Spectrum Brands Network Card C6x VME64 User Manual

Monaco  
Quad 'C6x VME64 Board  
Technical Reference  
Document Number 500-00191  
Revision 2.00  
September 1999  
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Spectrum Signal Processing  
Monaco Technical Reference  
Preface  
Preface  
Spectrum Signal Processing offers a complete line of DSP hardware, software and I/O  
products for the DSP Systems market based on the latest DSP microprocessors, bus  
interface standards, I/O standards and software development environments. By delivering  
quality products, and DSP expertise tailored to specific application requirements,  
Spectrum can consistently exceed the expectations of our customers. We pride ourselves  
in providing unrivaled pre- and post-sales support from our team of application  
engineers. Spectrum’s excellent relationships with third party vendors provide customers  
with a diverse and top quality product offering.  
About  
Spectrum  
In 1994, Spectrum achieved ISO 9001 quality certification.  
Spectrum’s Applications Engineers are available to provide technical support Monday to  
Friday, 8:00 AM to 5:00 PM, Pacific Standard Time.  
Contacting  
Spectrum  
Telephone 1-800-663-8986 or (604) 421-5422  
Fax  
(604) 421-1764  
Email  
Internet  
To help us assist you better and faster, please have the following information ready:  
A concise description of the problem  
The names of all Spectrum hardware components  
The names and version numbers of all Spectrum software components  
The minimum amount of code that demonstrates the problem  
The versions of all software packages, including compilers and operating systems  
At Spectrum, we know that accurate and easy to use manuals are important to help you  
develop your applications and products. If you wish to comment on this manual, please  
e-mail us at [email protected] or fax us at (604) 421-1764. Please  
include the following information:  
Customer  
Feedback  
The full name, document number, and version of the manual  
A description of any inaccuracies you may have found  
Comments about what you liked or did not like about the manual  
It may be helpful for us to call you to discuss your comments. If this would be acceptable  
please include your name, organization, and telephone number with your comments.  
Note: Spectrum board products are static sensitive and can be damaged by electrostatic  
discharges if not properly handled. Use proper electrostatic precautions whenever  
handling Spectrum board products.  
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Spectrum Signal Processing  
Preface  
Document  
Change  
History  
Rev.  
Date  
Changes  
Section  
2.00 Sept 1999  
Updated for TMS320C6201B and TMS320C6701  
DSPs  
n.a.  
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Monaco Technical Reference  
Table of Contents  
Table of Contents  
1 Introduction..............................................................................................................................1  
1.1. Features....................................................................................................................................1  
1.2. Interfaces ..................................................................................................................................2  
1.2.1. VME.............................................................................................................................2  
1.2.2. PMC ............................................................................................................................2  
1.2.3. PEM.............................................................................................................................2  
1.2.4. Serial Ports..................................................................................................................2  
1.2.5. JTAG...........................................................................................................................2  
1.3. Reference Documents ..............................................................................................................3  
1.4. General Bus Architecture..........................................................................................................4  
1.5. On-Board Power Supply ...........................................................................................................4  
1.6. Reset Conditions.......................................................................................................................5  
1.6.1. VME SYSRESET ........................................................................................................5  
1.6.2. VME A24 Slave Interface Reset..................................................................................5  
1.6.3. JTAG Reset.................................................................................................................5  
1.7. Board Layout.............................................................................................................................6  
1.8. Jumper settings.........................................................................................................................7  
2 Processor Nodes.....................................................................................................................9  
2.1. Processor Memory Configuration ...........................................................................................11  
2.1.1. Internal Memory ........................................................................................................11  
2.1.2. External Memory.......................................................................................................11  
2.2. Synchronous Burst SRAM ......................................................................................................15  
2.3. Synchronous DRAM ...............................................................................................................15  
2.4. Processor Expansion Module .................................................................................................15  
2.5. Host Port .................................................................................................................................15  
2.6. Interrupt Lines .........................................................................................................................15  
2.7. Processor Booting...................................................................................................................16  
2.8. Serial Port Routing..................................................................................................................17  
3 Global Shared Bus ................................................................................................................19  
3.1. Memory ...................................................................................................................................19  
3.2. Arbitration................................................................................................................................19  
3.2.1. Single Cycle Bus Access ..........................................................................................20  
3.2.2. Burst Cycle Bus Access............................................................................................20  
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3.2.3. Locked Cycles...........................................................................................................21  
4 VME64 Bus Interface ............................................................................................................23  
4.1. VME Operation........................................................................................................................23  
4.2. SCV64 Primary Slave A32/A24 Interface................................................................................23  
4.3. A24 Secondary Slave Interface...............................................................................................24  
4.4. Master A32/A24/A16 SCV64 Interface....................................................................................27  
5 DSP~LINK3 Interface............................................................................................................29  
5.1. DSP~LINK3 Data Transfer Operating Modes.........................................................................29  
5.2. Address Strobe Control Mode.................................................................................................30  
5.3. Interface Signals .....................................................................................................................31  
5.4. DSP~LINK3 Reset ..................................................................................................................31  
6 PCI Interface .........................................................................................................................33  
6.1. Hurricane Configuration ..........................................................................................................33  
6.2. Hurricane Implementation.......................................................................................................36  
7 JTAG Debugging...................................................................................................................37  
8 Interrupt Handling..................................................................................................................39  
8.1. Overview .................................................................................................................................39  
8.2. DSP~LINK3 Interrupts to Node A ...........................................................................................40  
8.3. PEM Interrupts ........................................................................................................................41  
8.4. PCI Bus Interrupts...................................................................................................................41  
8.5. Hurricane Interrupt ..................................................................................................................41  
8.6. SCV64 Interrupt ......................................................................................................................41  
8.7. Bus Error Interrupts.................................................................................................................43  
8.8. Inter-processor Interrupts........................................................................................................44  
8.9. VME Host Interrupts To Any Node..........................................................................................44  
9 Registers...............................................................................................................................45  
VPAGE Register..................................................................................................................46  
VSTATUS Register .............................................................................................................47  
VINTA Register ...................................................................................................................49  
VINTB Register ...................................................................................................................50  
VINTC Register ...................................................................................................................51  
VINTD Register ...................................................................................................................52  
KIPL Enable Register.........................................................................................................53  
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DSP~LINK3 Register ..........................................................................................................54  
ID Register ..........................................................................................................................55  
VME A24 Status Register....................................................................................................56  
VME A24 Control Register ..................................................................................................57  
10 Specifications ......................................................................................................................59  
10.1. Board Identification ...............................................................................................................59  
10.2. General .................................................................................................................................60  
10.3. Performance and Data Throughput ......................................................................................61  
11 Connector Pinouts...............................................................................................................63  
11.1. VME Connectors...................................................................................................................64  
11.2. PMC Connectors...................................................................................................................67  
11.3. PEM Connectors...................................................................................................................71  
11.4. JTAG Connectors .................................................................................................................73  
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List of Figures  
Figure 1 Block Diagram...................................................................................................................4  
Figure 2 Board Layout.....................................................................................................................6  
Figure 3 Processor Node Block Diagram ......................................................................................10  
Figure 4 DSP Memory Map...........................................................................................................13  
Figure 5 DSP Memory Map for External-Memory Space CE1 ......................................................14  
Figure 6 Serial Port Routing ..........................................................................................................17  
Figure 7 Global Bus Arbitration .....................................................................................................20  
Figure 8 Primary VME A24/A32 Memory Map ..............................................................................24  
Figure 9 A24 Secondary Interface Memory Map...........................................................................25  
Figure 10 PCI Memory Map ..........................................................................................................33  
Figure 11 JTAG Chain...................................................................................................................37  
Figure 12 Interrupt Routing............................................................................................................40  
Figure 13 Connector Layout..........................................................................................................63  
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List of Tables  
Table 1 Reset Summary..................................................................................................................5  
Table 2 Jumper Settings..................................................................................................................7  
Table 3 Processor Configurations ...................................................................................................9  
Table 4 'C6x Internal Peripheral Register Values..........................................................................12  
Table 5 Processor Boot Source Jumpers......................................................................................16  
Table 6 PEM Connections for Serial Port 0 and 1.........................................................................18  
Table 7 VME and PMC Connections for Serial Port 1....................................................................18  
Table 8 Global Shared Bus Access...............................................................................................19  
Table 9 HPI Register Addresses ...................................................................................................26  
Table 10 DSP~LINK3 Data Transfer Operating Modes ................................................................30  
Table 11 Hurricane Register Set ...................................................................................................34  
Table 12 KIPL Status Bits and the IACK Cycle .............................................................................42  
Table 13 Register Address Summary............................................................................................45  
Table 14 Specifications .................................................................................................................60  
Table 15 Data Access/Transfer Performance ...............................................................................61  
Table 16 VME P1 Connector Pinout..............................................................................................64  
Table 17 VME P2 Connector Pinout (PMC to VME P2)................................................................65  
Table 18 VME P2 Connector (DSP~LINK3 to VME P2)................................................................66  
Table 19 PMC Connector JN1 Pinout ...........................................................................................67  
Table 20 PMC Connector JN2.......................................................................................................68  
Table 21 PMC Connector JN4.......................................................................................................69  
Table 22 Non-standard PMC Connector JN5................................................................................70  
Table 23 PEM 1 Connector Pinout................................................................................................71  
Table 24 PEM 2 Connector Pinout................................................................................................72  
Table 25 JTAG IN Connector Pinout.............................................................................................73  
Table 26 JTAG OUT Connector ....................................................................................................73  
Table 27 SCV64 Register Initialization ..........................................................................................75  
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Introduction  
1 Introduction  
This manual describes the features, architecture, and specifications of the Monaco Quad  
'C6x VME64 Board. You can use this information to program the board at a driver level,  
extend the standard hardware functionality, or develop custom configurations.  
1.1. Features  
Spectrum’s Monaco VME64 board consists of four TMS320C6x processing nodes. It is  
available with either fixed-point or floating-point TMS320C6x processors.  
Product  
Operation  
Processors  
Processor Clock Speed  
Monaco  
Fixed-point  
TMS320C6201 200 MHz  
Monaco67 Floating-point TMS320C6701 167 MHz  
Both the Monaco and the Monaco67 are referred to as “Monaco” in this manual unless  
otherwise noted.  
Monaco has the following features:  
Up to four TMS320C6201 or TMS320C6701 processing nodes  
128K x 32-bit of SBSRAM per processing node  
4M x 32-bit of SDRAM per processing node  
Shared access to a 132 MBytes/s PMC module site via the Spectrum Hurricane chip  
512K x 32-bit of fast, globally shared SRAM accessible to the processor nodes, PCI  
interface, and VME64 interface.  
VME64 master/slave interface provided by Tundra Semiconductor’s SCV64 chip  
VME A24 slave interface access to the ‘C6x Host Port Interfaces (HPIs)  
JTAG debugging support  
Two PEM (Processor Expansion Module) sites  
DSP~LINK3 I/O interface supporting IndustryPack™ modules  
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1.2. Interfaces  
In addition to the VME bus which provides the primary interface to the host computer,  
the Monaco board features PMC, PEM, serial port, DSP~LINK3 and JTAG interfaces.  
1.2.1. VME  
Two VMEbus interfaces are provided on the Monaco board. The primary dataflow  
interface supports VME64 master and slave modes for fast data transfer through the  
SCV64 interface chip.  
A secondary interface gives the VME A24 bus direct access to the Host Port Interface  
(HPI) of each ‘C6x. This provides direct control and data transfer to and from the DSP  
without interfering with dataflow on the Monaco’s Global Shared Bus.  
1.2.2. PMC  
The Spectrum Hurricane PCI bridge chip supports high-speed data transfer from an on-  
board PMC site to the shared memory. The industry-standard IEEE-1386 PMC module  
site allows developers to select from a wide variety of third-party modules.  
1.2.3. PEM  
Four independent high-speed, full-bandwidth, bi-directional, dataflow channels between  
standard mezzanine boards (Processor Expansion Modules, or PEMs) and the ‘C6x  
processors are supported. Application-specific interfaces, mounted to the PEM, are  
available for computer telephony, digital radio as well as customer-specified interfaces.  
1.2.4. Serial Ports  
Two serial ports from each ‘C6x are available at each PEM site for on-board I/O  
expansion. For each ‘C6x, one of the serial ports is always routed to the PEM site, the  
second can be routed to either the PEM site or the VME P2 connector.  
1.2.5. JTAG  
The secondary VME interface allows access to the on-board JTAG Test Bus Controller  
(TBC) from a host single-board computer for diagnostic purposes.  
2
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1.3. Reference Documents  
Monaco Installation Guide from Spectrum  
Monaco Programming Guide from Spectrum  
DSP~LINK3 Specification from Spectrum  
PEM Specification from Spectrum  
TMS320C6000 Peripherals Reference Guide from Texas Instruments  
SCV64 User Manual from Tundra Semiconductor Corporation  
Hurricane Data Sheet from Spectrum  
Draft Standard Physical and Environmental Layers for PCI Mezzanine Cards: PMC  
IEEE P1386.1/Draft 2.0 available from IEEE  
VME64 ANSI/VITA 1-1994 available from ANSI  
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1.4. General Bus Architecture  
The following block diagram shows the main components of the Monaco board.  
'C6x Host Port Inteface (HPI)  
JTAG  
Node A  
'C6x  
Node B  
'C6x  
Node C  
'C6x  
Node D  
'C6x  
PEM Site  
PEM Site  
SBSRAM  
128K x 32  
SBSRAM  
128K x 32  
SBSRAM  
128K x 32  
DSP~LINK3 Interface  
SDRAM  
4M x 32  
SDRAM  
4M x 32  
SDRAM  
4M x 32  
SBSRAM  
128K x 32  
SDRAM  
4M x 32  
PMC  
Site  
Address Buffer  
and  
Data Latches  
Address Buffer  
and  
Data Latches  
Address Buffer  
and  
Data Latches  
Address Buffer  
and  
Data Latches  
PCI  
Bus  
Test Bus  
Controller  
Hurricane  
Global Shared Bus  
SCV64  
A24 VME  
Slave  
Interface  
Global Shared  
SRAM  
512K x 32  
VME64  
Interface  
VME P1 Connector  
VME P2 Connector  
Figure 1 Block Diagram  
1.5. On-Board Power Supply  
There is an on-board high-efficiency DC-DC power converter that supplies +2.5V and  
+3.3V power to the board from the VME 5V supply. The circuit efficiency is  
approximately 90%. The +3.3V supply is available to the PEM and PMC sites, as well as  
+5V and ±12V. Up to 16.5 Watts is available from the +3.3V supply for the PEM and  
PMC sites. The combined +3.3V current consumption of modules on these sites must not  
exceed 5 Amps.  
When adding modules to the Monaco board, ensure that the power requirements for the  
modules are within the specified limits, and that the system power supply and cooling are  
sufficient to meet the added requirements.  
