U S E R ’ S M A N U A L
ACTIVE MODULE
CARRIER
MODEL
VX402C-64
Document Part No: 11028504B
AMENDMENT NOTICE
C&H Technologies, Inc. makes every attempt to provide up-to-date manuals with the associated
equipment. Occasionally, changes are made to the equipment wherein it is necessary to provide
amendments to the manual. If any amendments are provided for this manual they are printed on colored
paper and will be provided with the module and manual. Manual updates may also be found on out web
NOTE
The contents of any amendment may affect operation, maintenance, or
calibration of the equipment.
REVISION HISTORY
Rev Date
Description
*
03-20-2002 Original release
A
B
09-13-2004 Corrected Figure A-3 (J1) & A-4 (J2) Pin Configurations
07-10-2008 Added -0003 and -0004 version information
Clarified Electrical information (Section 1.2.2)
Clarified Pass-Through Cable information (Section 3.3.3)
iii
INTRODUCTION
This manual describes the operation and use of the C&H Model VX402C-64 VXI Active Carrier
Module (Part Number 11028500 Revision B or higher). This VXI module is one of a number of
test and data acquisition/control modules in the VME and VXI format provided by C&H.
Contained within this manual are the physical and electrical specifications, installation and
startup procedures, functional description, and configuration guidelines to adequately use the
product.
The part numbers covered by this manual are:
Part Number
Description
11028500-0001 VX402C-64 (with +3.3V supplied from VXI +5V)
11028500-0002 VX402C-64 (without +3.3V supply)
11028500-0003 VX402C-64 (with +3.3V supplied from VXI -24V)
11028500-0004 VX402C-64 (with +3.3V supplied from VXI +24V)
iv
TABLE OF CONTENTS
1.0 GENERAL DESCRIPTION ..................................................................................................... 7
1.1 PURPOSE OF EQUIPMENT........................................................................................ 7
1.2 SPECIFICATIONS OF EQUIPMENT.......................................................................... 8
1.2.1 Key Features .................................................................................................. 8
1.2.2 Electrical ........................................................................................................ 8
1.2.3 Mechanical................................................................................................... 10
1.2.4 Environmental.............................................................................................. 10
1.2.5 Bus Compliance ........................................................................................... 10
2.0 INSTALLATION .................................................................................................................... 11
2.1 UNPACKING AND INSPECTION ............................................................................ 11
2.2 HANDLING PRECAUTIONS.................................................................................... 11
2.3 INSTALLATION ........................................................................................................ 11
2.4 PREPARATION FOR RESHIPMENT....................................................................... 11
3.0 FUNCTIONAL DESCRIPTION............................................................................................. 13
3.1 GENERAL.................................................................................................................. 13
3.2 TRIGGERS.................................................................................................................. 14
3.2.1 TTL TRIGGERS .......................................................................................... 14
3.2.2 ECL TRIGGERS.......................................................................................... 15
3.3 CONNECTORS........................................................................................................... 15
3.3.1 VXI REAR Connectors................................................................................ 15
3.3.2 VME-64 FRONT CONNECTORS............................................................... 15
3.3.3 PASS-THROUGH CONNECTORS............................................................. 16
3.4 SUMBUS CONFIGURATION.................................................................................... 18
3.4.1 SUMBUS CUSTOM AREA ......................................................................... 18
3.4.2 SUMBUS JUMPER SETTINGS................................................................... 19
4.0 OPERATING INSTRUCTIONS ............................................................................................. 21
APPENDIX A - CONNECTORS................................................................................................ A-1
v
LIST OF FIGURES
Figure 1. Front Panel and Top View (Top Shield Not Shown) .......................................................7
Figure 2. Power Schematic (-0001 version)....................................................................................8
Figure 3. Power Schematic (-0002 version)....................................................................................9
Figure 4. Power Schematic (-0003 & -0004 versions)....................................................................9
Figure 5. Functional Block Diagram.............................................................................................13
Figure 6. TTL Trigger Direction....................................................................................................14
Figure 7. ECL Trigger Direction...................................................................................................15
Figure 8. Pass-Through Connector Location ................................................................................16
Figure 9. SUMBUS Custom Area..................................................................................................18
Figure 10. SUMBUS Jumper Settings............................................................................................19
LIST OF TABLES
Table I. Power Supply Capabilities...............................................................................................10
Table II. VXI/VME Pass-Through Connections...........................................................................17
vi
1.0 GENERAL DESCRIPTION
The VX402C-64 Active Carrier allows an A- or B-size VME, VXI, or VME64 module to be used
in a C-size VXI mainframe chassis. Throughout the rest of this manual, the VME/VXI card being
carried will be referred to as the VME module.
