USER
MANUAL
MODEL 1065
Industrial Synchronous &
Asynchronous Short
Range Modem
Part# 07M1065-A
Doc# 058041UA
Revised 08/11/99
SALES OFFICE
(301) 975-1000
TECHNICAL SUPPORT
(301) 975-1007
An ISO-9001
Certified
Company
2.0 GENERAL INFORMATION
3.0 CONFIGURATION OVERVIEW
Thank you for your purchase of this Patton Electronics product.
This product has been thoroughly inspected by Patton's qualified tech-
nicians. If any questions or problems arise during installation or use of
this product, please do not hesitate to contact Patton Electronics
Technical Support at (301) 975-1007.
The Model 1065 is fairly simple to install and is ruggedly designed
for excellent reliability: just set it and forget it. The following instruc-
tions will help you set up and install the Model 1065 properly.
3.1 CONFIGURATION SWITCHES
2.1 FEATURES
The Model 1065 uses 24 external mini DIP switches that allow
configuration to an extremely wide range of applications. These 24
DIP switches are grouped into three eight-switch sets, and are exter-
nally accessible from the underside of the unit (see Figure 1). Since all
configuration DIP switches are externally accessible, there is no need
to open the case for configuration.
• Synchronous or asynchronous operation
• Model 1065 supports data rates up to 64.0 kbps
• Two-wire/half duplex or four-wire/full or half duplex
• V.52 & V.54 test modes
• Equalization
• Anti-streaming timer
• Distances up to 12 miles (19.2 km)
• Point-to-point or multipoint
• Internal, external or received loopback clocking
• 2000 VAC transformer isolation & high speed surge protection
• Internal power supply
The configuration switches allow you to select data rates, clocking
methods, V.52 & V.54 tests, word lengths, extended signaling rates,
async. or sync. mode, 2- or 4-wire operation, anti-stream control and
input impedance. The drawings, text and tables on the following pages
describe all switch locations, positions and functions.
• Mono-color LED indicators
2.2 DESCRIPTION
The Model 1065 Industrial Short Range Modem operates 2-wire
(half duplex) or 4-wire (full or half duplex), in synchronous or asyn-
chronous modes, over unconditioned telephone lines. The Model 1065
supports bit rates up to 64.0 kbps. The Model 1065 operates in syn-
chronous mode between the local and remote modems; when connect-
ed to an asynchronous RS-232 device, the Model 1065 SRM converts
the asynchronous data to synchronous data.
ON
S3
S2
S1
OFF
The Model 1065 has several features to enhance overall perform-
ance: equalization, anti-streaming timer, transformer isolation to guard
against data loss due to ground potential differences, and Silicon
Avalanche Diode surge protection to guard against data line transients.
The Model 1065 features V.52 compliant bit error rate pattern tests
and two V.54 test modes: local analog loopback and remote digital
loopback. The operator at the local end may test both local and
remote modems, plus the line, in the digital loopback mode. Both RDL
and LAL modes can be controlled by a manual switch or via the
V.24/RS-232 interface.
REAR
FRONT
Figure 1. Bottom view of Model 1065 Series, showing location of DIP switches
3
4
The Model 1065 SRM has three sets of eight switches, yielding 24
total DIP switches. The three sets will be referred to as S1, S2 and
S3. As Figure 2 shows, the orientation of all DIP switches is the same
with respect to “ON” and “OFF” positions.
Shown in the tables below are DIP Switch settings for Models
1065.
MODEL 1065 DATA RATE SETTINGS
S1-1
On
Off
On
Off
On
Off
On
Off
Off
On
Off
Off
On
Off
Off
S1-2
On
On
Off
Off
On
On
Off
Off
On
On
On
Off
On
On
On
S1-3
On
On
On
On
Off
Off
Off
Off
Off
On
On
Off
Off
Off
On
S1-4
On
On
On
On
On
On
On
On
On
Off
Off
On
Off
Off
Off
S3-3
Off
Off
Off
Off
Off
Off
Off
Off
On
Off
Off
On
Off
Off
On
Setting
1.2 kbps
1.8 kbps
2.4 kbps
3.6 kbps
4.8 kbps
7.2 kbps
9.6 kbps
14.4 kbps
16.0 kbps
19.2 kbps
28.8 kbps
32.0 kbps
38.4 kbps
57.6 kbps
64.0 kbps
ON
OFF
Figure 2. Close-up of DIP switches showing “ON” and “OFF” positions
*
*
3.2 CONFIGURATION SWITCH SET “S1”
The DIP switches on S1 set data rate, clock source, async./sync.
mode and carrier control method. The default settings are summarized
in the table below.