4
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1.6. Reset Conditions  
The Monaco board responds to three types of reset conditions:  
VME SYSRESET (VME bus /SYSRESET line)  
VME A24 Slave Interface Reset (VME A24 Control Register bit D0)  
JTAG reset (JTAG chain /TRST line)  
The following table indicates which hardware components are reset by the specific reset  
condition.  
Table 1 Reset Summary  
Reset Condition (Y = Component is Reset)  
Hardware  
Processor Nodes  
SYSRESET  
Slave Interface Reset  
JTAG Reset  
Y
Y
Y
Y
Y
Y
Y
Y
Y
Y
SCV64 VME Interface chip  
HPI registers  
Y
Y
Y
Y
Y
Y
Y
Global Shared Bus registers  
VME A24 slave interface registers  
JTAG (within DSPs)  
PEM interface  
Y
PMC interface  
DSP~LINK3 interface  
1.6.1. VME SYSRESET  
A VME SYSRESET is initiated when the /SYSRESET line on the VME bus is driven  
low. All devices and registers on the Monaco board are reset to their default conditions.  
1.6.2. VME A24 Slave Interface Reset  
The VME A24 slave interface reset is initiated from the VME bus by setting bit D0 of  
the VME A24 Control Register to “0”. All devices and registers on the Monaco board  
are reset to their default conditions except for the SCV64 VME interface chip. The  
VME A24 Control Register is located at VME A24 Base Address + 1004h. The base  
address for the VME A24 slave interface is set by jumper block JP1.  
1.6.3. JTAG Reset  
The JTAG path can be reset by asserting the /TRST line of the JTAG chain by an  
EMURST from the XDS or TBC. Only the JTAG path of the DSPs is reset by this  
action; no other devices or registers on the board are affected.  
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1.7. Board Layout  
The following diagram shows the board layout of the Monaco board.  
JP10 JP9 JP8 JP7  
JP4 JP5  
Node D  
‘C6x  
JN7  
JN6  
PEM Site  
Nodes C and D  
VME  
P1  
JN8  
JN9  
Node C  
‘C6x  
JN10  
JN11  
Node B  
‘C6x  
JP3  
JP2  
PEM Site  
Nodes A and B  
JP1  
1
3
5
7
8
2
4
6
8
9
JN13  
JN12  
Node A  
‘C6x  
10 11  
12 13  
JN1  
JN2  
JN5  
VME  
P2  
PMC Site  
JN4  
J3  
J1  
JTAG IN  
Connector  
J2  
JTAG OUT  
Connector  
J8  
DSP~LINK3 Ribbon Cable Connector  
Figure 2 Board Layout  
6
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1.8. Jumper settings  
Table 2 Jumper Settings  
Jumper  
Description  
IN  
OUT  
JP1 Pins 1-2  
JP1 Pins 3-4  
JP1 Pins 5-6  
JP1 Pins 7-8  
JP1 Pins 9-10  
JP1 Pins 11-12  
JP1 Pins 13-14  
VME A24 slave interface base address bit A23  
VME A24 slave interface base address bit A22  
VME A24 slave interface base address bit A21  
VME A24 slave interface base address bit A20  
VME A24 slave interface base address bit A19  
VME A24 slave interface base address bit A18  
VME A24 slave interface base address bit A17  
0
1*  
1
1
1
1
1
1
0*  
0*  
0*  
0*  
0*  
0*  
JP2  
JP3  
JP4  
JP5  
JP7  
JP8  
JP9  
JP10  
Node A boot mode  
PEM  
PEM  
HPI*  
HPI*  
Node B boot mode  
Node C boot mode  
PEM  
HPI*  
Node D boot mode  
PEM  
HPI*  
Node A Serial Port 1 Routing  
Node B Serial Port 1 Routing  
Node C Serial Port 1 Routing  
Node D Serial Port 1 Routing  
VME P2  
VME P2  
VME P2  
VME P2  
PEM*  
PEM*  
PEM*  
PEM*  
* Default position  
The default VME A24 slave interface base address is set to 80 0000h.  
Note:  
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Processor Nodes  
2 Processor Nodes  
The Monaco board supports one, two or four embedded ‘C6X processor nodes shared  
across the Global Shared Bus. The three possible processor configurations are described  
in the following figure.  
Table 3 Processor Configurations  
Populated  
Configuration  
One Node  
Node A  
Node B  
Node C  
Node D  
Y
Y
Y
Two Nodes  
Four Nodes  
Y
Y
Y
Y
Each DSP node consists of:  
One TMS320C6201 DSP operating at 200 MHz for Monaco, or one TMS320C6701  
DSP operating at 167 MHz for Monaco67  
128K of 32-bit Synchronous burst SRAM (SBSRAM)  
4M of 32-bit Synchronous DRAM (SDRAM)  
Processor Expansion Module (PEM) interface  
A slave Host Port Interface to VME A24 bus  
Two serial ports  
A DSP~LINK3 interface (DSP node A only)  
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Processor Nodes  
JTAG Test Bus  
‘C6x Host Port  
Interface (HPI) Bus  
Node Local  
Resources  
Serial  
Port 0  
‘C6x  
DSP  
Serial  
Port 1  
128K x 32  
SBSRAM  
PEM Site  
4M x 32  
SDRAM  
Shared with  
Node Pair  
DSP  
Local  
Bus  
DSP-LINK3  
Interface  
Node A  
Only  
Address Buffer  
and  
Data Latches  
Global Shared Bus  
Figure 3 Processor Node Block Diagram  
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Processor Nodes  
2.1. Processor Memory Configuration  
Each ‘C6X DSP processor implements a 4 Gigabyte (full 32-bit) address space. This  
address space is partitioned into internal memory space and external memory space.  
External memory space is accessed through four memory select lines (CE0, CE1, CE2  
and CE3).  
2.1.1. Internal Memory  
Internal memory space is further separated into three distinct regions:  
internal program RAM (64Kbytes)  
internal peripheral registers (2 Mbytes)  
internal data RAM (64 Kbytes)  
These three regions define memory space which is implemented in the DSP processor.  
2.1.2. External Memory  
External memory is segmented into 4 regions:  
external memory interface CE0 (16 Mbytes)  
external memory interface CE1 (4 Mbytes)  
external memory interface CE2 (16 Mbytes)  
external memory interface CE3 (16 Mbytes)  
External memory (CE0, CE1, CE2 and CE3) consists of node local memory resources  
which are accessed on the DSP Local Bus, but are external to the DSP processor. The  
type of memory in each of the four CE regions is determined by settings in the internal  
peripheral registers. All remaining memory in the 4 GB address space is reserved.  
The internal peripheral registers for Monaco must be initialized to the values in the  
following table upon reset for the board to operate.  
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Processor Nodes  
Table 4 'C6x Internal Peripheral Register Values  
Register Address  
Value  
Comments  
Global Control Register  
0x0180 0000  
0x0000 3078  
NOHOLD (External HOLD disable) off  
SDCEN (SDRAM clock enable) on  
SSCEN (SBSRAM clock enable) on  
CLK1EN (CLKOUT1 enable) on  
CLK2EN (CLKOUT2 enable) on  
SSCRT (SBSRAM clock rate select) 1/2x CPU clock  
RBTR8 off (requester controls EMIF until a high priority request  
occurs..  
EMIF CE0 Control Register  
0x0180 0008  
0xFFFF 3F43 MTYPE = 32 bit wide SBSRAM  
No other bits are used.  
EMIF CE1 Control Register  
0x0180 0004  
0x30E4 0421 MTYPE = 32 bit wide asynchronous interface  
write setup = 3 cycles  
write strobe = 3 cycles  
write hold = 2 cycles  
read setup = 4 cycles  
read strobe = 4 cycles  
read hold = 1 cycle  
all cycles are clockout1 cycles  
0xFFFF 3F33 MTYPE = 32 bit wide SDRAM  
No other bits are used.  
EMIF CE2 Control Register  
0x0180 0010  
EMIF CE3 Control Register  
0x72B7 0A23 MTYPE = 32 bit wide asynchronous interface  
address = 0x01800004  
(Used for PEM. Must be  
reconfigured for individual  
PEM)  
value = 0x30E40421  
MTYPE = 32 bit wide asynchronous interface  
write setup = 7 cycles  
0x0180 0014  
write strobe = 10 cycles  
write hold = 3 cycles  
read setup = 7 cycles  
read strobe = 10 cycles  
read hold = 3 cycle  
all cycles are clockout1 cycles  
EMIF SDRAM Control  
0x0180 0018  
0x0544 A000 RFEN = 0 internal refresh enable OFF. Only external SDRAM  
refresh can be used.  
SDWID = 1 (SDRAM width select) two 16 bit SDRAMs  
Other timing parameters are SDRAM specific and should not be  
modified by the user.  
EMIF SDRAM Timing  
0x0180 001C  
0x0000 061A Refresh timer implemented in external hardware. This register is  
not used.  
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‘C6x Addr  
Memory Contents  
Memory Size  
0000 0000  
0000 1000  
Internal-Program RAM  
64 KB  
Reserved  
4 MB - 64KB  
512 KB  
0040 0000  
0048 0000  
Local SBSRAM  
Reserved CE0  
16 M - 512 KB  
0140 0000  
External-Memory Space CE1  
External-Memory Space CE1  
Upon Reset  
After TOUT0 is toggled  
PEM EEPROM  
Boot Mode  
DSP~LINK3  
4 MB  
Shared SRAM  
SCV64 Registers  
(see the following CE1  
memory map)  
0180 0000  
01A0 0000  
Internal-Peripheral Space  
2 MB  
6 MB  
Reserved  
0200 0000  
0300 0000  
0400 0000  
Local SDRAM CE2  
16 MB  
16 MB  
Processor Expansion Module (PEM) CE3  
Reserved  
Internal-Data RAM  
Reserved  
2 GB - 64 MB  
64 KB  
8000 0000  
8001 0000  
2GB -  
(2GB - 64 KB)  
FFFF FFFF  
Figure 4 DSP Memory Map  
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Processor Nodes  
External Memory Space CE1 is dedicated to accessing registers, global shared RAM and  
DSP~LINK3 (Node A only). Node A differs from nodes B, C and D since it is the only  
node with access to the DSP~LINK3. The following figure shows the memory map for  
this region.  
Address  
Node A  
Nodes B, C, and D  
0140 0000  
Global Shared SRAM  
512K x 32  
Global Shared SRAM  
512K x 32  
015F FFFC  
0160 0000  
DSP~LINK3 Standard Access  
DSP~LINK3 Standard Fast Access  
DSP~LINK3 RDY Controlled Access  
Hurricane Registers  
0163 FFFC  
0164 0000  
Reserved  
0167 FFFC  
0168 0000  
016B FFFC  
016C 0000  
Hurricane Registers  
016C 1FFC  
016D 0000  
Node A VPAGE Register  
Shared Bus Registers  
SCV64 Register Set (R/W)  
Reserved  
Node B, C, or D VPAGE Register  
Shared Bus Registers  
016D 7FFC  
016D 8000  
016D FFFC  
016E 0000  
SCV64 Register Set (R/W)  
Reserved  
016E 7FFC  
016E 8000  
016E FFFC  
016F 0000  
IACK Cycle Space (Read Only)  
IACK Cycle Space (Read Only)  
016F FFFC  
0170 0000  
One Mbyte window to the  
VME Address Space  
One Mbyte window to the  
VME Address Space  
VME base address set by VPAGE register  
DSP as VME Master (R/W)  
VME base address set by VPAGE register  
DSP as VME Master (R/W)  
017F FFFC  
Figure 5 DSP Memory Map for External-Memory Space CE1  
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2.2. Synchronous Burst SRAM  
The board provides 128K of 32-bit synchronous burst SRAM (SBSRAM) on each ‘C6x  
local bus. The Monaco board supports 1 wait state operation.  
2.3. Synchronous DRAM  
The board provides 4M of 32-bit synchronous DRAM on each ‘C6x bus. The Monaco  
board supports 1 wait state operation. An additional 4M of 32-bit synchronous DRAM  
per DSP can also be supported on a PEM module.  
Burst data transfer rates from CPU to SDRAM are 400 Mbytes/s on a Monaco with  
200 MHz TMS320C6201 chips.  
2.4. Processor Expansion Module  
The Processor Expansion Module (PEM) provides a simple and flexible interface from  
the DSP to I/O. It is similar to a PMC module, although physically narrower.  
The Monaco board is designed to support two DSPs per PEM site, with a pair of  
connectors for each DSP. While both DSP devices share the same PEM, the two DSP  
buses are kept separate to allow very fast PEM data transfer rates.  
The PEM is capable of booting the DSPs from local ROM, with up to 4 MBytes of  
addressable boot space available to each DSP.  
Refer to the PEM Specification for mechanical and functional details of the PEM  
interface.  
2.5. Host Port  
A separate A24 VMEbus Slave interface is used for direct access to the DSP’s Host Port  
Interface. This interface can be used for downloading code and as a control path from the  
host to the DSP. Data transfer rates depend upon both the code executing in the DSP and  
the VMEbus Master performing the transfers, but can be as high as 30 Mbytes/second.  
Jumper block JP1 selects the VME A24 base address for this slave interface.  
2.6. Interrupt Lines  
There are four external interrupt inputs on each ‘C6x. They are INT4, INT5, INT6, and  
INT7. All four must be configured as rising-edge triggered interrupts upon initialization.  
See the Interrupt Handling chapter for further information.  
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2.7. Processor Booting  
The ‘C6x can boot from either the VME bus (via its Host Port Interface (HPI) port) or  
from an 8-bit EEPROM on an installed PEM module. The jumpers listed in the following  
table select the booting method for each node.  
Table 5 Processor Boot Source Jumpers  
Jumper  
Node  
PEM Boot  
HPI Boot  
JP2  
JP3  
JP4  
JP5  
Node A  
Node B  
Node C  
Node D  
IN  
IN  
IN  
IN  
OUT  
OUT  
OUT  
OUT  
The Monaco board uses the CE1 memory space of the ‘C6x memory map 1 for the boot  
space upon power up or reset. Immediately after booting, the ‘C6x cannot access the  
resources in its CE1 space such as the Hurricane registers, Global Shared SRAM, and  
SCV64 Registers. In order to access these CE1 resources, the ‘C6x must toggle the state  
of its Timer 0 pin (TOUT0). The state of this pin is controlled by the DataOut bit of the  
‘C6x Timer 0 Control Register. Once TOUT has been toggled, the CE1 resources are  
available to the ‘C6x until the ‘C6x is reset.  
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2.8. Serial Port Routing  
Each ‘C6x has two serial ports. Serial Port 0 of each DSP is routed to the PEM connector  
associated with the DSP node.  
Routing for Serial Port 1 on nodes A, B, C and D is determined by jumpers J7 to J10 as  
shown in the figure and following tables. The jumper setting selects routing either to the  
PMC JN5 and VME P2 connectors, or to the PEM connector associated with the DSP  
node.  
