XStream-PKG-R™ RS-232/485 RF Modem
Product Manual v5.x00
For XStream RF Modem Part Numbers:
X09-001PK…-R…
X09-009PK…-R…
X09-019PK…-R…
X24-009PK…-R...
X24-019PK…-R…
900 MHz and 2.4 GHz Stand-alone RF Modems by Digi International Inc.
XH9-001PK…-R...
XH9-009PK…-R…
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
XStream-PKG-R RS-232/485 RF Modem – Product Manual v5.x00
(Part number 90002211 B)
Revision
B
Date
Description
10/15//14
Minor changes and new part number
© 2014 Digi International Inc. All rights reserved.
Digi, Digi International Inc., the Digi logo, and XStream®
are trademarks or registered trademarks in the United
States and other countries worldwide. All other
trademarks mentioned in this document are the property
of their respective owners.
Information in this document is subject to change without
notice and does not represent a commitment on the part of
Digi International Inc. Digi provides this document “as is,”
without warranty of any kind, expressed or implied,
including, but not limited to, the implied warranties of
fitness or merchantability for a particular purpose. Digi
may make improvements and/or changes in this manual or
in the product(s) and/or the program(s) described in this
manual at any time.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
Contents
1. XStream RS-232/485 RF Modem
1.1. Features
1.1.1. Worldwide Acceptance
4
4
4
Antenna Usage
53
FCC-Approved Antennas
54
IC (Industry Canada) Certification
55
1.2. Specifications
5
Appendix B: Development Guide
56
1.3. External Interface
6
RS-232 Accessories Kit Contents
56
2. Interfacing Protocol
7
2.1. RS-232 Operation
2.1.1. DIP Switch Settings and Pin Signals
2.2. RS-485 (2-wire) Operation
2.2.1. DIP Switch Settings and Pin Signals
7
7
3. RF Modem Operation
3.1. Serial Communications
3.1.1. RS-232 and RS-485/422 Data Flow
9
59
Contact Digi
60
10
12
12
12
12
14
3.2.1. Idle Mode
14
3.2.2. Transmit Mode
14
3.2.3. Receive Mode
16
3.2.4. Sleep Modes
16
3.2.5. Command Mode
19
4. RF Modem Configuration
21
21
22
4.2.1. AT Commands
22
4.2.2. Binary Commands
23
4.3. Command Reference Table
24
4.4. Command Descriptions
25
5. RF Communication Modes
40
5.1. Addressing
41
5.1.1. Address Recognition
41
5.2. Basic Communications
42
5.2.1. Streaming Mode (Default)
42
5.2.2. Repeater Mode
43
5.3. Acknowledged Communications
46
5.3.1. Acknowledged Mode
46
5.3.2. Multi-Streaming Mode
48
Appendix A: Agency Certifications
FCC Certification
OEM Labeling Requirements
© 2014 Digi International Inc.
59
59
13
4.2. Programming Examples
Appendix C: Additional Information
Ordering Information
3.1.3. Flow Control
4.1. Automatic DIP Switch Configurations
58
1-Year Warranty
3.1.2. Host and RF Modem I/O Settings
3.2. Modes of Operation
57
Antennas
9
2.3. RS-485 (4-wire) and RS-422 Operation 10
2.3.1. DIP Switch Settings and Pin Signals
Adapters
52
52
53
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
1. XStream RS-232/485 RF Modem
The XStream-PKG-R RF Modem provides long range data
communications and advanced networking for OEMs and system
integrators. Out-of-box, the modem is equipped to sustain long range
wireless links between devices. Simply enter serial data into one
modem and the data surfaces on the other end of the wireless link.
The modem transfers a standard asynchronous serial data stream
between two or more modems. Its built-in RS-232/485/422 interfacing facilitates rapid
integration into existing data systems.
1.1. Features
Long Range
Easy-to-Use
9XStream-PKG-R (900 MHz) Range:
Out-of-Box RF Communications -
•
Indoor/Urban: up to 1500’ (450 m)
no configuration required
•
Outdoor line-of-sight: up to 7 miles (11 km)
w/ 2.1 dBm dipole antenna
External DIP Switch for configuring:
•
Outdoor line-of-sight: up to 20 miles (32 km)
w/ high gain antenna
24XStream-PKG-R (2.4 GHz) Range:
•
Indoor/Urban: up to 600’ (180 m)
•
Outdoor line-of-sight: up to 3 miles (5 km)
w/ 2.1 dBm dipole antenna
•
Outdoor line-of-sight: up to 10 miles (16 km)
w/ high gain antenna
Receiver Sensitivity: -110 dBm (900 MHz),
-105 dBm (2.4 GHz)
Advanced Networking and Security
True peer-to-peer (no “master” required),
point-to-point, point-to-multipoint, multidrop
Retries and Acknowledgements
7 hopping channels, each with over 65,000
available network addresses
• RS-232/485/422 support
(multidrop included)
• 2-wire (half-duplex) or 4-wire
RS-485/422 operation
• Parity options
7-18 VDC power supply
Simple AT and Binary commands for
programming the modem
Software-selectable serial
interfacing rates
MODBUS, CTS, RTS, DTR, DCD
(and more) I/O Support
XII™ Interference Blocking
Power-saving Sleep Modes
(as low as 6 mA)
FHSS (Frequency Hopping Spread Spectrum)
1.1.1. Worldwide Acceptance
FCC Certified (USA) - Refer to Appendix A for FCC Requirements.