*
MODEL 1065 S1 SUMMARY TABLE
* Must have switch 3-3 On
Position
S1-1
S1-2
S1-3
S1-4
S1-5
S1-6
S1-7
S1-8
Function
Data Rate
Factory Default
Switches S1-5 and S1-6: Clock Source
On
Off
Off
On
On
On
On
Off
Data Rate
9,600 bps
Switches S1-5 and S1-6 are set in combination to determine the
transmit clock source for the Model 1065 Series.
Data Rate
}
Data Rate
S1-5
On
Off
S1-6
On
On
Setting
Clock Source
Clock Source
Async./Sync.
Carrier Control
Internal transmit clock
Receive recover clock
External transmit clock
Internal
}
On
Off
Async.
Constantly On
Switch S1-7: Asynchronous/Synchronous Mode
Switches S1-1 through S1-4 & S3-3: Data Rate Setting
The setting for switch S1-7 determines whether the Model 1065
Series is in asynchronous or synchronous operating mode.
Switches S1-1, S1-4, and S3-3 are set in combination to deter-
mine the asynchronous and synchronous data rate for the Model 1065.
S1-7
On
Off
Setting
Asynchronous
Synchronous
5
6
Switch S1-8: Carrier Control Method
Switch S2-3: Extended Signaling Rate
The setting for switch S1-8 determines whether the carrier is “con-
stantly on” or “controlled by RTS”. This setting allows for operation in
switched carrier, multipoint and/or hardware handshaking applications.
The setting for switch S2-3 determines the range of variability the
Model 1065 Series “looks for” in asynchronous data rates (i.e., the
actual variance from a given frequency level the Model 1065 Series will
tolerate).
S1-8
Off
On
Setting
Constantly on
Controlled by RTS
S2-3
Off
On
Setting
-2.5% to +1%
-2.5% to +2.3%
3.3 CONFIGURATION SWITCH SET “S2”
The DIP switches on S2 set word length, extended signaling rate,
RTS/CTS delay, V.52 and V.54 diagnostic test and 2- and 4-wire opera-
tion.
Switches S2-4 and S2-5: RTS/CTS Delay
The combined settings for switches S2-4 and S2-5 determine the
amount of delay between the time the unit “sees” RTS and when it
sends CTS. Options are no delay, 7 ms and 53 ms.
S2 SUMMARY TABLE
Position
S2-1
S2-2
S2-3
S2-4
S2-5
S2-6
S2-7
S2-8
Function
Word Length
Factory Default
S2-4
On
S2-5
On
Setting
7 ms
Off
10 bits
}
Word Length
Off
Off
On
53 ms
Extended Signaling Rate
RTS/CTS Delay
RTS/CTS Delay
2-Wire/4-Wire
2-Wire/4-Wire
V.54
Off -2.5% to 1%
On
Off
Off
Off
No delay
No delay
On
7 ms
}
On
On (4-Wire) FDX
Off (4-Wire) FDX
Off V.54 Enabled
Switch S2-6 & S2-7: 2-Wire/4-Wire Mode Selection
The setting for switch S2-6 and S2-7 determines whether the
Model 1065 Series is operating in 2-wire or 4-wire mode.
S2-6
On
On
S2-7
On
Off
Setting
Switches S2-1 and S2-2: Word Length
4-wire (half duplex)
4-wire (full duplex)
2-wire (half duplex)
Switches S2-1 and S2-2 are set in combination to determine the
word length for asynchronous data, including the start and stop bits.
Off
On
S2-1
Off
S2-2
On
Setting
8 bits
Switch S2-8: V.54 Loopback Test Enable
On
On
9 bits
This switch enables or disables V.54 looping in the Model 1065.