Serial Port routing for the Monaco board is shown the figure. Complete pinouts for the  
connectors are given in the Connector Pinouts chapter.  
Serial  
Port 0  
Node D  
‘C6x  
Port 1  
Node  
D
PEM  
1
Node  
D
PEM  
2
JP10  
IN  
OUT  
Serial  
Serial  
Port 0  
VME  
P1  
Node C  
‘C6x  
Node  
C
PEM  
1
Node  
C
PEM  
2
JP9  
IN  
OUT  
Serial  
Port 1  
Serial  
Port 0  
Node  
B
PEM  
1
Node  
B
PEM  
2
Node B  
‘C6x  
JP8  
IN  
OUT  
Serial  
Port 1  
Serial  
Port 0  
Node  
A
PEM  
1
Node  
A
PEM  
2
Node A  
‘C6x  
JP7  
IN  
OUT  
Serial  
Port 1  
PMC  
Connector  
JN5  
Node D Serial Port 0  
Node C Serial Port 0  
Node D  
VME  
P2  
Node C  
Node B  
Node A  
Node B Serial Port 0  
Node A Serial Port 0  
Figure 6 Serial Port Routing  
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Pin assignments for the serial ports are given in the following tables.  
Table 6 PEM Connections for Serial Port 0 and 1  
Signal  
CLKS  
CLKR  
CLKX  
DR  
PEM 1 Port 0  
PEM 2 Port 1*  
External clock  
56  
52  
42  
48  
46  
50  
44  
17  
13  
3
Receive clock  
Transmit clock  
Received serial data  
Transmitted serial data  
Receive frame synchronization  
Transmit frame synchronization  
9
DX  
7
FSR  
11  
5
FSX  
*The serial port routing jumper corresponding to the node (J7, J8, J9, or J10) must be  
OUT for port 1 to be routed to the node’s PEM 2 connector.  
Table 7 VME and PMC Connections for Serial Port 1  
Node A (J7 IN)  
Node B (J8 IN)  
Node C (J9 IN)  
Node D (J10 IN)  
Signal  
PMC JN5 VME-P2 PMC JN5 VME-P2 PMC JN5 VME-P2 PMC JN5 VME-P2  
CLKS External clock  
CLKR Receive clock  
CLKX Transmit clock  
1
5
D-4  
D-6  
21  
25  
29  
31  
33  
35  
37  
D-18  
D-20  
D-22  
D-24  
D-26  
D-28  
D-30  
2
Z-3  
Z-5  
22  
26  
30  
32  
34  
36  
38  
Z-17  
Z-19  
Z-21  
Z-23  
Z-25  
Z-27  
Z-29  
6
9
D-8  
10  
12  
14  
16  
18  
Z-7  
DR  
DX  
Received serial data  
11  
13  
15  
17  
D-10  
D-12  
D-14  
D-16  
Z-9  
Transmitted serial data  
Z-11  
Z-13  
Z-15  
FSR  
FSX  
Receive frame synchronization  
Transmit frame synchronization  
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Global Shared Bus  
3 Global Shared Bus  
The Global Shared Bus provides access between devices on the Monaco board as shown  
in the following table.  
Table 8 Global Shared Bus Access  
Source  
Target  
‘C6x  
Nodes  
PMC  
Site  
VME Bus  
via SCV64  
Internal program & data RAM  
Local SDRAM  
R/W own node  
R/W own node  
R/W own node  
R/W (32-bit only)  
R/W  
No Access  
No Access  
No Access  
R/W  
No Access  
No Access  
No Access  
R/W  
Local SBSRAM  
Global Shared RAM  
Hurricane Registers  
PMC Site  
R/W  
R/W  
Hurricane DMA  
access only  
-
No Access  
SCV64 Registers  
R/W  
R/W  
R/W  
No Access  
No Access  
No Access  
No Access  
No Access  
-
Global Shared Bus Registers  
VMEbus as master  
3.1. Memory  
512K of 32-bit Asynchronous RAM, implemented in four 512K x 8-bit Asynchronous  
RAM devices, is provided on the Global Shared Bus. The ‘C6x DSPs can only perform  
32-bit accesses to the Global Shared RAM. Byte accesses are not supported.  
3.2. Arbitration  
Arbitration of the Global Shared Bus is implemented using a next bus owner token that is  
passed serially from one device to the next. Token passing follows a strict hierarchical  
sequence, ordered by bus servicing priority. There are six devices participating in the  
process. These are, in decreasing priority:  
SCV64  
Hurricane  
DSP Node A  
DSP Node B  
DSP Node C  
DSP Node D  
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Global Shared Bus  
Bus ownership is cycled between the two highest priority devices (SCV64 and  
Hurricane) until neither device requires the bus. Then the DSP Nodes are processed  
round robin. After one pass through the DSP chain, the cycle loops back to include the  
SCV64 and Hurricane. This eliminates any arbitration latency as bus ownership is  
transferred between devices, and grants the highest priority to those devices interfacing  
to external buses (VME and PCI), which require the fastest response. The arbitration  
cycle is shown in the following figure.  
Because there is no ownership timer for either Hurricane or SCV64 chip  
Note:  
the system designer must ensure that processors are not held off from the shared  
resources for unreasonable lengths of time.  
Highest Priority  
Lowest priority  
Node D  
SCV64  
Hurricane  
Node A  
Node B  
Node C  
Round Robin  
VME & PCI Bus  
DSP  
Round Robin  
Figure 7 Global Bus Arbitration  
Access to the Global Shared Bus can use single, burst, or locked cycles.  
3.2.1. Single Cycle Bus Access  
For single cycle accesses a device requests the global shared bus by simply initiating a  
read or write access to the bus. When the bus is free, the device acquires it and performs  
the single cycle access. The bus is then released.  
3.2.2. Burst Cycle Bus Access  
Burst cycles are used during DMA transfers from a ‘C6x processor to the Global Shared  
Bus. A 6-bit bus ownership timer on each node prevents a ‘C6x from owning the bus for  
more than 640 ns when another device is requesting the bus. When the burst cycles are  
begun, the timer is started. If another device requests the bus when the timer expires, the  
bus is released; otherwise ownership is maintained and the timer is reset and started  
again.  
If multiple DSPs request the bus, this scheme allocates time to them fairly so that none  
are locked out.  
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Global Shared Bus  
Although this is a non-prioritized scheme, the back-off function of the SCV64 interface  
resolves collisions between a bus master and the VMEbus if there is contention for the  
VMEbus.  
There are no ownership timers for the Hurricane or SCV64. If the  
Note:  
Hurricane holds the bus too long the VME bus could timeout.  
3.2.3. Locked Cycles  
A ‘C6x can lock the Global Shared Bus in order to perform Read-Modify-Write (RMW)  
or other atomic accesses to it, by driving its Timer 0 (TOUT0) low. After the TOUT0 is  
driven low, the next access to the Global Shared Bus acquires the bus. The bus is not  
released until the ‘C6x drives the Timer 0 (TOUT0) pin high.  
The capability of locking the Global Shared Bus from a ‘C6x should  
Caution:  
be used carefully because other devices will not acquire the bus once it is locked.  
This capability is intended for read-modify-write accesses to the Global Shared  
RAM and registers. It is highly recommended that Bus locking not be used. It  
can lead to a deadlock condition, and in particular, result in debugger timeouts.  
The following precautions should be observed when locking the Global Shared Bus:  
1. VME bus timeouts can occur because the SCV64 cannot access the board while a  
‘C6x has locked the bus.  
2. If node A accesses the DSP~LINK3 interface while it has locked the Global Shared  
Bus by asserting TOUT0, the bus will be released. Node A’s next access to the bus  
will re-lock it to node A, providing that TOUT0 is still asserted.  
3. Some SCV64 inbound cycles can occur while the bus is locked. If a ‘C6x has locked  
the bus and is performing a VME outbound cycle while a VME inbound cycle is in  
progress, the ‘C6x will be temporarily backed off and the SCV64 cycle will proceed.  
The Global Shared Bus will be returned to that ‘C6x node after the SCV64 cycle  
finishes. No other ‘C6x will get ownership of the bus.  
4. If a debugger is being used when one processor has the bus locked for an extended  
time while another processor is trying to get the bus, the debugger may timeout.  
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VME64 Bus Interface  
4 VME64 Bus Interface  
There are two separate VMEbus slave interfaces on the Monaco board. One is  
implemented by the SCV64 and provides A32 and A24 VMEbus masters access to the  
global shared bus. The second slave interface provides direct access to the Test Bus  
Controller for debugging, and to the Host Port Interfaces (HPIs) of each ‘C6x. The HPI  
provides support for code download, control, and data transfers from the VME64 bus.  
4.1. VME Operation  
The Monaco board requires a VME chassis (6U) with power supply. The board  
automatically becomes VMEbus system controller (Syscon) if it resides at the top of the  
VMEbus grant daisy chain. This capability is provided by the Tundra SCV64 interface  
chip. Refer to the SCV64 User Manual for details.  
The Monaco board has two VME backplane connectors: a 3 row P1 connector and a 5  
row P2 connector.  
The board may be installed in either a 5 row VME backplane or a 3 row backplane. The  
two additional rows on the VME P2 connector (Z and D) only serve to route serial port  
signals from DSP processor nodes A, B, C and D to the VME backplane, if the board is  
configured for that option.  
If the Monaco board is installed in a 3 row VME chassis, serial port  
Note:  
routing will be restricted to the PEM and PMC sites only.  
4.2. SCV64 Primary Slave A32/A24 Interface  
The primary interface to the VME64 bus is based on Tundra Semiconductor  
Corporation’s SCV64 VME64 Interface chip. This chip enables the Monaco board to act  
as a master or a slave on the VME64 bus, and also provides VME interrupt capabilities.  
Transfer rates of 40 MBytes/sec are supported between the SCV64 and the Global  
Shared Bus SRAM once the bus has been acquired. The SCV64 cannot be pre-empted  
from the Global Shared Bus and it does not have a bus ownership timer.  
A host on the VME64 bus can access both the lower half (1 Mbyte) of Global SRAM  
and the Hurricane control registers on a Monaco board in either A24 or A32 addressing  
modes as shown in the following memory map.  
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VME Offset Address  
Access  
0000 0000h  
Host  
VME  
Global Shared SRAM  
(lower 1Mbyte)  
DSP  
000F FFFFh  
0010 0000h  
accessible  
and  
Hurricane  
accessible  
Global Shared SRAM  
(Upper 1 Mbyte)  
001F FFFFh  
0020 0000h  
Hurricane Control Registers  
Reserved  
002F FFFFh  
0030 0000h  
003F FFFFh  
Figure 8 Primary VME A24/A32 Memory Map  
The full A24 memory map occupies one-quarter of the available A24  
Note:  
space. This can be reduced to the standard 512K (16M ÷ 32) of the available  
A24 space by mapping only the lower 512 Kbytes (128k x 32) of the global  
shared SRAM. This is entirely programmable in the SCV64 base address  
registers. Only SCV64 A21 and A20 are used for decode on SCV64 VME slave  
accesses to the board. D16 and D08E0 writes are not supported on the primary  
A32/A24 interface.  
4.3. A24 Secondary Slave Interface  
Jumper block JP1 sets address bits A23..A17 of the VME A24 slave interface. This base  
address defines a 128K byte addressed memory space accessed by the VME bus. Access  
to this space from the VME bus bypasses the SCV64 VME bus interface chip.  
All A24 VME transfer types are accepted except for LOCK, and MBLT types.  
As shown in the following memory map, the A24 slave interface provides the VME bus  
direct access to:  
The Host Port Interface (HPI) registers of each ‘C6x processor  
The Test Bus Controller (TBC) for JTAG debugging operation  
Control and Status registers of the Monaco board  
D16 and D08E0 accesses are not supported on the slave A24 secondary interface.  
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VME64 Bus Interface  
VME Offset Address  
00 0000h  
Test Bus Controller Registers (JTAG)  
VME A24 Status Register (Read Only)  
VME A24 Control Register (Read/Write)  
Reserved  
00 0FFFh  
00 1000h  
FPGA  
00 1003h  
00 1004h  
00 1007h  
00 1008h  
00 1FFFh  
00 2000h  
Node A HPI Registers  
00 2FFFh  
00 3000h  
Node B HPI Registers  
00 3FFFh  
00 4000h  
‘C6x  
Node C HPI Registers  
00 4FFFh  
00 5000h  
Node D HPI Registers  
00 5FFFh  
00 6000h  
Reserved  
00 FFFFh  
01 0000h  
Node A HPID DMA Space (HPIA incremented)  
all addresses mapped to 00 2008h  
16 KB  
01 3FFCh  
01 4000h  
Node B HPID DMA Space (HPIA incremented)  
all addresses mapped to 00 3008h  
16 KB  
01 3FFCh  
01 B000h  
‘C6x  
Node C HPID DMA Space (HPIA incremented)  
all addresses mapped to 00 4008h  
16 KB  
16 KB  
01 3FFCh  
01 C000h  
Node D HPID DMA Space (HPIA incremented)  
all addresses mapped to 00 5008h  
01 FFFCh  
Figure 9 A24 Secondary Interface Memory Map  
Refer to the JTAG Debugging chapter for information on using the Test Bus Controller  
for JTAG operation. The VME A24 Status Register and the  
VME A24 Control Register are described in the Registers chapter.  
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VME64 Bus Interface  
The Host Port Interface (HPI) allows a VME host to access the memory map of any  
‘C6X. The board transfers 32-bit VME accesses automatically through the 16-bit Host  
Port Interface as two 16-bit words. The interface consists of three read/write, 32-bit  
registers that are accessed through the VME A24 slave interface:  
HPI Address register (HPIA)  
HPI Control register (HPIC). A ‘C6x can also read and write to its HPI Control  
register (HPIC) at address 0188 0000h.  
HPI Data register (HPID)  
VME address bits A[3:2] select which register is being accessed in each node’s HPI  
register address space. These bits are mapped to the HCNTRL[1:0] control pins of the  
‘C6x. The following table shows how the HPI interface is addressed.  
Table 9 HPI Register Addresses  
VME address  
‘C6x  
Register  
Node  
A
Node  
B
Node  
C
Node  
D
Description  
HPIC 00 2000h 00 3000h 00 4000h 00 5000h State for reading/setting the Control Register value.  
HPIA 00 2004h 00 3004h 00 4004h 00 5004h Used to read/set the HPI address pointer. The HPIA  
points into the C6x memory space.  
HPID 00 2008h 00 3008h 00 4008h 00 5008h A VME host reads and writes data to this address for  
DMA transfers to the HPID register. The HPIA register  
automatically increments by 4 bytes as each word is  
transferred through the HPID register.  
HPID 00 200Ch 00 300Ch 00 400Ch 00 500Ch A VME host reads and writes data to this address for  
single cycle transfers to the HPID register. The HPIA is  
not incremented for this HPI access mode.  