The carrier provides an actively-buffered electrical interface for the standard VME bus signals.
The VX402C-64 does not support the full VME64 extension bus; however, -0001, -0003, and
-0004 versions provide +3.3V power to the P1 row D VME64 extension. The adapter also
features a VXI C-size mechanical enclosure to support and shield the VME module. The carrier
and its enclosure have been designed so that the front panel of the VME module sits flush with
the front panels of other C-size modules as shown in Figure 1.
The VX402C-64 supports interrupts and provides a capability for bringing P2 VME signals to the
front panel. The carrier also supports VXI VXITTL triggers and a prototype area is provided for
buffering the VXI SUMBUS signal. These features allow the VME module to transparently
interface to a C-size chassis.
VME
P1
J1
P1
USER’S VME
MODULE
VX402C-64
P2
J2
P2
VME
Figure 1. Front Panel and Top View (Top Shield Not Shown)
1.1 PURPOSE OF EQUIPMENT
This VX402C-64 was designed to provide an interface for using B-size VME modules in a VXI
C-size chassis. The active nature of the module allows extensions of the VXI bus without
violation of VME/VXI electrical bus standards.
7
1.2 SPECIFICATIONS OF EQUIPMENT
1.2.1 Key Features
Provides direct access to the VME module’s front panel I/O connections
Supplies buffered data, address, interrupt, and trigger lines (ECL and TTL)
Includes direct SUMBUS connections, as well as a prototyping area with fused ±12V
power supplies for buffered SUMBUS connections (jumper selectable)
Conforms with VMEbus/VXIbus driving and loading specifications
Provides VME64 +3.3V supplies (-0001, -0003, and -0004 versions only)
Mates with VXI, VME, and VME64 rear connectors
1.2.2 Electrical
The -0001, -0003, and -0004 versions provide +3.3V power to the P1 row D VME64 extension.
The -0002 version does not provide +3.3V power. A simplified power schematic for each
version is shown in Figure 2, Figure 3, and Figure 4. Excluding the +3.3V supply, the VX402C-
64 only requires 300mA of +5V power from the VXI backplane. This power requirement is for
the VX402C-64 alone. Any attached module will increase this value by the amount specified in
its data sheet.
Table I provides a summary of the supply capabilities of each version. The table assumes that
the VXI backplane is capable providing 1.2A on each of the seven +5V power pins. For versions
-0003 and -0004, 1.2A on the -24V and +24V pins.
VXI
VME64
BACKPLANE
CONNECTORS
+5V
(7 PINS)
+3.3V
+5V
(7 PINS)
DC-DC
CONVERTER
(10 PINS)
INTERNAL
LOGIC
GND
GND
Figure 2. Power Schematic (-0001 version)
8
VXI
VME64
BACKPLANE
CONNECTORS
+5V
+5V
(7 PINS)
(7 PINS)
INTERNAL
LOGIC
GND
GND
Figure 3. Power Schematic (-0002 version)
VXI
VME64
BACKPLANE
CONNECTORS
+5V
+5V
(7 PINS)
(7 PINS)
INTERNAL
LOGIC
GND
GND
OUT-
OUT+
ISOLATED
DC-DC
CONVERTER
+3.3V
+24V or -24V
(10 PINS)
(1 PIN)
Figure 4. Power Schematic (-0003 & -0004 versions)
9
Table I. Power Supply Capabilities
VX402C-64 Version
-0001
42.0W
not used
not used
1.5W
-0002
42.0W
not used
not used
1.5W
-0003
42.0W
not used
29W
1.5W
40.5W
-0004
42.0W
29W
not used
1.5W
VXI +5V Supply Capability
VXI +24V Supply Capability
VXI -24V Supply Capability
Internal +5V Power Consumption
Remaining +5V Power Available
40.5W
40.5W
40.5W
+3.3V Converter Efficiency
+5V Power Available to VME Module
+3.3V Power Available to VME Module
92%
n/a
40.5W
0W
80%
40.5W
23W
80%
40.5W
23W
37W Total
n/a = not applicable
1.2.3 Mechanical
The mechanical dimensions of the VX402C-64 are in conformance with the VXI bus
specification for the height and width of Size-C modules. The nominal dimensions are 233.35
mm (9.187 in) high x 156.337 mm (6.155 in) deep. Once the VX402C-64 is adapted to a VME
module, the total dimensions are 233.35 mm (9.187 in) high x 340.0 mm (13.386 in) deep. The
module is designed for a mainframe with 30.48 mm (1.2 in) spacing between slots.