Off
On
Off
Off
10 bits
11 bits
S2-8
Off
On
Setting
V.54 Normal Operation Enabled
V.54 Testing Disabled
7
8
S3-1, S3-2 SELECTION TABLE FOR MODEL 1065
3.4 CONFIGURATION SWITCH SET “S3”
Data Rates, kb/s
Gauge of
Cable
The DIP switches on S3 set the anti-stream control, local loopback
enable, remote loopback enable and receive (input) impedance levels
for the Model 1065. Factory default positions of Switch S3 are shown
in the table below.
1.2 1.8 2.4 3.6 4.8 7.2 9.6 14.4 19.2 28.8 38.4 57.6
320 320 200 200 200 200 200 130 130 130 130 High
320 320 320 200 200 200 200 200 130 130 130 High
320 320 320 320 200 200 200 200 200 130 130 High
320 320 320 320 320 200 200 200 200 200 130 High
19AWG/.9mm
22AWG/.6mm
24AWG/.5mm
26AWG/.4mm
S3 SUMMARY TABLE
Position
S3-1
Function
Input Impedance
Input Impedance
Timing Mode
Factory Default
On
200 Ohms
}
S3-1, S3-2 SELECTION TABLE FOR MODEL 1065 (CONTINUED)
S3-2
Off
Data Rates, kb/s
Gauge of
Off
S3-3
S3-4
16
32
64
Topology
On Point to Point
Cable
130 130
200 130
200 130
200 200
High
High
High
High
S3-5
S3-6
S3-7
S3-8
Local Loopback
Remote Loopback
Anti-stream Control
Anti-stream Control
Off
Off
Off
Off
Disabled
Disabled
19AWG/.9mm
22AWG/.6mm
24AWG/.5mm
Disabled
}
26AWG/.4mm
Switch S3-3: Rate Selection
Switches S3-1 & S3-2: Input Impedance
Use Switch S3-3 to select the timing mode of the 1065. To oper-
ate the 1065 at 16, 32, or 64kbps, set S3-3 to the On position. To
select any other DTE rate, set Switch S3-3 Off.
The setting for Switches S3-1 and S3-2 determines the 1065
Series’ input impedance. This allows you to choose the optimum
impedance setting for your application. In long distance applications
the impedance of the cable must match the impedance of the load (or
resistor) of the Model 1065 Series unit. Thicker gauge cables requires
a lower Ohm setting, while a thinner gauge cable should receive a
higher Ohm setting. If you are using higher speeds you will need a
lower Ohm setting, and a higher Ohm setting for the slower speeds.
Refer to the table on the following page for assistance in selecting a
setting.
S3-3
On
Setting
16, 32, or 64kbps
Off
1.2 - 57kbps, excluding 16 kbps and 32kbps
Switch S3-4: Topology
Use switch S3-4 to select the topology of the Model 1065.
S3-1
On
On
S3-2
On
Off
Setting
130 Ohms
200 Ohms
320 Ohms
S3-4
On
On
Setting
Point to point
Master multi-point
Slave multi-point
Off
On
Off
Off
Off
High impedance (minimum 2k ohms)
9
10
Switch S3-5: RS-232 Initiation of Local Loopback Test
4.0 INSTALLATION
The setting for switch S3-5 determines whether or not the Model
1065 local analog loopback test can be initiated by raising pin 18 on
the RS-232 interface.
The Model 1065 operates in four twisted pair topologies:
2-wire/point-to-point, 2-wire/multipoint, 4-wire/point-to-point, and
4-wire/multipoint. In each of these topologies, the twisted pair wire
must be 19 - 26 AWG "dry", unconditioned metallic wire (see Appendix
C for wire recommendations). Dial-up analog circuits, such as those
used with a standard Hayes-type modem, are not acceptable. The
twisted pair may be shielded or unshielded. Both types yield favorable
results.
S3-5
On
Setting
RS-232 initiation enabled
RS-232 initiation disabled
Off
Switch S3-6: RS-232 Initiation of Remote Loopback Test
The Model 1065 offers an RJ-45 jack for its twisted pair line con-
nection. Figure 4 (below) shows the location of these interfaces on the
rear panel of the Model 1065 Series. Connect the wire to each Model
1065 Series as described in the instructions that follow the illustration.
The “+” and “-” indicators are for reference only.
The setting for switch S3-6 determines whether or not the Model
1065 remote digital loopback test can be initiated by raising pin 21 on
the RS-232 interface.