HPID 01 0000h 01 4000h 01 8000h 01 C0000h VME hosts which increment their target address can use  
DMA  
Space  
this address space for DMA transfers to the HPID  
register. Up to 4K of 32-bit data can be transferred in this  
space. Data written to this space is automatically  
transferred to the HPID register, and the HPIA register  
automatically increments by 4 bytes as each word is  
transferred.  
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VME64 Bus Interface  
Before a host can transfer data through a node’s HPI, the VME host must set the HWOB  
bit of the node’s HPIC register to “1”. This only has to be done once after the Monaco  
board is reset. To access an address within a ‘C6x’s memory space, the VME host loads  
the address into the HPIA register. Data is then transferred through the HPID register.  
The HPID at offset “8h” auto-increments four bytes after every cycle, allowing it to  
be used for burst DMA data transfers.  
The HPID at offset “Ch” does not auto-increment, and is therefore intended for  
single cycle accesses only.  
The HPID DMA Space offers a 16K address space to VME hosts which increment  
their target address during DMA transfers. This allows them to transfer data in  
blocks of 16K 32-bit words to the HPID register used for DMA transfers.  
4.4. Master A32/A24/A16 SCV64 Interface  
As a VME master, the Monaco board supports A16, A24, or A32 transactions from any  
node to the VME64 bus through the SCV64 chip. Any node can program the SCV64’s  
DMA Controller for VME Master Accesses, and can directly master the VMEbus. Each  
node has its own VPAGE Register to support the KFC, KSIZE, and upper 12 and  
lower 2 address bits to the SCV64. The upper 11 bits extend the 20-bit address space of  
the ‘C6x to the full 32-bit address space of the VME bus. Any node can monitor the  
status of the /KIPL interrupt lines, BUSERRORs for each node, and KAVEC line by  
reading the VSTATUS Register.  
The Monaco board supports Auto-Syscon capabilities allowing it to become the System  
Controller board when placed in the leftmost slot of the VME backplane. If it is to be the  
System Controller it should typically be booted from a PEM module equipped with a  
boot PROM.  
Upon reset, the SCV64 is in Bus-Isolation Mode (BI-Mode) which isolates the SCV64  
from the VME64 bus. The SCV64 is released from BI-Mode by a write to the SCV64  
Location Monitor from any node of the Monaco board.  
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DSP~LINK3 Interface  
5 DSP~LINK3 Interface  
The Monaco board provides a DSP~LINK3 interface through a ribbon cable connector.  
The interface supports up to 4 slave DSP~LINK3 devices. The ribbon cable can be up to  
12 inches (30 cm) long.  
The DSP~LINK3 interface is accessed from node A’s local bus only; it is not accessible  
from any other node nor from the VME bus. Accesses to the DSP~LINK3 interface do  
not require the Global Shared Bus. As a result, DSP~LINK3 accesses can happen  
concurrently with Global Shared Bus access by other devices (such as the other  
processors or the SCV64 chip).  
If a DSP~LINK3 access is interleaved within global shared SRAM accesses, node A  
acquires the Global Shared Bus, performs the SRAM access, releases the Global Shared  
Bus, performs the DSP~LINK3 access, acquires the Global Shared Bus, and then  
performs the next Global Shared Bus SRAM access using a control register.  
5.1. DSP~LINK3 Data Transfer Operating Modes  
The Monaco board supports four data transfer operating modes.  
Standard Access  
Standard Fast Access  
Address Strobe Control  
Ready Control Access  
The three “access” data transfer operating modes (Standard, Standard Fast and Ready  
Control) of the DSP~LINK3 interface use three 64K address spaces accessed from node  
A. Each of the three “access” modes is assigned its own 64K memory space. Address  
Strobe Control cycles are multiplexed with the Standard Fast Access mode space.  
The following table shows how the DSP~LINK3 data transfer operating modes are  
supported.  
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Table 10 DSP~LINK3 Data Transfer Operating Modes  
Base  
Address  
ASTRB_EN  
Bit  
Mode  
Description  
0160 0000h  
x
For slave boards that are similar to DSP~LINK1  
slave boards and operate with a fixed access  
time.  
Standard  
Access  
0164 0000h  
0
For DSP~LINK3 slave boards that have fast,  
fixed access time. This memory space is  
shared with the Address Strobe Control  
operating mode.  
Standard  
Fast  
Access  
0164 0000h  
1
For slave boards that require more than the  
16 KWords of addressing provided by the  
standard DSP~LINK3 address lines. The bus  
master uses the /ASTRB cycle to place the  
page address onto the DSP~LINK3 data lines.  
It determines which address page is accessed  
on the slave board. This allows access to up to  
214 address pages with each address page  
having an address depth of 214. The /ASTRB  
Cycle has the same timing as the Standard  
Fast transfer cycle.  
Address  
Strobe  
Control  
0168 0000h  
x
For DSP~LINK3 slave boards that require  
variable length access times. /DSTRB is active  
until the slave asserts the DSP~LINK3 ready  
signal (/RDY) to end the cycle.  
Ready  
Control  
Access  
5.2. Address Strobe Control Mode  
The Address Strobe Control mode uses the same node A 64K address space as the  
Standard Fast Access mode. The Address Strobe Control mode is enabled for this space  
by setting bit D1, the ASTRB_EN bit, of the DSP~LINK3 register to “1”. This register is  
located at address 016D 8018h of node A. Standard Fast Access mode writes will now  
generate /ASTRB cycles. The DSP~LINK3 slave attached to the Monaco board should  
then latch the lower addresses.  
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5.3. Interface Signals  
The DSP~LINK3 interface consists of two 16-bit bi-directional buffers for data, a 16-bit  
address latch, and a control signal buffer. The control signals are terminated via a SCSI  
terminator. The DSP~LINK3 interface signals are:  
32 data I/O lines: D[31..0]  
16 address outputs: A[15..0] A15 and A14 are used for slave device (board)  
selection.  
/DSTRB, /ASTRB, R/W and /RST outputs  
Tri-state ready (/RDY) input  
4 open-collector interrupt inputs (IRQ0 to IRQ3). These interrupt are logically  
OR’ed and routed to the INT7 line of node A’s ‘C6x.  
Refer to DSP~LINK3 specification for details (available from Spectrum’s internet web  
site at http://www.spectrumsignal.com)  
5.4. DSP~LINK3 Reset  
Bit D0 of the DSP~LINK3 register controls the DSP~LINK3 reset line. This register is  
located at address 016D 8018h of node A. Setting bit D0 to “1” asserts the DSP~LINK3  
reset line; setting it to “0” releases the reset. DSP~LINK3 resets must be at least 1 µs  
long. This reset is entirely under software control.  
The DSP~LINK3 reset line will also be asserted during /SYSRESET or secondary  
control register board reset conditions.  
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PCI Interface  
6 PCI Interface  
The Hurricane chip provides the interface between the Global Shared SRAM on the  
Global Shared Bus and the PMC site which supports a 32 bit, 33 MHz PCI bus. Although  
the DSPs cannot directly master the PCI bus, the Hurricane’s DMA controller provides  
flexible data transfer between the Global Shared Bus SRAM and the PMC.  
Embedded PCI buses require Hurricane PCI configuration cycle generation.  
Pre-emptive arbitration is not used. If a node requests the Global Shared bus when the  
bus is not currently in use, then it will be granted the bus. It is up to the bus ownership  
timers of the Hurricane and PMC devices to prevent bus hogging.  
PMC modules can directly master the Global Shared SRAM.  
The memory map of the Monaco seen by a PMC module is shown in the following  
figure.  
PCI Offset Address  
Access  
0000 0000h  
Global Shared SRAM  
001F FFFFh  
0020 0000h  
Hurricane Control Registers  
Reserved  
002F FFFFh  
0030 0000h  
003F FFFFh  
Figure 10 PCI Memory Map  
6.1. Hurricane Configuration  
Before the PMC site can be accessed, the Monaco initialization software must configure  
the Hurricane registers with the values shown in the following table. Only the indicated  
values should be initialized, all other values should be left alone. As can be seen, these  
registers can be accessed from a ‘C6x, the PMC’s PCI bus, and a host on the VME bus.  
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PCI Interface  
Table 11 Hurricane Register Set  
Hurricane  
DSP Offset  
'C6x  
Address  
PCI Bus  
Offset  
Slave A32/A24 Register  
SCV64 Offset  
Description  
Value  
Initialize  
0x00  
0x01  
0x02  
0x03  
0x04  
0x05  
0x06  
0x07  
0x08  
0x09  
0x0A  
0x0B  
0x0C  
0x0D  
0x0E  
0x0F  
0x10  
0x11  
0x12  
0x13  
0x14  
0x15  
0x16  
0x17  
0x18  
0x19  
0x1A  
0x1B  
0x1C  
0x1D  
0x1E  
0x1F  
0x20  
0x21  
0x22  
0x23  
0x24  
0x25  
0x26  
0x27  
0x016C 0000 0x0020 0000  
0x016C 0004 0x0020 0004  
0x016C 0008 0x0020 0008  
0x0020 0000 DCSR  
0x0020 0004 IFSC  
0x0020 0008 IED  
DMA Control / Status Register  
Interrupt Flag, Set, Clr  
Interrupt Enable to DSP  
Interrupt Enable to PCI  
Interrupt type  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0006  
0x1F00 0011  
0x0000 0001  
0x0000 0000  
0x0000 302C  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0010  
0x0000 0100  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 00F6  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0020 0020  
0x0000 0620  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0010 0021  
0x0000 0140  
0xB401 6820  
0x2800 2800  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
Y
Y
0x016C 000C 0x0020 000C 0x0020 000C IEP  
0x016C 0010 0x0020 0010  
0x016C 0014 0x0020 0014  
0x016C 0018 0x0020 0018  
0x0020 0010 IT  
Y
0x0020 0014 GCSR  
0x0020 0018 TTP  
General control and status register  
Timer trigger point  
Timer value  
0x016C 001C 0x0020 001C 0x0020 001C TV  
0x016C 0020 0x0020 0020  
0x016C 0024 0x0020 0024  
0x016C 0028 0x0020 0028  
0x0020 0020 SCR  
0x0020 0024 SEA  
0x0020 0028 SED  
Serial EEPROM control  
Serial EEPROM address  
Serial EEPROM data  
Pin Function Register  
reserved  
0x016C 002C 0x0020 002C 0x0020 002C PFR  
0x016C 0030 0x0020 0030  
0x016C 0034 0x0020 0034  
0x016C 0038 0x0020 0038  
0x0020 0030  
0x0020 0034  
reserved  
0x0020 0038 REV  
Chip Rev Code  
0x016C 003C 0x0020 003C 0x0020 003C RAC  
Register access control  
DSP Address  
0x016C 0040 0x0020 0040  
0x016C 0044 0x0020 0044  
0x016C 0048 0x0020 0048  
0x0020 0040 DDA  
0x0020 0044 DPA  
PCI Address  
0x0020 0048 DLNGTH Length  
0x016C 004C 0x0020 004C 0x0020 004C DINTP  
Interrupt Point  
Y
Y
0x016C 0050 0x0020 0050  
0x016C 0054 0x0020 0054  
0x016C 0058 0x0020 0058  
0x0020 0050 DSTRD  
0x0020 0054 DPC  
0x0020 0058 DCAR  
DSP Stride  
Packet Control  
DMA Chain Address Register  
reserved  
0x016C 005C 0x0020 005C 0x0020 005C  
0x016C 0060 0x0020 0060  
0x016C 0064 0x0020 0064  
0x016C 0068 0x0020 0068  
0x0020 0060 DCDA  
0x0020 0064 DCPA  
Current DSP Address  
Current PCI Address  
0x0020 0068 DCLNTGH Current Length  
0x016C 006C 0x0020 006C 0x0020 006C DBC  
PCI DMA burst control  
0x016C 0070 0x0020 0070  
0x016C 0074 0x0020 0074  
0x016C 0078 0x0020 0078  
0x0020 0070 DFC  
0x0020 0074 DBE  
0x0020 0078  
DMA FIFO Control  
PCI byte enable and command register  
0x016C 007C 0x0020 007C 0x0020 007C  
0x016C 0080 0x0020 0080  
0x016C 0084 0x0020 0084  
0x016C 0088 0x0020 0088  
0x0020 0080 BCC0A  
DSP Cycle control 0A  
DSP Cycle control 0B  
DSP Cycle control 0C  
DSP Cycle control 0D  
DSP Cycle control 1A  
DSP Cycle control 1B  
DSP Cycle control 1C  
DSP Cycle control 1D  
Y
Y
Y
Y
0x0020 0084 BCC0B  
0x0020 0088 BCC0C  
0x016C 008C 0x0020 008C 0x0020 008C BCC0D  
0x016C 0090 0x0020 0090  
0x016C 0094 0x0020 0094  
0x016C 0098 0x0020 0098  
0x0020 0090 BCC1A  
0x0020 0094 BCC1B  
0x0020 0098 BCC1C  
0x016C 009C 0x0020 009C 0x0020 009C BCC1D  
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PCI Interface  
Hurricane  
DSP Offset  
'C6x  
Address  
PCI Bus  
Offset  
Slave A32/A24 Register  
SCV64 Offset  
Description  
Value  
Initialize  
0x28  
0x29  
0x2A  
0x2B  
0x2C  
0x2D  
0x2E  
0x2F  
0x30  
0x31  
0x32  
0x33  
0x34  
0x35  
0x36  
0x37  
0x38  
0x39  
0x3A  
0x016C 00A0 0x0020 00A0 0x0020 00A0 BCC2A  
0x016C 00A4 0x0020 00A4 0x0020 00A4 BCC2B  
0x016C 00A8 0x0020 00A8 0x0020 00A8 BCC2C  
0x016C 00AC 0x0020 00AC 0x0020 00AC BCC2D  
0x016C 00B0 0x0020 00B0 0x0020 00B0 BCC3A  
0x016C 00B4 0x0020 00B4 0x0020 00B4 BCC3B  
0x016C 00B8 0x0020 00B8 0x0020 00B8 BCC3C  
0x016C 00BC 0x0020 00BC 0x0020 00BC BCC3D  
0x016C 00C0 0x0020 00C0 0x0020 00C0 BMI0  
0x016C 00C4 0x0020 00C4 0x0020 00C4 BMI1  
0x016C 00C8 0x0020 00C8 0x0020 00C8 BMI2  
0x016C 00CC 0x0020 00CC 0x0020 00CC BMI3  
0x016C 00D0 0x0020 00D0 0x0020 00D0 BMI4  
0x016C 00D4 0x0020 00D4 0x0020 00D4 BMI5  
0x016C 00D8 0x0020 00D8 0x0020 00D8 BMI6  
0x016C 00DC 0x0020 00DC 0x0020 00DC BMI7  
0x016C 00E0 0x0020 00E0 0x0020 00E0 BMI8  
0x016C 00E4 0x0020 00E4 0x0020 00E4 CSCR  
0x016C 00E8 0x0020 00E8 0x0020 00E8 MABE  
CSER  
DSP Cycle control 2A  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x00D6 1DE0  
0x0000 0000  
0xA9E0 69A0  
0x0000 0000  
0x1000 0003  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0001 0100  
DSP Cycle control 2B  
DSP Cycle control 2C  
DSP Cycle control 2D  
DSP Cycle control 3A  
DSP Cycle control 3B  
DSP Cycle control 3C  
DSP Cycle control 3D  
Bank 0 Mapping Information  
Bank 1 Mapping Information  
Bank 2 Mapping Information  
Bank 3 Mapping Information  
Bank 4 Mapping Information  
Bank 5 Mapping Information  
Bank 6 Mapping Information  
Bank 7 Mapping Information  
Bank 8 Mapping Information  
Cycle select (all banks)  
Map Bank Enable  
Y
Y
Y
Chip Select Enable  
BER  
Mask Broadcast  
0x3B  
0x3C  
0x3D  
0x3E  
0x3F  
0x40  
0x41  
0x42  
0x43  
0x44  
0x45  
0x46  
0x47  
0x48  
0x49  
0x4A  
0x4B  
0x4C  
0x4D  
0x4E  
0x016C 00EC 0x0020 00EC 0x0020 00EC IRBAR  
Internal Register Base Address Register  
Programmable Chip Select  
DSP bus timer control register  
DSP bus interface control  
reserved  
0x0020 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0xFFFF12FB  
0x0280 0006  
0x0680 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0x0000 0000  
0xFFFF FFFF  
0x0000 0000  
0x0000 0000  
0x0000 0000  
Y
Y
0x016C 00F0 0x0020 00F0  
0x016C 00F4 0x0020 00F4  
0x016C 00F8 0x0020 00F8  
0x0020 00F0 PCS  
0x0020 00F4 DSPBT  
0x0020 00F8 DBIC  
0x016C 00FC 0x0020 00FC 0x0020 00FC  
0x016C 0100 0x0020 0100  
0x016C 0104 0x0020 0104  
0x016C 0108 0x0020 0108  
0x0020 0100  
0x0020 0104  
0x0020 0108  
0x016C 010C 0x0020 010C 0x0020 010C  
0x016C 0110 0x0020 0110  
0x016C 0114 0x0020 0114  
0x016C 0118 0x0020 0118  
0x0020 0110  
0x0020 0114  
0x0020 0118  
PCI Configuration Registers  
0x016C 011C 0x0020 011C 0x0020 011C  
0x016C 0120 0x0020 0120  
0x016C 0124 0x0020 0124  
0x016C 0128 0x0020 0128  
0x0020 0120  
0x0020 0124  
0x0020 0128  
0x016C 012C 0x0020 012C 0x0020 012C  
0x016C 0130 0x0020 0130  
0x016C 0134 0x0020 0134  
0x016C 0138 0x0020 0138  
0x0020 0130  
0x0020 0134  
0x0020 0138  
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Spectrum Signal Processing  
PCI Interface  
Hurricane  
DSP Offset  
'C6x  
Address  
PCI Bus  
Offset  
Slave A32/A24 Register  
SCV64 Offset  
Description  
Value  
Initialize  
0x4F  
0x50  
0x016C 013C 0x0020 013C 0x0020 013C  
0x016C 0140 0x0020 0140 0x0020 0140  
0x0120 0100  
0xFF00 0000  
BAR0 Shadow Register  
Y
6.2. Hurricane Implementation  
The Hurricane PCI-to-DSP Bridge Data Sheet should be read in order to understand  
how it is used with the Monaco board.  