Systems that contain XStream RF Modems automatically inherit Digi Certifications.
ISM (Industrial, Scientific and Medical) frequency band
Manufactured under ISO 9001:2000 registered standards
9XStream (900 MHz) RF Modems are approved for use in US, Canada, Australia and Israel
(and more).
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
1.2. Specifications
Table 1.1.
XStream-PKG-R RS-232/485 RF Modem Specifications
Specification
9XStream-PKG-R (900 MHz)
24XStream-PKG-R (2.4 GHz)
Indoor/Urban Range
Up to 1500’ (450 m)
Up to 600’ (180 m)
Outdoor LOS Range
Up to 7 miles (11 km) w/ dipole antenna
Up to 20 miles (32 km) w/ high-gain antenna
Up to 3 miles (5 km) w/ dipole antenna
Up to 10 miles (16 km) w/ high-gain antenna
Transmit Power Output
100 mW (20 dBm)
50 mW (17 dBm)
Interface Data Rate
125 – 65,000 bps (software selectable)
125 – 65,000 bps (software selectable)
Throughput Data Rate
9,600 bps
19,200 bps
9,600 bps
19,200 bps
RF Data Rate
10,000 bps
20,000 bps
10,000 bps
20,000 bps
Receiver Sensitivity
-110 dBm
-107 dBm
-105 dBm
-102 dBm
Performance
Power Requirements
Supply Voltage
7-18 VDC
7-18 VDC
Receive Current
70 mA
90 mA
Transmit Current
170 mA
180 mA
Pin Sleep Power-Down
6 mA
6 mA
Frequency
902-928 MHz
2.4000-2.4835 GHz
Spread Spectrum
Frequency Hopping, Wide band FM modulator
Frequency Hopping, Wide band FM modulator
Network Topology
Peer-to-Peer, Point-to-Multipoint, Point-to-Point, Multidrop
Peer-to-Peer, Point-to-multipoint, Point-to-Point, Multidrop
Channel Capacity
7 hop sequences share 25 frequencies
7 hop sequences share 25 frequencies
Data Connection
DB-9
DB-9
Enclosure
7.1 oz. (200g), Extruded aluminum, black anodized
7.1 oz. (200g), Extruded aluminum, black anodized
Enclosure Size
2.750” x 5.500” x 1.125”
(6.99cm x 13.97” x 2.86cm)
2.750” x 5.500” x 1.125”
(6.99cm x 13.97” x 2.86cm)
Operating Temperature
0 to 70º C (commercial), -40 to 85º C (industrial)
0 to 70º C (commercial), -40 to 85º C (industrial)
Type
½ wave dipole whip, 6.75” (17.1 cm), 2.1 dBi Gain
½ wave dipole whip, 5.25” (13.3 cm), 2.1 dBi Gain
Connector
Reverse-polarity SMA
Reverse-polarity SMA
Impedance
50 ohms unbalanced
50 ohms unbalanced
General
Physical Properties
Antenna
Certifications (Refer to www.digi.com for additional certifications)
FCC Part 15.247
OUR9XSTREAM
OUR-24XSTREAM
Industry Canada (IC)
4214A-9XSTREAM
4214A 12008
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
1.3. External Interface
1.1a. Power Switch
Figure 1.1. Front View
Move the Power Switch to the on (up) position to power the
Interface Board. DIP Switch (1.2a] settings are only read
during a power-up sequence.
1.1b. I/O and Power LEDs
The LED indicators visualize diagnostic status information. The
modem’s status is represented as follows:
Yellow (top LED) = Serial Data Out (to host)
1.1a.
Power
Switch
Green (middle) = Serial Data In (from host)
1.1c. DB-9
Serial Port
1.1b. I/O and
Power LEDs
1.1d. Power
Connector
Red (bottom) = Power/TX Indicator (Red light is on when
powered, off briefly during RF transmission)
1.1c. Serial Port (DB-9 Connector)
Standard female DB-9 (RS-232) DCE connector – This connector
can be also used for RS-485 and RS-422 connections.