S3-6
On
Off
Setting
RS-232 initiation enabled
RS-232 initiation disabled
Switches S3-7 and S3-8: Anti-stream Control
Switches S3-7 and S3-8 are set in combination to determine the
time out period for the Model 1065 Series’ anti-stream control timer.
S3-7
Off
S3-8
Off
Setting
Disabled
Figure 4. Model 1065 rear panel.
Off
On
On
On
Off
On
12.5 seconds
50.0 seconds
12.5 seconds
4.1 TWO-WIRE INSTALLATION
When communicating over a single twisted pair circuit, the Model
1065 operates half duplex: that is, it transmits in only one direction at
a time. This method of operation is effective for both point-to-point and
multipoint applications.
In single pair point-to-point applications, you will need a pair of
Model 1065s for each circuit—one at each end of the single pair wire.
In single-pair multipoint applications you will need three or more Model
1065 units. These can be connected using a star topology, although a
daisy chain topology is usually used.
11
12
4.2 FOUR-WIRE INSTALLATION
4.1.1 Two-Wire Cable Connection Via RJ-45
When communicating over a two twisted pair circuit, the Model
1065 can operate full or half duplex, point-to-point or multipoint. In two
pair point-to-point applications, you will need a pair of Model 1065s for
each circuit—one at each end of the two pair cable. In two pair multi-
point applications you will need three or more Model 1065 units. These
can be connected using a star topology, although a daisy chain topolo-
gy is usually used.
A. The RJ-45 jack on a Model 1065 Series Short Range Modem is
prewired for a standard TELCO wiring environment. To be sure you
have the right wiring, use the table below as a guide.
RJ-45
SIGNAL
1 -------------NC
2 -------------GND†
3 -------------RCV
4 -------------XMT
5 -------------XMT
6 -------------RCV
7 -------------GND
8 -------------NC
4.2.1 Four-Wire Cable Connection Via RJ-45
A. The RJ-45 jack on a Model 1065 Short Range Modem is
prewired for a standard TELCO wiring environment. To be sure you
have the right wiring, use the table below as a guide.
RJ-45
SIGNAL
†Connection to ground is optional
1 -------------NC
2 -------------GND†
3 -------------RCV
4 -------------XMT
5 -------------XMT
6 -------------RCV
7 -------------GND
8 -------------NC
B. Proper wiring of pairs between the two modems is as follows:
SIGNAL PIN#
COLOR*
COLOR PIN#
SIGNAL
XMT
XMT
4
5
Green ------------Green
Red---------------Red
4
5
XMT
XMT
*Standard color codes—yours may be different
B. Proper crossing of pairs between the two modems is as fol-
lows:
C. AT&T standard modular color codes:
†Connection to ground is optional
1 - Blue
2 - Orange
3 - Black
4 - Red
5 - Green
6 - Yellow
7 - Brown
8 - Slate
SIGNAL PIN#
COLOR*
COLOR PIN#
SIGNAL
GND†
RCV
XMT
XMT
RCV
GND
2
3
4
5
6
7
Orange ----------Brown
7
5
6
3
4
2
GND
XMT
RCV
RCV
XMT
GND
Black -------------Green
Red---------------Yellow
Green ------------Black
Yellow------------Red
Brown------------Orange
*Standard color codes—yours may be different
†Connection to ground is optional
13
14
C. AT&T standard modular color codes:
4.3.1 Multipoint Twisted Pair Connection
The Model 1065 supports multipoint applications using a star topol-
ogy. Maximum distance between the units will vary based upon the
number of drops, data rate, wire gauge, etc. Call Patton Technical
Support for specific distance estimates. Figures 5 and 6 show how to
wire the one-pair and two-pair cables properly for a Model star topolo-
gy. Note that the ground connection is not needed.
1 - Blue
2 - Orange
3 - Black
4 - Red
5 - Green
6 - Yellow
7 - Brown
8 - Slate
4.3 FOUR-WIRE, MULTIPOINT INSTALLATION
Multipoint operation involves the connection of several terminals to
one host port. In such an application, one local Model 1065 is used as
a master unit, and it is connected to several remote Model 1065s that
are acting as slaves.