On the DSP port of the Hurricane, only bank 0 is used to access the Global Shared Bus.  
All other Hurricane DSP banks are unused.  
There are two devices on the PMC site’s PCI bus: the Hurricane chip and the PMC  
device. The IDSEL line from each of the two PCI devices is connected to the following  
Address/Data lines:  
PCI Device  
IDSEL Connection  
Hurricane  
AD16  
AD17  
PMC Module  
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JTAG Debugging  
7 JTAG Debugging  
The Monaco board supports JTAG in-circuit emulation from a built in 74ACT8990 Test  
Bus Controller. The 74ACT8990 Test Bus Controller permits the VME interface to  
operate the JTAG chain. There are also two JTAG connectors for an XDS510 or White  
Mountain debugger, JTAG IN (J1) and JTAG OUT (J2), which can route the JTAG  
chain off-board.  
JTAG in-circuit emulation is fed to the Test Bus Controller from the VME A24  
secondary interface. C source debugging using an emulator board running a debug  
monitor on an adjacent computer is supported through the JTAG IN connector. If a  
JTAG IN connection with a clock signal is present the Test Bus Controller is  
automatically disconnected.  
JTAG data lines are routed to each available ‘C6x node. The full JTAG chain is shown  
in the following diagram. Unpopulated processor nodes are bypassed.  
TDO  
Node D  
‘C6x  
TDO  
TDI  
JTAG OUT  
TDI  
TDO  
Routed back  
to JTAG IN if  
nothing is  
Node C  
‘C6x  
connected to  
JTAG OUT  
TDI  
TDO  
Node B  
‘C6x  
TDI  
TDO  
The Test Bus Controller  
(TBC) is disabled  
TDO  
(bypassed) if an external  
debugger is connected to  
the JTAG IN connector.  
TDI  
Node A  
‘C6x  
JTAG IN or TBC  
Figure 11 JTAG Chain  
The JTAG IN input is buffered to reduce the load on an external JTAG device. The  
JTAG OUT output is buffered to guarantee enough drive to external JTAG loads. Up to  
three Monaco boards can be chained together through JTAG.  
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JTAG Debugging  
For multiple Monaco boards, the JTAG cable of the external debugger should be  
connected to the JTAG IN of the first board. The JTAG OUT of the first board should be  
connected to the JTAG IN of second board. The JTAG OUT of the second board should  
be connected to the JTAG IN of third board and so on. The JTAG OUT connector of the  
last board is not connected to anything.  
All hardware must be powered off before the JTAG cable are connected  
Note:  
and the JTAG chain is set up.  
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Interrupt Handling  
8 Interrupt Handling  
8.1. Overview  
Each ‘C6x has four interrupt pins which are configurable as either leading or falling  
edge-triggered interrupts. For the Monaco board, all ‘C6x interrupts are configured as  
rising edge-triggered interrupts. The /NMI interrupts for the ‘C6x DSPs are not used;  
they are tied high.  
The following block diagram shows how interrupts are routed to these pins on the  
Monaco board.  
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Spectrum Signal Processing  
Interrupt Handling  
KIPL D Enable  
KIPL C Enable  
KIPL B Enable  
SCV64 Interrupt  
VME Interrupt  
BUSERR_D  
VINTD  
INT 4  
INT 5  
INT 6  
INT 7  
PCI Interrupt  
Node D  
'C6x  
PEM INT1  
PEM INT2  
Hurricane  
VME Interrupt  
PCI Interrupt  
INT 4  
INT 5  
INT 6  
INT 7  
BUSERR_C  
VINTC  
Node C  
'C6x  
PEM INT1  
PEM INT2  
Hurricane  
VME Interrupt  
PCI Interrupt  
INT 4  
INT 5  
INT 6  
INT 7  
BUSERR_B  
VINTB  
Node B  
'C6x  
PEM INT1  
PEM INT2  
Hurricane  
KIPL A Enable  
VME Interrupt  
BUSERR_A  
VINTA  
INT 4  
INT 5  
INT 6  
INT 7  
PCI Interrupt  
Hurricane  
Node A  
'C6x  
Hurricane  
PEM INT1  
PEM INT2  
De-Bounce Logic  
INTA  
INTB  
INTC  
INTD  
PCI Bus  
Interrupts  
INT0  
INT1  
INT2  
INT3  
Note  
DSP~LINK3  
Interface  
Interrupts  
‘C6x interrupts  
are rising edge-  
triggered.  
De-Bounce Logic  
Figure 12 Interrupt Routing  
8.2. DSP~LINK3 Interrupts to Node A  
The four active-low interrupts from the DSP~LINK3 interface are logically OR’ed and  
routed to the INT7 interrupt input of the node A ‘C6x. The open-collector signals are de-  
bounced. The interrupts are not latched on the Monaco board and must be cleared on the  
DSP~LINK3 board that generated them.  
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8.3. PEM Interrupts  
There are two active-low, driven interrupts from the PEM connectors for each node.  
These interrupts (/PEM INT1 and /PEM INT2) are OR’ed together. Their output is  
routed to INT6 of each node’s DSP and inverted to create a rising-edge trigger.  
The Monaco board does not latch the PEM interrupts. They must be cleared on the PEM  
module that generated them.  
8.4. PCI Bus Interrupts  
The four active-low interrupt signals from the PCI bus (INTA#, INTB#, INTC#, and  
INTD#) are physically tied together and routed to INT5 of each of ‘C6x DSPs. They are  
also buffered through a de-bounce circuit because they are open-collector. On node A the  
PCI bus interrupt is also shared with the Hurricane interrupt on INT5 of the ‘C6x through  
an OR gate.  
The interrupt is not latched, and its source must be cleared on the PMC module.  
8.5. Hurricane Interrupt  
The interrupt signal from the Hurricane chip is routed to each of the board’s ‘C6x  
processors. On node A the PCI bus interrupt is also shared with the Hurricane interrupt  
on INT5 of the ‘C6x through an OR gate. For nodes B, C, and D, the Hurricane interrupt  
is routed to INT7 of the ‘C6x.  
8.6. SCV64 Interrupt  
An interrupt line from the SCV64 VME interface is routed to the INT4 interrupt input of  
all four ‘C6x processors. The interrupt provides VME, SCV64 timers and DMA, and  
other local interrupt capability. On-board logic routes VME bus error and the inter-  
processor VINTx interrupts to INT4 as well.  
This interrupt can be individually enabled or disabled for each node using the  
KIPL Enable Register (address 016D 8014h). Bits D0..D4 enable the interrupt for each  
node when set to “1”. The SCV64 interrupt is disabled from reaching the node when the  
corresponding bit is set to “0”.  
Bit  
Interrupted Node  
D0  
D1  
D2  
D3  
Node A  
Node B  
Node C  
Node D  
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The /KIPL[2..0] status bits, D[2..0], in the VSTATUS Register indicate the priority  
level of the SCV64 interrupt. These bits reflect the state of the /KIPL lines from the  
SCV64. If all three active-low bits are set to “1” (inactive), then an SCV64 interrupt did  
not cause the INT4 interrupt.  
If the interrupt was due to an SCV64 interrupt, it is serviced by performing an IACK  
cycle to the SCV64. An IACK cycle is a special type of VME read cycle to a specific  
location in the IACK cycle space (base address 016F 0000h).  
For an IACK read cycle, bits D[0..7] of the VPAGE Register must be initialized in the  
following way:  
KADDR0 (bit D0) is set to “0”  
The value of the /KIPL0 bit in the VSTATUS Register is inverted and placed in  
the KADDR1 bit (bit D1)  
KSIZE0 (bit D2) is set to “1”  
KSIZE1 (bit D3) is set to “0”  
All three KFC bits (bits D[6..4]) are set to “1”  
The /KIPL[2..1] status bits, D[2..1], in the VSTATUS Register determine the offset of  
the address to read within the IACK cycle space.  
/KIPL2 is inverted to determine IACK address bit A3  
/KIPL1 is inverted to determine IACK address bit A2  
The following table summarizes how the /KIPL[2..1] bits in the VSTATUS Register  
initialize the VPAGE Register and set the IACK cycle address.  
Table 12 KIPL Status Bits and the IACK Cycle  
/KIPL2 /KIPL1 /KIPL0  
VPAGE KADDR1 IACK Address  
1
1
1
1
0
0
0
0
1
1
0
0
1
1
0
0
1
0
1
0
1
0
1
0
Not Used  
Not Used  
1
0
1
0
1
0
1
016F 0000h  
016F 0004h  
016F 0004h  
016F 0008h  
016F 0008h  
016F 000Ch  
016F 000Ch  
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SCV64 interrupts can be generated from the VMEbus (vectored) or internally by the  
SCV64 (auto-vectored).  
If the interrupt was caused by an external VMEbus interrupt the SCV64 initiates an  
/IACK cycle on the VMEbus. The /IACK cycle is acknowledged by the interrupter  
which puts its interrupt vector on the lower 8 data bits of the DSP’s data bus.  
If the /KIPL lines were set due to an internal (auto-vectored) interrupt source the  
SCV64 initiates an /IACK cycle on the VMEbus, but no value is place on the lower  
8 data bits. The SCV64 terminates the cycle by asserting the /KAVEC signal.  
The KAVEC bit (bit D3) in the VSTATUS Register can be read to determine which  
type of interrupt was generated. After an IACK cycle is performed, it is set to “0” if the  
value on the lower 8 bits is a valid interrupt vector; or to “1” if the value is not a valid  
interrupt vector.  
Auto-vectored interrupt sources can be cleared by accessing the SCV64 register set.  
Refer to the SCV64 User Manual for more information.  
8.7. Bus Error Interrupts  
Bus error interrupts (BUSERR_x) are generated whenever an access cycle from a node  
or SCV64 DMA to the VME bus causes the SCV64 to generate a bus error.  
This interrupt is routed only to INT4 of the ‘C6x responsible for causing the VME bus  
error. On-board logic routes enabled SCV64 interrupts and the inter-processor VINTx  
interrupts to INT4 as well.  
Any node can also determine the status of the bus error interrupts by reading the  
VSTATUS Register at address 016D 8000h. A “1” in any of the following bit  
positions of the register indicates which nodes have pending bus error interrupts.  
Bit  
Node Whose Access Caused the Bus Error  
D4  
D5  
D6  
D7  
Node A  
Node B  
Node C  
Node D  
To clear the interrupt, the interrupted ‘C6x writes a “1” to the same bit in the  
VSTATUS Register. It must also clear the appropriate bits in the SCV64 DCSR  
register before the board can access the VME bus again.  
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8.8. Inter-processor Interrupts  
The Inter-processor interrupts (VINTx) are shared with the SCV interrupt. They allow  
any processor to interrupt any other processor through the VINTx registers. There are  
four of these registers; one for each of the processors.  
To generate an interrupt to a particular processor, a “1” is written to bit D0 of the VINT  
register corresponding to the processor to be interrupted. These registers are accessible  
from any of the four processors. Node C, for example, can interrupt node B by writing  
“1” to the VINTB Register (address 016D 8008h).  
The VSTATUS Register (address 016D 8000h) also indicates that a node has a  
pending interrupt whenever any of the following bits is set to “1”:  
Bit  
Interrupted Node  
D8  
Node A  
Node B  
Node C  
Node D  
D9  
D10  
D11  
A processor clears an interrupt by clearing its corresponding bit VINTx register. In the  
case where node C interrupts node B, for example, node B would clear the interrupt by  
writing “0” to the VINTB Register (address 016D 8008h).  