1.1d. Power Connector
7-18 VDC Power Connector (Center positive, 5.5/2.1mm) – Power
can also be supplied through Pin 9 of the DB-9 Serial Port.
1.2a. DIP Switch
Figure 1.2. Back View
The DIP Switch automatically configures the XStream RF Modem
to operate in different modes. Each time the modem is poweredon, intelligence inside the XIB-R interface board (inside the
modem) programs the modem according to the positions of the
DIP Switch. (See figure below for DIP Switch settings]
NOTE: In cases where AT Commands should not be sent each time
the RF Modem is powered-on, the processor must be disabled by
populating J7 on the interface board inside the modem (p21).
1.2b.
Config Switch
1.2a.
1.2c.
DIP Switch
Antenna Port
1.2b. Config (Configuration) Switch
The Configuration Switch provides an alternate way to enter “AT
Command Mode”. To enter “AT Command Mode” at the RF
modem’s default baud rate, hold the Configuration Switch down
while powering on the modem using the Power Switch (1.1a).
1.2c. Antenna Port
Figure 1.3. DIP Switch Settings
Port is a 50Ω RF signal connector for connecting to an external
antenna. The connector type is RPSMA (Reverse Polarity SMA) female.
The connector has threads on the outside of a
barrel and a male center conductor.
Refer to table in the “Automatic
DIP Switch Configurations” (p19]
section for more information about
configurations triggered by the
DIP Switch.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
2. Interfacing Protocol
The XStream-PKG-R RF Modem supports the following interfacing protocols:
• RS-232
• RS-485 (2-wire) Half-Duplex
• RS-485 (4-wire) and RS-422
2.1. RS-232 Operation
2.1.1. DIP Switch Settings and Pin Signals
Figure 2.1.
RS-232 DIP Switch Settings
Figure 2.2.
Pins used on the female RS-232 (DB-9)
Serial Connector
DIP Switch settings are read and applied
only while powering-on.
Table 2.1.
RS-232 Signals and their implementations on the XStream RF Modem
(Low-asserted signals are distinguished by horizontal line over pin name.)
DB-9 Pin
RS-232
Name
AT Command
Reference*
Description
Implementation
1
DCD
DO3
Data-Carrier-Detect
Connected to DSR (pin6)
2
RXD
DO
Received Data
Serial data exiting the RF Modem (to host)
3
TXD
DI
Transmitted Data
Serial data entering into the RF modem (from host)
4
DTR
DI3
Data-Terminal-Ready
Can enable POWER-DOWN on the RF Modem
5
GND
-
Ground Signal
Ground
6
DSR
DO3
Data-Set-Ready
Connected to DCD (pin1)
7
/
CMD
DI2
Request-to-Send
Provides
flow control or
enables “Command Mode” on the RF Modem
DO2
Clear-to-Send
-
Ring Indicator
8
9
RI
Provides
flow control
Optional power input that is connected internally to
the positive lead of the front power connector
* Inside the XStream RF Modem is an XStream OEM RF Module. The names in this column refer to the pin
signals of the embedded RF module. XStream Commands (p24) used to configure pin behaviors are named
according to the pins of the module, not the RS-232 connection pins.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
Wiring Diagram: RS-232 DTE Device to a DCE RF Modem
Figure 2.3. RS-232 DTE (male connector) device wired to an XStream RF Modem (female connector)
Wiring Diagram: DCE RF Modem to an RS-232 DCE Device
Figure 2.4. XStream RF Modem (female connector) wired to an RS-232 DTE (male connector) device
Sample Wireless Connection: DTE DCE
DCE DCE
Figure 2.5. Typical wireless link between DTE and DCE devices
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
2.2. RS-485 (2-wire) Operation
2.2.1. DIP Switch Settings and Pin Signals
Figure 2.6.
RS-485 (2-wire) Half-Duplex
DIP Switch Settings
Figure 2.7.
Pins used on the female RS-232 (DB-9)
Serial Connector
Figure 2.8.
RS-485 (2-wire) with Termination (optional)
Termination is the 120 Ω resistor between T+ and T-.
DIP Switch settings are read and applied only while powering-on.
Note:
Refer to Figures 2.15 and 2.16 for RJ-45 connector pin designations used in
RS-485/422 environments.
Table 2.2.