1.2.4 Environmental
The environmental specifications of the module are:
Operating Temperature: 0C to +55C
Storage Temperature:
Humidity:
-40C to +75C
<95% without condensation
1.2.5 Bus Compliance
The module complies with the VXIbus Specification Revision 1.4 and with VMEbus
Specification ANSI/IEEE STD 1014-1987, IEC 821 and IEC 822.
Module:
Device Type:
VME to VXI Extender
Active Carrier
10
2.0 INSTALLATION
2.1 UNPACKING AND INSPECTION
In most cases the VX402C-64 is individually sealed and packaged for shipment. Verify that there
has been no damage to the shipping container. If damage exists then the container should be
retained as it will provide evidence of carrier caused problems. Such problems should be
reported to the carrier immediately as well as to C&H. If there is no damage to the shipping
container, carefully remove the module from its box and anti static bag and inspect for any signs
of physical damage. If damage exists, report immediately to C&H.
2.2 HANDLING PRECAUTIONS
The VX402C-64 contains components that are sensitive to electrostatic discharge. When
handling the module for any reason, do so at a static-controlled workstation, whenever possible.
At a minimum, avoid work areas that are potential static sources, such as carpeted areas. Avoid
unnecessary contact with the components on the module.
2.3 INSTALLATION
CAUTION: Read the entire User's Manual before proceeding with the
installation and application of power.
If necessary, remove the shield from the VX402C-64 and configure the switches and jumpers.
Replace the shield and insert the carrier into the appropriate slot according to the desired priority.
Insert the VME module through the front panel of the VX402C-64. Push firmly until the VME
module’s rear connectors are fully inserted into the front connector of the VX402C-64. Apply
power. If no obvious problems exist, proceed to communicate with the VME module.
The VX402C-64 connectors require high insertion force to completely connect with the VME
module. If it is difficult to assemble the unit through the front panel, it is recommended that the
VX402C-64 shield be removed, and the boards be mated before insertion into the chassis.
2.4 PREPARATION FOR RESHIPMENT
If the module is to be shipped separately it should be enclosed in a suitable water and vapor proof
anti static bag. Heat seal or tape the bag to insure a moisture-proof closure. When sealing the
bag, keep trapped air volume to a minimum.
The shipping container should be a rigid box of sufficient size and strength to protect the
equipment from damage. If the module was received separately from a C&H system, then the
original module shipping container and packing material may be re-used if it is still in good
condition.
11
12
3.0 FUNCTIONAL DESCRIPTION
3.1 GENERAL
VX402C-64 is a general purpose carrier module for VXI C-Size chasses. The module provides
actively buffered signals, which meet all VME specifications, to the VME module. A functional
block diagram is shown in Figure 5.
P1
J1
Trigger
Buffer
Interrupt
Buffer
Address
Buffer
To VME
Module
To VXI
Backplane
P2
J2
Data
Buffer
Pass-Through
Connectors
Trigger
Buffer
Figure 5. Functional Block Diagram
13
3.2 TRIGGERS
Both ECL and TTL triggers are supplied through the VX402C-64. There are switches on the
carrier which are used to set the direction of the triggers (to the backplane and from the
backplane).
3.2.1 TTL TRIGGERS
Eight TTL Trigger lines pass through the VX402C-64 to the front panel: TTLTRG0-7. Each
trigger line may be set as an input or output trigger. The trigger direction is set using switch S1
which can be seen in Figure 6. The directions are also clearly marked on the board itself.
`
J1
P1
S1
ON
1
TTLTRG0
TTLTRG1
TTLTRG2
TTLTRG3
TTLTRG4
TTLTRG5
TTLTRG6
TTLTRG7
J2
P2
S1
TO
FROM
BACKPLANE
BACKPLANE
TTLTRG
Figure 6. TTL Trigger Direction
14
3.2.2 ECL TRIGGERS
The VX402C-64 supports two ECL Trigger lines: ECLTRG0-1. Each trigger line may be set as
an input or output trigger. The trigger direction is set using switch S2 which can be seen in Figure
7. The trigger directions are clearly marked on the board itself.
J1
P1
S2
ON
1
ECLTRG0
ECLTRG1
S2
TO
FROM
BACKPLANE
BACKPLANE
ECLTRG
J2
P2
Figure 7. ECL Trigger Direction
3.3 CONNECTORS
3.3.1 VXI REAR Connectors
The P1 and P2 connectors are configured in accordance with the VXI specification and utilize
the ECL and TTL trigger lines. Pinout details for the rear connectors can be found in Appendix
A.