8.9. VME Host Interrupts To Any Node  
A VME host can interrupt a particular node on the Monaco board using DSPINT in the  
HPIC register of the Host Port Interface (HPI). Refer to the TMS320C6x documentation  
for further information on using DSPINT.  
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Registers  
9 Registers  
This section provides a reference to the registers that are unique to the Monaco board.  
Information for the registers within the SCV64 bus interface chip, the ACT8990 Test  
Bus Controller (TBC), and the Hurricane PCI interface chip can be found in their  
respective data sheets.  
Most of the registers described in this section are accessed from the processor nodes. Of  
these, most are shared among nodes A, B, C, and D. A few, though, are unique to each  
node. The registers that are not accessible from the processor nodes are part of the VME  
A24 Host Port Interfaces and to the TBC.  
The following table summarizes the registers described in this section.  
Table 13 Register Address Summary  
Access  
Register  
Privilege  
Bus  
Address  
VPAGE Register (for node A) R/W  
VPAGE Register (for node B) R/W  
VPAGE Register (for node C) R/W  
VPAGE Register (for node D) R/W  
Node A only  
Node B only  
Node C only  
Node D only  
016D 0000h  
016D 0000h  
016D 0000h  
016D 0000h  
VSTATUS Register  
VINTA Register  
VINTB Register  
VINTC Register  
VINTD Register  
KIPL_EN Register  
DSP~LINK3 Register  
ID Register  
R/W  
R/W  
R/W  
R/W  
R/W  
R/W  
R/W  
R/W*  
All nodes  
All nodes  
All nodes  
All nodes  
All nodes  
All nodes  
Node A only  
All nodes  
016D 8000h  
016D 8004h  
016D 8008h  
016D 800Ch  
016D 8010h  
016D 8014h  
016D 8018h  
016D 801Ch  
VME A24 Status Register  
VME A24 Control Register  
Read Only VME A24 slave interface base + 1000h  
R/W VME A24 slave interface base + 1004h  
*A processor can only write its own bit within this register.  
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VPAGE Register  
Address: 016D 0000h  
D31..  
..D24  
Reserved  
D23..  
..D20  
D19  
D18  
D17  
D16  
Reserved  
KADDR31  
KADDR30  
KADDR29  
KADDR28  
D15  
D14  
D13  
D12  
D11  
D10  
D9  
D8  
KADDR27  
KADDR26  
KADDR25  
KADDR24  
KADDR23  
KADDR22  
KADDR21  
KADDR20  
D7  
D6  
D5  
D4  
D3  
D2  
D1  
D0  
Reserved  
KFC2  
KFC1  
KFC0  
KSIZE1  
KSIZE0  
KADDR1  
KADDR0  
This register sets certain SCV64 address and control lines in order to extend the address  
range of the ‘C6x processors and set up the type of VME cycle to be performed. Each  
node has its own register. Except for D7 all other reserved bits are disconnected; D7 will  
store what is written to it. These register is undefined upon reset and should be  
initialized. Refer to the SCV64 User Manual for complete information on these signals.  
Sets the upper 12 address bits that are latched to the SCV64 when the  
‘C6x accesses the VME address space. This extends the 20 address bits  
of the ‘C6x to the full 32 bits of the VME address space. This allows a  
‘C6x access the entire VME bus as a master by setting these bits to  
1 Mbyte region being accessed. A write to this register latches data lines  
D19..8 and presents them to the SCV64 upper address lines  
KADDR31..20 respectively. For example, a write to the VPAGE register  
with data equal to 8 0000h causes the next outbound VME cycle (base  
address 0170 0000h) with offset 0x0 to be addressed at VME address  
8000 0000h.  
KADDR[31..20]  
Sets the access type as User or Supervisor Program, or Data accesses.  
Directly affects the address modifiers used for the VME Master cycle.  
KFC[2..0]  
Sets the number of bytes transferred for VME Master cycles. Directly  
affects D32, D16, or D8 access type.  
KSIZE[1..0]  
KADDR[1..0]  
These bits allow the node, which is little endian in order to access the  
PEM and PMCs, to access the SCV64, which is big endian.  
Although access to VPAGE is local to each processor node, any read or  
Note:  
write to the register requires that the Global Shared Bus to be acquired. The  
DSP’s cycles are extended until any current Global Shared Bus operations are  
complete when accessing the VPAGE Register.  
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VSTATUS Register  
Address: 016D 8000h  
D31..  
D23..  
D15  
D7  
..D24  
..D16  
Reserved  
Reserved  
D14  
D6  
D13  
D5  
D12  
D4  
D11  
D10  
D9  
D8  
Reserved  
VINTD  
VINTC  
VINTB  
VINTA  
D3  
D2  
D1  
D0  
BUSERRD BUSERRC BUSERRB BUSERRA  
KAVEC  
/KIPL2  
/KIPL1  
/KIPL0  
This register is used by a processor to identify the source of an INT4 interrupt.  
Status of the user defined interrupt to node D. Set to “1” when another  
processor has set the VINTD interrupt register. Active High.  
VINTD  
Status of the user defined interrupt to node C. Set to “1” when another  
processor has set the VINTC interrupt register. Active High.  
VINTC  
Status of the user defined interrupt to node B. Set to “1” when another  
processor has set the VINTB interrupt register. Active High.  
VINTB  
Status of the user defined interrupt to node A. Set to “1” when another  
processor has set the VINTA interrupt register. Active High.  
VINTA  
Status of the last bus cycle access made to the SCV64 by node D, including  
SCV64 register and VME master accesses. Set to “1” if there was an error.  
Cleared by writing“80h” to the VSTATUS register. All other interrupts are  
cleared when the source of the interrupt is cleared. This interrupt is cleared  
on reset.  
BUSERRD  
Status of the last bus cycle access made to the SCV64 by node C, including  
SCV64 register and VME master accesses. Set to “1” if there was an error.  
Cleared by writing“40h” to the VSTATUS register. All other interrupts are  
cleared when the source of the interrupt is cleared. This interrupt is cleared  
on reset.  
BUSERRC  
BUSERRB  
Status of the last bus cycle access made to the SCV64 by node B, including  
SCV64 register and VME master accesses. Set to “1” if there was an error.  
Cleared by writing “20h” to the VSTATUS register. All other interrupts are  
cleared when the source of the interrupt is cleared. This interrupt is cleared  
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on reset.  
Status of the last bus cycle access made to the SCV64 by node A, including  
SCV64 register and VME master accesses. Set to “1” if there was an error.  
Cleared by writing “10h” to the VSTATUS register. All other interrupts are  
cleared when the source of the interrupt is cleared. This interrupt is cleared  
on reset.  
BUSERRA  
Status of the interrupt vector last received on the data bus. High if the  
vector was not valid. During the IACK cycle, a non-vectored interrupt  
source causes this bit to be set, denoting a non-valid vector value on the  
bus. This bit is cleared on reset. The next SCV64 register, IACK, or  
VMEOUT cycle updates KAVEC. This signal is active high.  
KAVEC  
The interrupt level of pending interrupts in the SCV64. These signals are  
active low. For example, a value of 0x0 indicates that interrupt level 7 is  
pending.  
/KIPL2..0  
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VINTA Register  
Address: 016D 8004h  
D31..  
..D8  
Reserved  
D7..  
..D1  
D0  
Reserved  
Interrupt  
This register allows any processor to generate or clear an interrupt to node A. Upon reset  
this value is ‘0’.  
To generate an interrupt to node A, set bit D0 of this register to “1”.  
To clear an interrupt to node A, set bit D0 of this register to “0”.  
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VINTB Register  
Address: 016D 8008h  
D31..  
..D8  
Reserved  
D7..  
..D1  
D0  
Reserved  
Interrupt  
This register allows any processor to generate or clear an interrupt to node B. Upon reset  
this value is ‘0’.  
To generate an interrupt to node B, set bit D0 of this register to “1”.  
To clear an interrupt to node B, set bit D0 of this register to “0”.  
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VINTC Register  
Address: 016D 800Ch  
D31..  
..D8  
Reserved  
D7..  
..D1  
D0  
Reserved  
Interrupt  
This register allows any processor to generate or clear an interrupt to node C. Upon reset  
this value is ‘0’.  
To generate an interrupt to node C, set bit D0 of this register to “1”.  
To clear an interrupt to node C, set bit D0 of this register to “0”.  
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VINTD Register  
Address: 016D 8010h  
D31..  
..D8  
Reserved  
D7..  
..D1  
D0  
Reserved  
Interrupt  
This register allows any processor to generate or clear an interrupt to node D. Upon reset  
this value is ‘0’.  
To generate an interrupt to node D, set bit D0 of this register to “1”.  
To clear an interrupt to node D, set bit D0 of this register to “0”.  
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KIPL Enable Register  
Address: 016D 8014h  
D31..  
D7..  
..D8  
Reserved  
..D4  
D3  
D2  
D1  
D0  
Reserved  
KIPL_END KIPL_ENC KIPL_ENB  
KIPL_ENA  
The KIPL Enable Register is used to enable interrupts generated from the SCV64 to be  
sent to a particular processor node. The /KIPL lines represent VME interrupts, location  
monitor interrupt, SCV64 DMA, and SCV64 timer interrupts. These enable bits do not  
affect the individual KBERR interrupt bits.  
When set to “1”, interrupts to node D that are generated from the SCV64  
/KIPL lines are enabled. Active high.  
KIPL_END  
KIPL_ENC  
KIPL_ENB  
KIPL_ENA  
When set to “1”, interrupts to node C that are generated from the SCV64  
/KIPL lines are enabled. Active high.  
When set to “1”, interrupts to node B that are generated from the SCV64  
/KIPL lines are enabled. Active high.  
When set to “1”, interrupts to node A that are generated from the SCV64  
/KIPL lines are enabled. Active high.  
These bits are set to “0” upon reset.  
/KIPL interrupts must also be enabled by register writes to the SCV64.  
Note:  
Refer to the SCV64 data book for further information.  
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DSP~LINK3 Register  
Address: 016D 8018h  
D31..  
D7..  
..D8  
Reserved  
..D2  
D1  
D0  
Reserved  
ASTRB_EN DL3_RESET  
Processor node A uses this register assert or release reset to the DSP~LINK3 interface its  
local bus. It is also used to control the operation of DSP~LINK3 standard fast accesses.  
Setting this bit (D0) to “1” asserts reset to the DSP~LINK3.  
Setting this bit (D0) to “0” releases the DSP~LINK3 from reset.  
DL3_RESET  
Set to “1” upon reset. Application code must set it to “0” to release the  
DSP~LINK3 from reset.  
Setting this bit (D1) to “1” enables ASTRB accesses to DSP~LINK3.  
Accesses to the standard fast region when ASTRB_EN is set will be  
/ASTRB accesses.  
ASTRB_EN  
Setting this bit (D1) to “0” disables ASTRB accesses to  
DSP~LINK3. Accesses to the standard fast region when ASTRB_EN  
is cleared will be /DSTRB accesses.  
Set to “0” upon reset.  
This read/write register is not accessible from nodes B, C, or D.  
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ID Register  
Address: 016D 801Ch  
D31..  
..D8  
Reserved  
D7..  
..D4  
D3  
Node D  
D2  
D1  
D0  
Reserved  
Node C  
Node B  
Node A  
This register allows DSP software to identify which processor it is running on. Each of  
the four bits in the register correspond to a particular processor node. A node can read  
the status of all four bits but can only write to its own bit.  
To identify its processor, the DSP program first locks the Global Shared Bus for its use  
by asserting TOUT0. It then reads the value of this register and stores the result. This  
value is toggled (inverted) and written back to the register. The register is read once  
again and compared to the first reading to determine which bit was changed by the write  
operation. Because only the bit corresponding to the node can be changed, this bit will  
identify the node that the application is running on. TOUT0 should then be de-asserted to  
release the Global Shared Bus.  
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VME A24 Status Register  
VME A24 Secondary Base Address + 1000h  
D31..  
D7..  
..D8  
Reserved  
..D4  
D3  
HINT_D  
D2  
D1  
D0  
Reserved  
HINT_C  
HINT_B  
HINT_A  
The VME host reads this register to determine the state of the HINT lines from each  
processor node. Each bit corresponds to one of the four processor nodes. The state of the  
bit is simply a reflection of the HINT bit value in the corresponding ‘C6x HPIC register.  
A “1” in the bit position indicates that the corresponding ‘C6x processor has requested  
an interrupt.  
Bit D0 is set to “1” when node A is requesting a host interrupt.  
Bit D1 is set to “1” when node B is requesting a host interrupt.  
Bit D2 is set to “1” when node C is requesting a host interrupt.  
Bit D3 is set to “1” when node D is requesting a host interrupt.  
HINT_A  
HINT_B  
HINT_C  
HINT_D  
This read only register is accessed from the VME A24 bus. It is located at offset 1000h  
from the base address set by jumper JP1 (A23..A17).  
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VME A24 Control Register  
VME A24 Secondary Base Address + 1004h  
D31..  
D7..  
..D8  
Reserved  
..D1  
D0  
Reserved  
/Reset  
The VME host uses this register to reset all Monaco board devices except for the SCV64  
bus interface chip.  
To reset the board, the VME host writes a “0” to bit D0.  
This read/write register is accessed from the VME A24 bus. It is located at offset 1004h  
from the base address set by jumper JP1 (A23..A17).  
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Spectrum Signal Processing  
Monaco Technical Reference  
Specifications  
10 Specifications  
10.1. Board Identification  
Power, current, and data throughput specifications depend upon the type and version of  
processors used on the board.  
Monaco  
Monaco boards currently use the TMS320C6201B  
DSP.  
Earlier Monaco versions used the TMS320C6201.  
Monaco boards with this processor may have heat  
sinks or fans installed over the DSPs due to the  
higher power consumption of the earlier DSP.  
Monaco67 boards use the TMS320C6701 DSP.  
Monaco67  
The processor type and version can be identified by examining the DSPs on the board;  
earlier DSPs have the marking “C21”, while TMS320C6201B chips are marked “C31”.  
Boards equipped with earlier TMS320C6201 revision 2.1 chips may also have heat sinks  
or fans attached to the cover of the DSPs.  
The board’s 600-level part number may also be used to determine which DSPs are used  
on the board. The following table presents a partial list of Monaco part numbers.  
