: IBM AT 16-bit bus
Controller:
Serial Communications Controller, 10 MHz
(determined by user, typically an AMD 85C30).
Interface:
DTE: male D-25 connector
Transmit drivers:
Receive buffers:
RS-232:
RS-232:
MC1488 or compatible
MC1489 or compatible
I/O Address range: 0000H - FFFFH
Interrupt levels:
DMA levels:
IRQ 2-7, 10-12, 14-15
DMA Channel 1, 2, and 3 on transmit and
receive.
Physical Dimensions: 4.2” x 7.65”
Power requirements:
ITyp (mA)
IMax (mA)
Supply Voltage (Volts)
1248
25
1402
36
5
12
-12
25
36
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MPA-100
User's Manual
Version 4.12
March 2004
Part No. 940-0037-412
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