3.3.2 VME-64 FRONT CONNECTORS
The VX402C-64 interfaces with the VME module through two 160 pin VME-64 connectors: J1
and J2. These connectors conform to VME and VXI specifications and can accept both 160 pin
VME-64 (DIN 41 612 type C) and standard 96 pin VME/VXI connectors. Pinout details for the
front connectors can be found in Appendix A.
15
3.3.3 PASS-THROUGH CONNECTORS
One major difference between the VME bus and the VXI bus is that the outer rows of the P2
connector are not defined on the VME bus and they are defined on the VXI bus. For this reason,
the VX402C-64 Active Module Carrier provides a Pass-Through Connector system that be used
to optionally connect or not connect the VME P2 Rows A & C signals to the VXI P2 Rows A &
C signals.
The VX402C-64 can be shipped with an optional pass-through connector cable (11028508-
0001). This cable is used to make internal connections between the P2 and J2 connectors on the
VX402C-64. When the cable is installed, signals on the J2 connector of the VME module are
routed to signals on the P2 connector of the backplane. Only use this cable for modules which
utilize the outer rows on the J2 connector and completely adhere to the VXI specification. If the
VME module has no outer row connections, it is unnecessary to install the cable.
If the VME module has P2 signals which do not conform to the VXI spec, it may be necessary to
make a custom pass-through cable. Also, if the VME module does not support the outer row of
the J2 connector, a longer cable may be used to directly access these signals. Pinout details for
the pass-through connectors can be found in Appendix A. Figure 8 shows the placement of the
pass-through connectors on the VX402C-64.
J1
P1
Pass-Through
Connectors
To J2 Front
Connector
To P2 Rear
Connector
P2
J2
J12
J11
Figure 8. Pass-Through Connector Location
16
A one-to-one cable that connects Pin 1 (C32) on the VXI side to Pin 1 (C32) on the VME side,
and so on, could only be used if the VME module was designed to meet all of the VXI bus
specifications for these pins. If the installed VME module can not handle -24V, +24V, -5.2V or
any other signal on the corresponding pin, then a one-to-one cable can not be used.
The signal list for both the VXI side and the VME side is shown in Table II. The pass-through
connectors on the PCB are standard 64-pin (32x2) shrouded headers, specifically Samtec TST-
132-01-S-D. Mating connectors are very common in both IDC and discreet wire varieties.
Table II. VXI/VME Pass-Through Connections
VXI SIDE PASS-THROUGH CONNECTOR
VME SIDE PASS-THROUGH CONNECTOR
PIN
P2
SIGNAL
PIN
P2
SIGNAL
PIN
P2
SIGNAL
PIN
P2
SIGNAL
1
3
5
7
9
C32
C31
C30
C29
C28
-24V
+24V
GND
RSV3
GND
2
4
6
8
10
A32
A31
A30
A29
A28
SUMBUS
GND
MODID
RSV2
GND
1
3
5
7
9
C32
C31
C30
C29
C28
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
2
4
6
8
10
A32
A31
A30
A29
A28
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
11
13
15
17
19
C27
C26
C25
C24
C23
TTLTRG7*
TTLTRG5*
GND
TTLTRG3*
TTLTRG1*
12
14
16
18
20
A27
A26
A25
A24
A23
TTLTRG6*
TTLTRG4*
+5V
TTLTRG2*
TTLTRG0*
11
13
15
17
19
C27
C26
C25
C24
C23
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
12
14
16
18
20
A27
A26
A25
A24
A23
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
21
23
25
27
29
C22
C21
C20
C19
C18
GND
22
24
26
28
30
A22
A21
A20
A19
A18
GND
21
23
25
27
29
C22
C21
C20
C19
C18
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
22
24
26
28
30
A22
A21
A20
A19
A18
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
LBUSC11
LBUSC10
-5.2V
LBUSA11
LBUSA10
-5.2V
LBUSC09
LBUSA09
31
33
35
37
39
C17
C16
C15
C14
C13
LBUSC08
GND
LBUSC07
LBUSC06
-2V
32
34
36
38
40