200 MHz TMS320C6201  
200 MHz TMS320C6201B  
167 MHz TMS320C6701  
600-00078  
600-00112  
600-00127  
600-00128  
600-00129  
600-00220  
600-02097  
600-02100  
600-00271  
600-00272  
600-00273  
600-00254  
600-00256  
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Specifications  
10.2. General  
Table 14 Specifications  
Parameter  
Monaco  
Monaco  
Monaco67  
TMS320C6201B TMS320C6201 TMS320C6701  
Current Consumption  
+5 Volts  
3.6 Amps  
0 Amps  
8.8 Amps  
0 Amps  
0 Amps  
44 Watts  
6U  
3.0 Amps  
0 Amps  
+12 Volts  
-12 Volts  
0 Amps  
0 Amps  
Power  
18 Watts  
15 Watts  
Height  
Width  
1 VME slot  
0° C to 50° C  
Operating Temperature  
60  
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Specifications  
10.3. Performance and Data Throughput  
The following table gives the data transfer rates between different memory, processor  
and interface resources on the Monaco board. Monaco boards using the TMS320C6201  
processor have a clock speed of 200 MHz; Monaco67 boards using the TMS230C6701  
processor have a clock speed of 167 MHz.  
Table 15 Data Access/Transfer Performance  
Clock Speed  
200 167  
400  
Units  
MHz  
Source  
Target  
Comment  
‘C6x  
Local SBSRAM  
333 MB/s  
333 MB/s  
333 MB/s  
74 MB/s  
83 MB/s  
12.5 MB/s  
24 MB/s  
138 ns  
Local SDRAM  
400  
400  
88  
PEM Site  
Global SRAM read  
Global SRAM write  
DSP~LINK3 Standard  
DSP~LINK3 Standard Fast  
Hurricane Registers  
VMEbus (master) read  
100  
15  
28  
115  
2
MB/s  
Coupled read. Typical value for a "real" slave, which is slower  
than for an "ideal" VME slave.  
VMEbus (master) write  
9
MB/s  
De-coupled write. Typical value for a "real" slave, which is  
slower than for an "ideal" VME slave.  
VME Host  
Global SRAM  
Hurricane Registers  
HPI read  
40 MB/s  
150 ns  
14 MB/s  
Maximum speed from internal ‘C6x memory when the ‘C6x is  
not accessing memory  
HPI write  
28 MB/s  
Maximum speed to internal ‘C6x memory when the ‘C6x is not  
accessing memory.  
SCV64 DMA  
Global SRAM  
40 MB/s  
150 ns  
Hurricane Registers  
VMEbus (master) read  
VMEbus (master) write  
80 MB/s  
80 MB/s  
128 MB/s  
128 MB/s  
Hurricane DMA Global SRAM R/W  
PMC Site Global SRAM R/W  
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Monaco Technical Reference  
Connector Pinouts  
11 Connector Pinouts  
C B A  
1
1
2
1
2
Node D  
‘C6x  
JN7  
JN6  
Node  
D
PEM  
1
PEM  
2
59 60 59 60  
1
2
1
2
VME  
P1  
JN8  
JN9  
Node C  
‘C6x  
Node  
C
PEM  
1
PEM  
2
59 60 59 60  
1
2
1
2
JN10  
JN11  
C B A  
32  
Node B  
‘C6x  
Node  
B
PEM  
1
PEM  
2
59 60 59 60  
1
2
1
2
JN13  
JN12  
Node A  
‘C6x  
Node  
A
PEM  
1
PEM  
2
D C B A Z  
1
59 60 59 60  
1
2
1
2
JN1  
JN2  
1
2
JN5  
VME  
P2  
49 50  
63 64  
63 64  
1
2
JN4  
63 64  
2
68  
D C B A Z  
32  
1
2
1
2
13  
14  
13  
14  
J3  
J1  
J2  
1
67  
JTAG IN  
Connector  
JTAG OUT  
Connector  
J8  
DSP~LINK3 Ribbon Cable Connector  
Figure 13 Connector Layout  
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Connector Pinouts  
11.1. VME Connectors  
VME connector P1 is a standard 96-pin DIN 3-row connector. VME connector P2 is  
standard 160-pin DIN 5-row connector. The Monaco board will be factory configured to  
route either the PMC or DSP~LINK3 connector to P2. Refer to the appropriate pinout for  
your board for this.  
Table 16 VME P1 Connector Pinout  
Pin #  
1
A Row Signal  
D00  
B Row Signal  
BBSY*  
BCLR*  
ACFAIL*  
BG0IN*  
BG0OUT*  
BG1IN*  
BG1OUT*  
BG2IN*  
BG2OUT*  
BG3IN*  
BG3OUT*  
BR0*  
C Row Signal  
D08  
2
D01  
D09  
3
D02  
D10  
4
D03  
D11  
5
D04  
D12  
6
D05  
D13  
7
D06  
D14  
8
D07  
D15  
9
GND  
SYSCLK  
GND  
DS1*  
DS0*  
WRITE*  
GND  
DTACK*  
GND  
AS*  
GND  
SYSFAIL*  
BERR*  
SYSRESET*  
LWORD*  
AM5  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
25  
26  
27  
28  
29  
30  
31  
32  
BR1*  
BR2*  
BR3*  
A23  
AM0  
A22  
AM1  
A21  
AM2  
A20  
GND  
IACK*  
IACKIN*  
IACKOUT*  
AM4  
AM3  
A19  
GND  
A18  
NC  
A17  
NC  
A16  
GND  
A15  
A07  
IRQ7*  
IRQ6*  
IRQ5*  
IRQ4*  
IRQ3*  
IRQ2*  
IRQ1*  
NC  
A14  
A06  
A13  
A05  
A12  
A04  
A11  
A03  
A10  
A02  
A09  
A01  
A08  
-12V  
+12V  
+5V  
+5V  
+5V  
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Table 17 VME P2 Connector Pinout (PMC to VME P2)  
Pin #  
Z Row Signal  
NC  
A Row Signal  
PMC JN4-2  
PMC JN4-4  
PMC JN4-6  
PMC JN4-8  
PMC JN4-10  
PMC JN4-12  
PMC JN4-14  
PMC JN4-16  
PMC JN4-18  
PMC JN4-20  
PMC JN4-22  
PMC JN4-24  
PMC JN4-26  
PMC JN4-28  
PMC JN4-30  
PMC JN4-32  
PMC JN4-34  
PMC JN4-36  
PMC JN4-38  
PMC JN4-40  
PMC JN4-42  
PMC JN4-44  
PMC JN4-46  
PMC JN4-48  
PMC JN4-50  
PMC JN4-52  
PMC JN4-54  
PMC JN4-56  
PMC JN4-58  
PMC JN4-60  
PMC JN4-62  
PMC JN4-64  
B Row Signal  
+5V  
C Row Signal  
D Row Signal  
NC  
1
PMC JN4-1  
PMC JN4-3  
PMC JN4-5  
PMC JN4-7  
PMC JN4-9  
PMC JN4-11  
PMC JN4-13  
PMC JN4-15  
PMC JN4-17  
PMC JN4-19  
PMC JN4-21  
PMC JN4-23  
PMC JN4-25  
PMC JN4-27  
PMC JN4-29  
PMC JN4-31  
PMC JN4-33  
PMC JN4-35  
PMC JN4-37  
PMC JN4-39  
PMC JN4-41  
PMC JN4-43  
PMC JN4-45  
PMC JN4-47  
PMC JN4-49  
PMC JN4-51  
PMC JN4-53  
PMC JN4-55  
PMC JN4-57  
PMC JN4-59  
PMC JN4-61  
PMC JN4-63  
2
GND  
GND  
NC  
NC  
3
CLKS_C1  
GND  
GND  
4
A24  
CLKS_A1  
GND  
5
CLKR_C1  
GND  
A25  
6
A26  
CLKR_A1  
GND  
7
CLKX_C1  
GND  
A27  
8
A28  
CLKX_A1  
GND  
9
DR_C1  
GND  
A29  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
25  
26  
27  
28  
29  
30  
31  
32  
A30  
DR_A1  
GND  
DX_C1  
GND  
A31  
GND  
+5V  
DX_A1  
GND  
FSR_C1  
GND  
D16  
D17  
D18  
D19  
D20  
D21  
D22  
D23  
GND  
D24  
D25  
D26  
D27  
D28  
D29  
D30  
D31  
GND  
+5V  
FSR_A1  
GND  
FSX_C1  
GND  
FSX_A1  
GND  
CLKS_D1  
GND  
CLKS_B1  
GND  
CLKR_D1  
GND  
CLKR_B1  
GND  
CLKX_D1  
GND  
CLKX_B1  
GND  
DR_D1  
GND  
DR_B1  
GND  
DX_D1  
GND  
DX_B1  
GND  
FSR_D1  
GND  
FSR_B1  
GND  
FSX_D1  
GND  
FSX_B1  
NC  
NC  
GND  
NC  
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Table 18 VME P2 Connector (DSP~LINK3 to VME P2)  
Pin #  
Z Row Signal  
NC  
A Row Signal  
NC  
B Row Signal  
+5V  
C Row Signal  
D Row Signal  
NC  
1
DL3_A15  
DL3_A13  
DL3_A11  
DL3_A9  
DL3_A7  
DL3_A5  
DL3_A3  
DL3_A1  
DL3_R/W  
NC  
2
GND  
DL3_A14  
DL3_A12  
DL3_A10  
DL3_A8  
GND  
NC  
NC  
3
CLKS_C1  
GND  
GND  
4
A24  
CLKS_A1  
GND  
5
CLKR_C1  
GND  
A25  
6
DL3_A6  
A26  
CLKR_A1  
GND  
7
CLKX_C1  
GND  
DL3_A4  
A27  
8
DL3_A2  
A28  
CLKX_A1  
GND  
9
DR_C1  
GND  
DL3_A0  
A29  
10  
11  
12  
13  
14  
15  
16  
17  
18  
19  
20  
21  
22  
23  
24  
25  
26  
27  
28  
29  
30  
31  
32  
/DL3_RESET  
/DL3_DSTRB  
/DL3_ASTRB  
/DL3_RDY  
/DL3_INT0  
/DL3_INT1  
NC  
A30  
DR_A1  
GND  
DX_C1  
GND  
A31  
NC  
GND  
+5V  
NC  
DX_A1  
GND  
FSR_C1  
GND  
NC  
D16  
D17  
D18  
D19  
D20  
D21  
D22  
D23  
GND  
D24  
D25  
D26  
D27  
D28  
D29  
D30  
D31  
GND  
+5V  
/DL3_INT2  
/DL3_INT3  
NC  
FSR_A1  
GND  
FSX_C1  
GND  
FSX_A1  
GND  
CLKS_D1  
GND  
DL3_D31  
DL3_D29  
DL3_D27  
DL3_D25  
DL3_D23  
DL3_D21  
DL3_D19  
DL3_D17  
DL3_D15  
DL3_D13  
DL3_D11  
DL3_D9  
DL3_D30  
DL3_D28  
DL3_D26  
DL3_D24  
DL3_D22  
DL3_D20  
DL3_D18  
DL3_D16  
DL3_D14  
DL3_D12  
DL3_D10  
DL3_D8  
DL3_D6  
DL3_D4  
DL3_D2  
DL3_D0  
CLKS_B1  
GND  
CLKR_D1  
GND  
CLKR_B1  
GND  
CLKX_D1  
GND  
CLKX_B1  
GND  
DR_D1  
GND  
DR_B1  
GND  
DX_D1  
GND  
DX_B1  
GND  
FSR_D1  
GND  
FSR_B1  
GND  
FSX_D1  
GND  
DL3_D7  
DL3_D5  
FSX_B1  
NC  
NC  
DL3_D3  
GND  
DL3_D1  
NC  
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11.2. PMC Connectors  
The PMC Connectors use a standard CMC style 1mm pitch SMT connector.  
Table 19 PMC Connector JN1 Pinout  
Pin #  
1
Signal  
TCK  
Pin #  
2
Signal  
-12V  
3
GND  
4
INTA#  
INTC#  
+5V  
5
INTB#  
BMODE1#  
INTD#  
GND  
6
7
8
9
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
52  
54  
56  
58  
60  
62  
64  
RSVD  
RSVD  
GND  
GNT#  
+5V  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
51  
53  
55  
57  
59  
61  
63  
CLK  
GND  
REQ#  
V(I/O)  
AD28  
AD25  
GND  
AD31  
AD27  
GND  
BE3#  
AD21  
+5V  
AD22  
AD19  
V(I/O)  
FRAME#  
GND  
AD17  
GND  
IRDY#  
+5V  
DEVSEL#  
GND  
LOCK#  
SBO#  
GND  
AD15  
AD11  
+5V  
SDONE#  
PAR  
V(I/O)  
AD12  
AD9  
GND  
BE0#  
AD5  
AD6  
AD4  
GND  
AD3  
V(I/O)  
AD2  
AD1  
AD0  
+5V  
GND  
REQ64#  
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Table 20 PMC Connector JN2  
Pin #  
1
Signal  
+12V  
Pin #  
2
Signal  
TRST#  
TDO  
3
TMS  
4
5
TDI  
6
GND  
7
GND  
8
RSVD  
RSVD  
+3.3V  
BMODE3#  
BMODE4#  
GND  
9
RSVD  
BMODE2#  
RST#  
+3.3V  
RSVD  
AD30  
GND  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
52  
54  
56  
58  
60  
62  
64  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
51  
53  
55  
57  
59  
61  
63  
AD29  
AD26  
AD24  
IDSEL  
+3.3V  
AD18  
AD16  
GND  
+3.3V  
AD23  
AD20  
GND  
BE2#  
RSVD  
+3.3V  
STOP#  
GND  
TRDY#  
GND  
PERR#  
+3.3V  
BE1#  
AD14  
GND  
SERR#  
GND  
AD13  
AD10  
AD8  
+3.3V  
RSVD  
RSVD  
GND  
AD7  
+3.3V  
RSVD  
RSVD  
GND  
RSVD  
RSVD  
+3.3V  
RSVD  
ACK64#  
GND  
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Table 21 PMC Connector JN4  
Pin #  
1
Signal  
P2C1  
Pin #  
2
Signal  
P2A1  
3
P2C2  
4
P2A2  
5
P2C3  
6
P2A3  
7
P2C4  
8
P2A4  
9
P2C5  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
52  
54  
56  
58  
60  
62  
64  
P2A5  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
51  
53  
55  
57  
59  
61  
63  
P2C6  
P2A6  
P2C7  
P2A7  
P2C8  
P2A8  
P2C9  
P2A9  
P2C10  
P2C11  
P2C12  
P2C13  
P2C14  
P2C15  
P2C16  
P2C17  
P2C18  
P2C19  
P2C20  
P2C21  
P2C22  
P2C23  
P2C24  
P2C25  
P2C26  
P2C27  
P2C28  
P2C29  
P2C30  
P2C31  
P2C32  
P2A10  
P2A11  
P2A12  
P2A13  
P2A14  
P2A15  
P2A16  
P2A17  
P2A18  
P2A19  
P2A20  
P2A21  
P2A22  
P2A23  
P2A24  
P2A25  
P2A26  
P2A27  
P2A28  
P2A29  
P2A30  
P2A31  
P2A32  
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Table 22 Non-standard PMC Connector JN5  
Pin #  
1
Signal  
CLKS_A1  
GND  
Pin #  
2
Signal  
CLKS_C1  
GND  
3
4
5
CLKR_A1  
GND  
6
CLKR_C1  
GND  
7
8
9
CLKX_A1  
DR_A1  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
CLKX_C1  
DR_C1  
DX_C1  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
DX_A1  
FSR_A1  
FSX_A1  
GND  
FSR_C1  
FSX_C1  
GND  
CLKS_B1  
GND  
CLKS_D1  
GND  
CLKR_B1  
GND  
CLKR_D1  
GND  
CLKX_B1  
DR_B1  
CLKX_D1  
DR_D1  
DX_D1  
DX_B1  
FSR_B1  
FSX_B1  
GND  
FSR_D1  
FSX_D1  
GND  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
Reserved  
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Connector Pinouts  
11.3. PEM Connectors  
Both PEM connectors use 60 pin 0.8mm pitch SMT connectors. PEM_CON1 is the  
closest to the front panel.  