HOST
FIRST SLAVE
SECOND SLAVE
XMT-----------------------------RCV
------------------------------------------------------------------RCV
In a multipoint environment the master Model 1065 transmits con-
tinually. Initiation of two-way communication is RTS controlled by each
“slave” Model 1065 unit. To facilitate multipoint communication, the
master Model 1065 should have its carrier control DIP switch set to
“constantly ON” (S1-8=OFF). Each slave Model 1065 unit should have
its carrier control DIP switch set to “controlled by RTS” (S1-8=ON).
Figure 5 illustrates a typical Model 1065 multipoint application.
XMT-----------------------------RCV
------------------------------------------------------------------RCV
RCV-----------------------------XMT
------------------------------------------------------------------XMT
RCV-----------------------------XMT
------------------------------------------------------------------XMT
HOST
FIRST SLAVE
SECOND SLAVE
XMT-----------------------------XMT
------------------------------------------------------------------XMT
RCV-----------------------------XMT
------------------------------------------------------------------XMT
4.4 RS-232 CONNECTION
Connect the synchronous or asynchronous output of your RS-232
device to the DB-25 interface on the rear panel of the Model 1065.
Note: The Model 1065 is wired to connect to a DTE. If your RS-232
output device is DCE, call Patton Technical Support at: (301) 975-
for specific installation instructions.
Figure 5. Typical multipoint set-up
15
16
5.0 OPERATION
Once you have configured each Model 1065 Series unit properly
and connected the twisted pair and RS-232 cables (see Section 4.0),
you are ready to operate the units. This section describes reading the
LED status monitors, powering-up and using the built-in V.52 and V.54
test modes.
5.1.4 The “Error” Indicators
The “Error” indicator LED has two functions:
A. When the 1065 unit is in test mode (green “Test” LED is lit), the
error LED glows red when bit errors occur.
5.1 LED STATUS MONITORS
B. When not in test mode (green “Test” LED is off), the error LED
is used to indicate an RTS streaming condition. (See Section 5.2) for
information on the anti-streaming circuitry.
The Model 1065 Series features seven front panel status LEDs that
indicate the condition of the modem and communication link. Figure 5
shows the front panel location of each LED. Following Figure 6 is a
description of each LED's function.
5.2 ANTI-STREAMING ERROR INDICATOR
When not in test mode (green “Test” LED is off), the front panel
“Error” LED is used to indicate a streaming error. When the Model
1065s’ anti-streaming circuitry is enabled, the RTS signal from the DTE
is timer controlled. The timer begins to count when the DTE raises
RTS. If the time period that RTS remains high exceeds the preset time
out period, the anti-stream circuit will force RTS low. The “Error” LED
will light red, indicating a streaming condition (RTS continually on).
This feature prevents a malfunctioning terminal from tying-up a com-
puter port in a multi-drop or polling environment. When the DTE drops
RTS, the anti-streaming timer is automatically reset and the front panel
“Error” LED turns off. The time out period is DIP switch selectable for
12.5 or 50 seconds.
Model 1065 Industrial Short Range Modem
V.54 Test
Modes
Power
TX
RX
RTS
CD
Error
Test
511 -
- Remote
- Normal
- Local
511E -
Figure 6. Model 1065 front panel.
5.1.1 The “TD” and “RD” Indicators
The Power LED glows green to signal power present. The “TD” and
“RD” indicators blink green with data activity. Off indicates a low RS-
232 logic level, green indicates a high RS-232 logic level. Note: RS-
232 devices idle in a low state, so the LED will be off if the connections
are correct and the RS-232 device is in an idle state.
5.1.2 The “RTS” and “CD” Indicators
The “RTS” and “CD” indicators are monocolor and will be off for a
“low” signal or green for a “high” signal. RTS lights for an incoming
signal on RS-232 pin 4. CD lights for an incoming signal on the line
side, and the resulting output signal on RS-232 pin 8.
5.1.3 The “Test” Indicator
The yellow“Test” LED indicates that V.52 or V.54 tests are running.