A17
A16
A15
A14
A13
LBUSA08
GND
LBUSA07
LBUSA06
-5.2V
31
33
35
37
39
C17
C16
C15
C14
C13
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
32
34
36
38
40
A17
A16
A15
A14
A13
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
41
43
45
47
49
C12
C11
C10
C9
LBUSC05
LBUSC04
GND
LBUSC03
LBUSC02
42
44
46
48
50
A12
A11
A10
A9
LBUSA05
LBUSA04
GND
LBUSA03
LBUSA02
41
43
45
47
49
C12
C11
C10
C9
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
42
44
46
48
50
A12
A11
A10
A9
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
C8
A8
C8
A8
51
53
55
57
59
C7
C6
C5
C4
C3
GND
LBUSC01
LBUSC00
-5.2V
52
54
56
58
60
A7
A6
A5
A4
A3
-5.2V
LBUSA01
LBUSA00
GND
51
53
55
57
59
C7
C6
C5
C4
C3
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
52
54
56
58
60
A7
A6
A5
A4
A3
USER DEF
USER DEF
USER DEF
USER DEF
USER DEF
GND
ECLTRG1
61
63
C2
C1
CLK10-
CLK10+
62
64
A2
A1
-2V
ECLTRG0
61
63
C2
C1
USER DEF
USER DEF
62
64
A2
A1
USER DEF
USER DEF
To use the VXI TTLTRG signals, a custom cable should be used that connects each TTLTRG
signal to the desired VME P2 connector signal. The VX402C-64 has a set of eight switches that
are set to specify the direction of the trigger signal as shown Figure 6. If the trigger signal is an
input to the VME module, the switch should be ON (closed). If the trigger signal is output from
the VME module, the switch should be OFF (open).
17
3.4 SUMBUS CONFIGURATION
The VX402C-64 provides a direct connection of the SUMBUS signal through the pass-through
connector to the front connectors. The board also has a prototyping area so that the user can
hardwire a custom buffer for the SUMBUS signal.
3.4.1 SUMBUS CUSTOM AREA
The SUMBUS custom area consists of a prototyping grid, ±12V supplies, and two jumpers for
configuring the signal. The prototyping area is a 10x10 grid of 0.1” spaced through-hole pads
which can be used in any way desired. The SUMBUS signal can be wired to the prototyping area
using the two pads next to jumpers J21 and J13, and the jumpers must be configured to the
proper setting. The location of the custom area can be seen in Figure 9.
J1
P1
J2
P2
SUMBUS
CUSTOM AREA
J21
J13
-12V +12V
Figure 9. SUMBUS Custom Area
18
3.4.2 SUMBUS JUMPER SETTINGS
In order to use the SUMBUS signal, the jumpers J11 and J12 must be configured properly. The
three different settings for the jumpers can be seen in Figure 10. The SUMBUS signal can be
connected directly to the front panel (A), connected through the prototyping area (B), or
disconnected (C).
The pass-through connector must be installed for the SUMBUS signal to route to the front panel.
Also, both jumpers must be configured the same, or the SUMBUS signal will be disconnected.
J21 J13
J21 J13
J21 J13
DIR
DIR
DIR
SUMBUS
CUST
SUMBUS
CUST
SUMBUS
CUST
Direct Connection
Custom Connection
Disconnected
(C)
(A)
(B)
Figure 10. SUMBUS Jumper Settings
19
20
4.0 OPERATING INSTRUCTIONS
While the VX402C-64 is an active carrier, it is designed to be completely transparent to the host
interface. For this reason, the VME module can be accessed as if it were plugged directly into
the host backplane.
In order to operate the VME module, first set up the hardware configurations on the VX402C-64.
Then set the necessary trigger directions using the switches. Ensure the jumpers are set for proper
SUMBUS signal routing. Install or remove the pass-through connector cable as desired and
replace the shield if necessary.
The unit is now ready to be inserted into the chassis. Next, install the VME module into the front
connectors of the VX402C-64. Once power is applied, the VME module can be readily accessed
as if it were plugged directly in the backplane.