Table 23 PEM 1 Connector Pinout  
Pin #  
1
Signal  
32MHz  
EA2  
Pin #  
2
Signal  
GND  
3
4
ED16  
ED17  
ED18  
ED19  
ED20  
ED21  
ED22  
ED23  
GND  
5
EA3  
6
7
EA4  
8
9
EA5  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
52  
54  
56  
58  
60  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
51  
53  
55  
57  
59  
EA6  
EA7  
EA8  
EA9  
GND  
EA10  
EA11  
EA12  
EA13  
EA14  
EA15  
EA16  
EA17  
+3.3V  
+3.3V  
EA18  
EA19  
/ARE  
ARDY  
/PEM_CE1  
/AWE  
/AOE  
GND  
ED24  
ED25  
ED26  
ED27  
ED28  
ED29  
ED30  
ED31  
+5V  
+5V  
CLKX0  
FSX0  
DX0  
DR0  
FSR0  
CLKR0  
GND  
CLKS0  
/RESET  
/PEM_INT1  
SDCLK  
GND  
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Table 24 PEM 2 Connector Pinout  
Pin #  
1
Signal  
GND  
Pin #  
2
Signal  
GND  
3
CLKX1  
FSX1  
4
ED0  
5
6
ED1  
7
DX1  
8
ED2  
9
DR1  
10  
12  
14  
16  
18  
20  
22  
24  
26  
28  
30  
32  
34  
36  
38  
40  
42  
44  
46  
48  
50  
52  
54  
56  
58  
60  
ED3  
11  
13  
15  
17  
19  
21  
23  
25  
27  
29  
31  
33  
35  
37  
39  
41  
43  
45  
47  
49  
51  
53  
55  
57  
59  
FSR1  
ED4  
CLKR1  
GND  
ED5  
ED6  
CLKS1  
RSVD  
/PEM_CE2  
RSVD  
/HOLD  
/HOLDA  
RSVD  
EA20  
ED7  
GND  
ED8  
ED9  
ED10  
ED11  
ED12  
ED13  
ED14  
ED15  
+5V  
EA21  
RSVD  
+3.3V  
+3.3V  
+5V  
/BE0  
DMAC0  
DMAC1  
DMAC2  
+12V  
-12V  
/BE1  
/BE2  
/BE3  
/SDRAS  
/SDCAS  
/SDWE  
GND  
/PEM_INT2  
RSVD  
GND  
PEM_TIMER  
GND  
RSVD  
SDA10  
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11.4. JTAG Connectors  
Both JTAG connectors use 2 x 7, 0.1” x 0.1” bare pin headers.  
Table 25 JTAG IN Connector Pinout  
Pin #  
Signal  
TMS  
Pin #  
2
Signal  
/TRST  
GND  
1
3
TDI  
4
5
PD  
6
key (no pin)  
GND  
7
TDO  
8
9
TCK_RET  
TCK  
10  
12  
14  
GND  
11  
13  
GND  
EMU0  
EMU1  
Table 26 JTAG OUT Connector  
Pin #  
Signal  
TMS  
Pin #  
2
Signal  
/TRST  
key (no pin)  
GND  
1
3
TDO  
4
5
PD  
6
7
TDI  
8
GND  
9
TCK_RET  
TCK  
10  
12  
14  
GND  
11  
13  
GND  
EMU0  
EMU1  
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SCV64 Register Values  
Appendix A: SCV64 Register Values  
This appendix briefly describes the default register settings for the SCV64 on the  
Monaco board. The following table shows the default values that are programmed into  
the registers by the initialization code supplied with the Monaco board.  
Table 27 SCV64 Register Initialization  
‘C6x Address Register  
DMA Local Address  
Value  
016E 0000h  
016E 0004h  
016E 0008h  
016E 000Ch  
016E 0010h  
016E 0014h  
016E 0018h  
016E 001Ch  
016E 0020h  
016E 0024h  
016E 0028h  
016E 002Ch  
016E 0030h  
016E 0034h  
016E 0038h  
016E 003Ch  
016E 0040h  
016E 0044h  
016E 0048h  
016E 004Ch  
016E 0050h  
to  
00000000h  
00000000h  
00000000h  
00000000h  
See notes  
Read only  
Read only  
Read only  
00000000h  
00000000h  
00000000h  
Read only  
Read only  
DMA VMEbus Address  
DMA Transfer Count  
Control and Status  
VMEbus Slave Base Address  
Rx FIFO Data  
Rx FIFO Address Register  
Rx FIFO Control Register  
VMEbus/VSB Bus Select  
VMEbus Interrupter Vector  
Access Protect Boundary  
Tx FIFO Data Output Latch  
Tx FIFO Address Output Latch  
Tx FIFO AM Code and Control Bit Latch Read only  
Location Monitor FIFO Read Port  
SCV64 Mode Control  
Read only  
24000005h  
00000000h  
00000000h  
Read only  
Read only  
Slave A64 Base Address  
Master A64 Base Address  
Local Address Generator  
DMA VMEbus Transfer Count  
Reserved  
016E 007Ch  
016E 0080h  
016E 0084h  
016E 0088h  
016E 008Ch  
016E 0090h  
016E 0094h  
016E 0098h  
016E 009Ch  
016E 00A0h  
Status Register 0  
00000000h  
00000080h  
0000001Ch  
00000000h  
000000CFh  
00000034h  
Read only  
00000002h  
Read only  
Status Register 1  
General Control Register  
VMEbus Interrupter Requester  
VMEbus Requester Register  
VMEbus Arbiter Register  
ID Register  
Control and Status Register  
Level 7 Interrupt Status Register  
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SCV64 Register Values  
Table 27 SCV64 Register Initialization  
‘C6x Address Register  
Value  
016E 00A4h  
016E 00A8h  
Local Interrupt Status Register  
Level 7 Interrupt Enable Register  
Read only  
00000001h  
00000000h  
00000000h  
016E 00ACh Local Interrupt Enable Register  
016E 00B0h  
016E 00B4h  
016E 00B8h  
VMEbus Interrupt Enable Register  
Local Interrupts 1 and 0 Control Register 00000089h  
Local Interrupts 3 and 2 Control Register 000000A8h  
016E 00BCh Local Interrupts 5 and 4 Control Register 000000CBh  
016E 00C0h  
016E 00C4h  
016E 00C8h  
Miscellaneous control register  
Delay line control register  
Delay line status register 1  
00000000h  
Dynamically configured by SCV64 initialization routine  
Dynamically configured by SCV64 initialization routine  
016E 00CCh Delay line status register 2  
Dynamically configured by SCV64 initialization routine  
016E 00D0h  
016E 00D4h  
016E 00D8h  
Delay line status register 3  
Mailbox register 0  
Dynamically configured by SCV64 initialization routine  
Not used  
Not used  
Not used  
Not used  
Mailbox register 1  
016E 00DCh Mailbox register 2  
016E 00E0h  
016E 00E4h  
to  
Mailbox register 3  
Reserved  
016E 01FCh  
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SCV64 Register Values  
Index  
configurations  
DSP processor, 9  
configuring  
Hurricane, 33  
connector, 63  
A
A24 slave interface reset, 5  
arbitration  
global shared bus, 19  
Auto-Syscon capability, 27  
JTAG, 73  
IN, 73  
OUT, 73  
layout, 63  
B
PEM, 71  
PEM 1, 71  
PEM 2, 72  
backplane connectors  
VME bus, 23  
PMC, 67  
JN1, 67  
JN2, 68  
JN4, 69  
JN5, 70  
base address, VME  
A24 slave interface  
setting via jumpers, 7  
block diagram, 4  
processor node, 10  
board layout diagram, 6  
boot mode  
VME  
P1, 64  
P2  
DSP~LINK3 to VME, 66  
PMC to VME, 65  
setting via jumpers, 7  
boot source of DSP, setting, 16  
booting  
D
DSP, 16  
burst cycle global shared bus access, 20  
bus  
data throughput specifications, 61  
data transfer operating modes  
DSP~LINK3, 29  
Address Strobe Control, 30  
debugging, JTAG, 37  
global shared. See global shared bus  
VME  
backplane connectors, 23  
interface, 23  
DSP  
SCV64 VME64  
master, 27  
primary slave, 23  
secondary slave, 24  
operation, 23  
booting, 16  
jumpers to set boot source, 16  
identifying which processor the  
software is running on, 55  
memory configuration, 11  
bus error interrupts, 43  
memory map, 13  
external-memory space CE1, 14  
C
processor configurations, 9  
registers  
C6x. See DSP  
CE1 - external-memory space, 14  
chain, JTAG, 37  
clear interrupt  
Host Port Interface register addresses, 26  
internal peripheral, 12  
DSP~LINK3  
to node A, 49  
connector to VME, 66  
to node B, 50  
to node C, 51  
to node D, 52  
data transfer operating modes, 29  
Address Strobe Control, 30  
interface, 29  
signals, 31  
clock speed, 1  
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Index  
interrupts to node A, 40  
register, 54  
identifying processor the software is  
running on, 55  
reset, 31  
IDSEL line, 36  
INT4 interrupt  
identify source, 47  
interface  
assert or release, 54  
standard fast accesses, control, 54  
DSP~LINK3, 29  
PCI, 33  
E
EEPROM, 16  
enable interrupt  
from SCV64 to a node, 53  
external memory space of DSP, 11  
signals  
DSP~LINK3, 31  
internal memory space of DSP, 11  
internal peripheral register values, C6x,  
12  
F
inter-processor interrupts, 44  
interrupt  
features of the board, 1  
fixed-point, 1  
floating-point, 1  
bus error, 43  
DSP~LINK3  
to node A, 40  
enable  
G
from SCV64 to a node, 53  
handling, 39  
Hurricane, 41  
generate interrupt  
to node A, 49  
INT4  
to node B, 50  
to node C, 51  
to node D, 52  
identify source, 47  
inter-processor, 44  
lines, 15  
global shared bus, 19  
node A, to, 49  
node B, to, 50  
node C, to, 51  
node D, to, 52  
PCI, 41  
access  
burst cycle, 20  
locked cycle, 21  
locking, 21  
precautions to follow, 21  
single cycle, 20  
PEM, 41  
routing, 40  
arbitration, 19  
memory, 19  
SCV64, 41  
enable to a node, 53  
VME host to any node, 44  
H
handling interrupts, 39  
Host Port Interface, 15, 26  
register addresses, 26  
HPI. See Host Port Interface  
Hurricane, 33  
J
JN1 connector, 67  
JN2 connector, 68  
JN4 connector, 69  
JN5 connector, 70  
JTAG, 2  
configuring, 33  
implementation, 36  
interrupts, 41  
connector, 73  
IN, 73  
register set, 34  
OUT, 73  
debugging, 37  
reset, 5  
JTAG chain, 37  
JTAG IN connector, 73  
I
ID register, 55  
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SCV64 Register Values  
JTAG OUT connector, 73  
power supply, 4  
jumper settings, 7  
processor. See DSP  
setting DSP boot source, 16  
Processor Expansion Module. See PEM  
K
R
KIPL  
reference documents, 3  
register, 45  
enable register, 53  
status bits, 42  
address summary, 45  
C6x internal peripheral, 12  
DSP~LINK3, 54  
Host Port Interface  
addresses, 26  
L
locked cycle (global shared bus access),  
21  
locking  
Hurricane register set, 34  
ID, 55  
KIPL enable, 53  
SCV64 VME64, 75  
VINTA, 49  
VINTB, 50  
VINTC, 51  
VINTD, 52  
global shared bus, 21  
precautions to follow, 21  
M
memory  
configuration, DSP, 11  
global shared bus, 19  
map  
VME A24 control register, 57  
VME A24 status register, 56  
VPAGE, 27, 46  
VSTATUS, 27, 47  
reset, 5  
DSP, 13  
external-memory space CE1, 14  
PCI, 33  
primary VME A24/A32, 24  
secondary VME A24, 25  
DSP~LINK3, 31  
assert or release, 54  
JTAG, 5  
Monaco67, 1  
VME A24 slave interface reset, 5  
VME SYSRESET, 5  
routing  
P
P1 connector, 64  
P2 connector, 65  
PCI  
interrupts, 40  
serial ports, 17  
IDSEL line of device, 36  
interface, 33  
S
interrupts, 41  
memory map, 33  
PEM, 2, 15  
SBSRAM, 15  
SCV64 VME64 interface  
interrupts, 41  
connector, 71  
PEM 1, 71  
master, 27  
memory map  
primary, 24  
PEM 2, 72  
interrupts, 41  
secondary interface, 25  
performance specifications, 61  
pinout. See connector  
PMC, 2  
primary slave, 23  
register initialization, 75  
secondary slave, 24  
VPAGE register, 46  
SDRAM, 15  
connector, 67  
JN1, 67  
JN2, 68  
serial ports, 2  
JN4, 69  
JN5, 70  
pin assignments, 18  
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Index  
port1  
VINTC register, 51  
VINTD register, 52  
VME, 2  
VME and PMC connections, 18  
routing, 17  
setting via jumpers, 7  
A24 control register, 57  
A24 slave interface base address  
setting via jumpers, 7  
single cycle global shared bus access,  
20  
specifications  
A24 slave interface reset, 5  
A24 status register, 56  
data throughput, 61  
performance, 61  
synchronous burst SRAM, 15  
synchronous DRAM, 15  
SYSRESET, 5  
bus  
backplane connectors, 23  
interface, 23  
SCV64 VME64  
master, 27  
primary slave, 23  
secondary slave, 24  
operation, 23  
T
TBC, 37  
connector  
P1, 64  
Test Bus Controller, 37  
throughput specifications, 61  
TMS320C6201, 1, 9  
TMS320C6701, 1, 9  
token passing, 19  
P2  
DSP~LINK3 to VME, 66  
PMC to VME, 65  
interrupts  
host to any node, 44  
TOUT0, 16, 21  
SYSRESET, 5  
VME A24 control register, 57  
VME A24 status register, 56  
VPAGE register, 27, 46  
V
VINTA register, 49  
VINTB register, 50  
VSTATUS register, 27, 47  
80  
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