17
18
5.3 POWER-UP
5.4.2 Remote Digital Loopback (RDL)
Apply AC power to the Model 1065 by plugging the separate AC
power cable first into the rear panel of the Model 1065 and then into an
acceptable AC power outlet. The remote/normal/loopback switch
should be set to “normal”. When the local and remote Model 1065 are
poweyellow up, and passing data normally, the following LED condi-
tions will exist:
The Remote Digital Loopback (RDL) test checks the performance
of both the local and remote Model 1065s and the communication link
between them. Any characters sent to the remote 1065 in this test
mode will be returned back to the originating device. For example,
characters typed on the keyboard of the local terminal will appear on
the local terminal screen after having been passed to the remote
Model 1065 and looped back. To perform an RDL test, follow these
steps:
• TD & RD = flashing on and off
• RTS & DCD = green
• TEST = off
A. Activate RDL. This may be done in two ways: By moving the
front panel toggle switch UP to "Remote" or by raising pin 21 on the
RS-232 interface (Note: Make sure DIP switch S3-6 is ON; and DIP
switch S2-6 is OFF).
5.4 V.54 TEST MODES
The Model 1065 offers two V.54 test modes to evaluate the condi-
tion of the modems and the communication link. These tests can be
activated physically from the front panel, or via the RS-232 interface.
Note: V.54 test modes are available for point-to-point applications only.
B. Perform a BER (bit error rate) 511/511E test on the system.
C. If the BER test equipment indicates a fault, and the Local
Analog Loopback test was successful for both Model 1065 Series
units, you may have a problem with the twisted pair line between the
modems. You should then test the twisted pair line for proper connec-
tions and continuity.
5.4.1 Local Analog Loopback (LAL)
The Local Analog Loopback (LAL) test checks the operation of the
local Model 1065 Series unit, and is performed separately on each
unit. Any data sent to the local Model 1065 in this test mode will be
echoed (returned) back to the user device. For example, characters
typed on the keyboard of a terminal will appear on the terminal screen.
To perform a LAL test, follow these steps:
5.4.3 Using the V.52 BER Test Independently
The V.52 BER test can be used independently of the V.54 loopback
tests. This requires two operators: one to initiate and monitor the test
at the local Model 1065, and one at the remote Model 1065. To use the
V.52 BER test by itself, both operators should simultaneously follow
these steps:
A. Activate LAL. This may be done in one of two ways: By mov-
ing the front panel toggle switch DOWN to "Local" or by raising pin 18
on the RS-232 interface (Note: Make sure DIP switch S2-6 is OFF,
and DIP switch S3-5 is ON). Once LAL is activated, the Model 1065s
transmit output is connected to its own receiver. The "test" LED should
be lit.
1. Locate the “511/511E” toggle switch on the front panel of the unit
and move it UP. This activates the V.52 BER test mode and trans-
mits a “511” test pattern to the other unit. If any errors are pres-
ent, the receiving modem's red “ERROR” LED will blink sporadi-
cally. Note: For this test to function, the “511” switch on both
Model 1065 units must be on.
B. Verify that the data terminal equipment is operating properly and
can be used for a test. If a fault is indicated, call a technician or
replace the unit.
2. If the test indicates no errors are present, move the V.52 toggle
switch DOWN, activating the “511/E” test with periodic errors pres-
ent. If the test is working properly, the receiving modem’s yellow
“ERROR” LED will blink regularly. A successful “511/E” test will
confirm that the link is in place, and that the Model 1065s’ built-in
“511” generator and detector are working properly.
C. Perform a BER (bit error rate) or 511/511E test on each unit. If
the BER test equipment indicates no faults, but the data terminal indi-
cates a fault, follow the manufacturer's checkout procedures for the
data terminal. Also, check the RS-232 interface cable between the ter-
minal and the Model 1065.
19
20
5.5 POWER-DOWN
APPENDIX A
Turn off the Model 1065 Series by simply unplugging the AC power
cord from the wall. There is no power switch.