21
22
APPENDIX A - CONNECTORS
PIN
1
C
D08
B
-
A
D00
2
D09
-
D01
3
4
5
6
7
8
9
D10
D11
D12
D13
D14
D15
ACFAIL*
BGIN0*
BGOUT0*
BGIN1*
BG0UT1*
BGIN2*
BG0UT2*
BGIN3*
BGOUT3*
-
D02
D03
D04
D05
D06
D07
GND
SYSFAIL*
BERR*
SYSRESET*
LWORD*
AM5
A23
GND
SYSCLK
GND
DS1*
DS0*
WRITE*
GND
DTACK*
GND
AS*
GND
IACK*
IACKIN*
IACKOUT*
AM4
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
-
-
-
A22
A21
A20
A19
A18
A17
A16
A15
A14
A13
A12
A11
A10
A09
A08
+12 V
+5 V
AM0
AM1
AM2
AM3
GND
-
-
GND
IRQ7*
IRQ6*
IRQ5*
IRQ4*
IRQ3*
IRQ2*
IRQ1*
+5VSTBY
+5 V
A07
A06
A05
A04
A03
A02
A01
-12 V
+5 V
Figure A-1. P1 Pin Configuration
NOTE: BGINx tied directly to BGOUTx
A-1
PIN
1
2
3
4
5
6
7
8
C
B
A
CLK10+
CLK10-
GND
+5V
GND
RSV1
A24
A25
A26
A27
A28
A29
A30
A31
GND
+5V
D16
D17
D18
D19
D20
D21
D22
D23
GND
D24
D25
D26
D27
D28
D29
D30
D31
GND
+5V
ECLTRG0
-2V
ECLTRG1
GND
LBUSA00
LBUSA01
-5.2V
LBUSA02
LBUSA03
GND
LBUSA04
LBUSA05
-5.2V
LBUSA06
LBUSA07
GND
LBUSA08
LBUSA09
-5.2V
LBUSA10
LBUSA11
GND
TTLTRG0*
TTLTRG2*
+5V
TTLTRG4*
TTLTRG6*
GND
RSV2
MODID
GND
SUMBUS
-5.2V
LBUSC00
LBUSC01
GND
LBUSC02
LBUSC03
GND
LBUSC04
LBUSC05
-2V
LBUSC06
LBUSC07
GND
LBUSC08
LBUSC09
-5.2V
LBUSC10
LBUSC11
GND
TTLTRG1*
TTLTRG3*
GND
TTLTRG5*
TTLTRG7*
GND
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
RSV3
GND
+24V
-24V
Figure A-2. P2 Pin Configuration
A-2
PIN
1
D
-
C
BD08
B
-
A
BD00
Z
-
2
GND
BD09
-
BD01
GND
3
4
-
-
BD10
BD11
BACFAIL*
IN0*
BD02
BD03
-
GND
5
-
BD12
OUT0*
BD04
-
6
-
BD13
IN1*
BD05
GND
7
8
-
-
BD14
BD15
0UT1*
IN2*
BD06
BD07
-
GND
9
-
-
-
GND
0UT2*
IN3*
OUT3*
-
GND
BSYSCLK
-
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
BSYSFAIL*
BBERR*
BSYSRESET*
BLWORD*
BAM5
BA23
GND
-
GND
-
GND
-
GND
-
GND
-
GND
-
GND
+3.3V
BDS1*
BDS0*
BWRITE*
GND
BDTACK*
GND
-
-
-
-
+3.3V
-
+3.3V
BA22
BA21
BA20
BA19
BA18
BA17
BA16
BA15
BA14
BA13
BA12
BA11
BA10
BA09
BA08
+12 V
+5 V
BAM0
BAM1
BAM2
BAM3
GND
-
-
+3.3V
BAS*
GND
-
+3.3V
BIACK*
BIACKIN*
BIACKOUT*
BAM4
BA07
-
+3.3V
-
GND
-
GND
BIRQ7*
BIRQ6*
BIRQ5*
BIRQ4*
BIRQ3*
BIRQ2*
BIRQ1*
+5VSTBY
+5 V
-
GND
-
GND
-
GND
-
GND
+3.3V
-
BA06
BA05
BA04
BA03
BA02
BA01
-12 V
+5 V
+3.3V
-
+3.3V
-
+3.3V
GND
-
-
GND
Figure A-3. J1 Pin Configuration
NOTES:
1. INx tied directly to OUTx.
2. +3.3V supplied on Version -0001 only
A-3
PIN
1
2
3
4
5
6
7
8
D
-
-
-
-
-
-
-
-
-
-
-
-
-
-
-
C
B
+5V
A
Z
-
GND
-
GND
-
GND
-
GND
-
GND
-
CLK10+n
CLK10-n
GND14
BECLTRG0
-2V2
BECLTRG1
GND13
LBUSA00n
LBUSA01n
-5.2V4
LBUSA02n
LBUSA03n
GND11
LBUSA04n
LBUSA05n
-5.2V3
LBUSA06n
LBUSA07n
GND
RSV1
BA24
BA25
BA26
BA27
BA28
BA29
BA30
BA31
GND
+5V
-5.2V5
LBUSC00n
LBUSC01n
GND12
LBUSC02n
LBUSC03n
GND10
LBUSC04n
LBUSC05n
-2V1
LBUSC06n
LBUSC07n
9
10
11
12
13
14
15
GND
-
GND
-
BD16
BD17
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
31
32
-
-
-
-
-
-
-
-
-
-
-
-
-
-
GND08
LBUSC08n
LBUSC09n
-5.2V1
LBUSC10n
LBUSC11n
GND06
BTTLTRG1*
BTTLTRG3*
GND05
BTTLTRG5*
BTTLTRG7*
GND03
BD18
BD19
BD20
BD21
BD22
BD23
GND
BD24
BD25
BD26
BD27
BD28
BD29
BD30
BD31
GND
+5V
GND09
LBUSA08n
LBUSA09n
-5.2V2
LBUSA10n
LBUSA11n
GND07
BTTLTRG0*
BTTLTRG2*
+5Vn
BTTLTRG4*
BTTLTRG6*
GND04
GND
-
GND
-
GND
-
GND
-
GND
-
GND
-
GND
-
GND
RSV3n
GND02
+24Vn
-24Vn
RSV2n
MODIDn
GND01
BSUMBUSn
-
GND
-
-
GND
Figure A-4. J2 Pin Configuration
NOTES:
1. Signals on Rows A & C are only connected, if the pass-through cable is installed.
2. +3.3V supplied on Version -0001 only
A-4
TO FRONT CONNECTOR J2
PIN
TO REAR CONNECTOR P2
PIN
PIN
1
3
PIN
1
3
-24Vn
+24Vn
2
4
BSUMBUSn
GND01
-24V
+24V
2
4
BSUMBUS
GND
5
7
GND02
RSV3n
6
8
MODIDn
RSV2n
5
7
GND
RSV3
6
8
MODID
RSV2
9
GND03
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
GND04
9
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
GND
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
BTTLTRG7*n
BTTLTRG5*n
GND05
BTTLTRG3*n
BTTLTRG1*n
GND06
LBUSC11n
LBUSC10n
-5.2V1
LBUSC09n
LBUSC08n
GND08
LBUSC07n
LBUSC06n
-2V1
LBUSC05n
LBUSC04n
GND10
LBUSC03n
LBUSC02n
GND12
LBUSC01n
LBUSC00n
-5.2V5
BTTLTRG6*n
BTTLTRG4*n
+5Vn
BTTLTRG2*n
BTTLTRG0*n
GND07
LBUSA11n
LBUSA10n
-5.2V2
LBUSA09n
LBUSA08n
GND09
LBUSA07n
LBUSA06n
-5.2V3
LBUSA05n
LBUSA04n
GND11
LBUSA03n
LBUSA02n
-5.2V4
LBUSA01n
LBUSA00n
GND13
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
BTTLTRG7*
BTTLTRG5*
GND
BTTLTRG3*
BTTLTRG1*
GND
LBUSC11
LBUSC10
-5.2V
LBUSC09
LBUSC08
GND
LBUSC07
LBUSC06
-2V
LBUSC05
LBUSC04
GND
LBUSC03
LBUSC02
GND
LBUSC01
LBUSC00
-5.2V
BTTLTRG6*
BTTLTRG4*
+5V
BTTLTRG2*
BTTLTRG0*
GND
LBUSA11
LBUSA10
-5.2V
LBUSA09
LBUSA08
GND
LBUSA07
LBUSA06
-5.2V
LBUSA05
LBUSA04
GND
LBUSA03
LBUSA02
-5.2V
LBUSA01
LBUSA00
GND
GND14
CLK10-n
CLK10+n
BECLTRG1n
-2V2
BECLTRG0n
GND
CLK10-
CLK10+
BECLTRG1
-2V
BECLTRG0
Figure A-5. P2 Pin Configuration
A-5
A-6
N O T E S :
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