PATTON ELECTRONIICS MODEL 1065 SPECIFICATIONS
Transmission Format:
Interface:
Synchronous or asynchronous, 2-
wire/half duplex, or 4-wire/full or half
duplex
RS-232 (CCITT V.24) connection via
DB-25 female; twisted pair connection
via RJ-45
Transmission Line:
Data Rates:
2 or 4-wire UTP, 19 - 26 AWG
Model 1065 - Synchronous or
asynchronous at 1.2, 1.8, 2.4, 3.6, 4.8,
7.2, 9.6, 14.4, 19.2, 28.8, 38.4, 57.6 and
64 kbps—switch selectable;
Clocking:
Controls:
Internal, external or receive recover
Carrier constantly “ON” or “controlled by
RTS”; RTS/CTS delay set to no
delay, 7 or 53 ms
Applications:
Indicators:
Point-to-point or multi-point
Mono-color LED indicators for TD, RD,
RTS & DCD; single LED indicators for
Power, Test, and Error
RTS Anti-stream Timer
Diagnostics:
12.5 sec., 50 sec., or disabled (switch
selectable); tolerance: +50%, -0
V.52 compliant bit error rate pattern
(511/511E pattern) generator and
detector with error injection mode;
V.54 compliant—Local Analog Loopback
and Remote Digital Loopback, activated
by front panel switch or via RS-232
interface
Transformer Isolation:
Surge Protection:
2000 V RMS
Immune to IEC-801-5 Level 2, 1kV
Temperature:
Humidity:
-10°C to 70°C
100% condensing from -10°C to +30°C
Absolute humidity from +30°C to +70°C
5.5” (W) X 7.5” (D) X 1.6” (H)
(13.9 cm X 19 cm X 4 cm)
157-242 VAC Universal Interface
Dimensions:
Power Supply:
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APPENDIX B
APPENDIX C
PATTON ELECTRONICS MODEL 1065
CABLE RECOMMENDATIONS
PATTON ELECTRONICS MODEL 1065 FACTORY REPLACEMENT
PARTS AND ACCESSORIES
All Patton Electronics Company Short Range Modems are tested to the
distances published in our Catalogs and Specification Sheets on twisted-
pair cable with the following characteristics:
Patton Model #
Description
0805FR............................France/Belgium Power Cord
07M1065 .........................Model 1065 Series User Manual
Wire Gauge
Capacitance
Resistance
19 AWG(.9mm) 83nF/mi or 15.72 pF/ft.
22 AWG(.6mm) 83nF/mi or 15.72 pF/ft.
24 AWG(.5mm) 83nF/mi or 15.72 pF/ft.
26 AWG(.4mm) 83nF/mi or 15.72 pF/ft.
.0163 ohms/ft.
.0326 ohms/ft.
.05165 ohms/ft.
.08235 ohms/ft.
We fully expect that the Short Range Modems will operate on lines
with specifications different from those tested, but to reduce the potential
difficulties in the field, one should ensure that the cable being used has
similar or better characteristics (lower capacitance or lower resistance).
M odel1065RC Distance Table -M iles (KM )
Data Rate
(kbps)
W ire Gauge (AW G/m m )
22 (.6m m ) 24 (.5m m ) 26 (.4m m )
1.2
1.8
11.9(19.2)
11.6(18.6)
11.1(18.0)
10.4(16.8)
9.7(15.5)
9.1(14.6)
7.6(12.2)
7.4(11.9)
7.2(11.6)
6.8(11.0)
6.0(9.6)
9.8(15.8)
8.7(14.0)
8.0(12.8)
7.6(12.2)
6.9(11.1)
6.6(10.7)
6.25(10.1)
5.2(8.4)
5.1(8.2)
4.9(7.9)
3.8(6.1)
3.6(5.8)
3.2(5.2)
2.7(4.3)
2.3(3.7)
7.2(11.6)
7.0(11.3)
6.6(10.7)
6.25(10.1)
5.9(9.4)
4.9(7.9)
4.5(7.3)
4.0(6.4)
3.8(6.1)
3.6(5.8)
3.0(4.9)
2.8(4.6)
2.2(3.7)
1.9(3.0)
1.3(2.1)
2.4
3.6
4.8
7.2
9.6
14.4
16
19.2
28.8
32
5.7(9.1)
38.4
57.6
64
4.7(7.6)
3.4(5.5)
2.5(4.0)
Wire with capacitance of 20pF/ft. or less is suitable for all our Short
Range Modems however, distances may vary from those published in our
catalog. Resistance will also affect distance but not functionality. Wire
should be 26 AWG (.4mm) or larger (smaller AWG#).
Patton products are designed to withstand normal environmental noise
and conditions however, other environmental factors too numerous to dis-
cuss in this format may affect proper operation of the SRM’s.
Selection of the proper SRM for an application is critical to maintaining
Customer Satisfaction and should be taken seriously. Certain models are
better suited for particular applications and environments than others.
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