RS-485 (2-wire half-duplex) Signals and their implementations on the XStream RF Modem
DB-9 Pin
RS-485 Name
Description
Implementation
2
T/R- (TRA)
Negative Data Line
Transmit serial data to and from the
XStream RF Modem
5
GND
Ground Signal
Ground
8
T/R+ (TRB)
Positive Data Line
Transmit serial data to and from the
XStream RF Modem
9
PWR
Power
Optional power input that is connected internally
to the front power connector
1, 3, 4, 6, 7
not used
Wiring Diagram: RS-485 (2-wire) Half-Duplex
Figure 2.9. XStream RF Modem in an RS-485 (2-wire) half-duplex environment
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
2.3. RS-485 (4-wire) and RS-422 Operation
2.3.1. DIP Switch Settings and Pin Signals
Figure 2.10.
RS-485 (4-wire) and RS-422
DIP Switch Settings
Figure 2.11.
Pins used on the female RS-232 (DB-9)
Serial Connector
Figure 2.12.
RS-485 (4-wire) and RS-422 with Termination (optional)
Termination is the 120 Ω resistor between T+ and T-.
DIP Switch settings are read and applied only while powering-on.
Table 2.3.
RS-485/422 (4-wire) Signals and their implementations with the XStream-PKG-R RF Modem
DB-9 Pin
RS-485/422
Name
Description
Implementation
2
T- (TA)
Transmit Negative
Data Line
Serial data sent from the XStream RF Modem
3
R- (RA)
Receive Negative
Data Line
Serial data received by the XStream RF Modem
5
GND
Signal Ground
Ground
7
R+ (RB)
Receive Positive
Data Line
Serial data received by the XStream RF Modem
8
T+ (TB)
Transmit Positive
Data Line
Serial data sent from the XStream RF Modem
9
PWR
Power
Optional power input that is connected internally
to the front power connector
1, 4, 6
not used
Wiring Diagram: RS-485 (4-wire) Half-Duplex
Figure 2.13.
© 2014 Digi International Inc.
XStream RF Modem in an RS-485 (4-wire) environment
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
Wiring Diagram: RS-422
Figure 2.14.
XStream RF Modem in an RS-485 (4-wire) environment
RS-485/422 Connection Guidelines
The RS-485/422 protocol provides a solution for wired communications that can tolerate high
noise and push signals over long cable lengths. RS-485/422 signals can communicate as far as
4000 feet (1200 m). RS-232 signals are suitable for cable distances up to 100 feet (30.5 m).
RS-485 offers multi-drop capability in which up to 32 nodes can be connected. The RS-422
protocol is used for point-to-point communications.
Suggestions for integrating the XStream Modem with the RS-485/422 protocol:
1.
When using Ethernet twisted pair cabling: Select wires so that T+ and T- are connected to
each wire in a twisted pair. Likewise, select wires so that R+ and R- are connected to a
twisted pair. (For example, tie the green and white/green wires to T+ and T-.)
2.
For straight-through Ethernet cable (not cross-over cable) – The following wiring pattern
works well: Pin3 to T+, Pin4 to R+, Pin5 to R-, Pin6 to T-
3.
Note that the connecting cable only requires 4 wires (even though there are 8 wires).
4.
When using phone cabling (RJ-11) – Pin2 in the cable maps to Pin3 on opposite end of cable
and Pin1 maps to Pin4 respectively.
Figure 2.15.
Male (yellow) DB-9 to RJ-45 Adapters
Figure 2.16.
Female (green) DB-9 to RJ-45 Adapters
An RS-232 Accessories Kit is available that includes connectors that facilitate RS-232/485/422
and other serial communications. Refer to the Development Guide in Appendix B for information
concerning the connectors and tools included in the kit.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
3. RF Modem Operation
3.1. Serial Communications
3.1.1. RS-232 and RS-485/422 Data Flow
Devices that have a UART interface can connect directly through the pins of the XStream Modem
as is shown in the figure below.
Figure 3.1. System Data Flow Diagram in a UART-interfaced environment
(Low-asserted signals distinguished with horizontal line over signal name.)
3.1.2. Host and RF Modem I/O Settings
Serial communications between a host and an XStream RF Modem are dependent upon having
matching baud rate, parity, stop bit and number of data bits settings. Failure to enter the modem
into AT Command Mode is most commonly due to baud rate mismatch. Refer to the table below
to ensure host serial port settings match those of the modem.
Table 3.1.
Parameter values critical to serial communications between the RF Modem and host
Parameter Setting
XStream RF Modem Default Parameter Value
Baud (Serial Data Rate)
9600 bps or 19200 baud (Factory-set RF data rates)
Number of Data Bits
8
(NB parameter = 0)
Parity
None
(NB parameter = 0)
Number of Stop Bits
1
(NB parameter = 0)
Both the XStream RF Modem and host (PC) settings can be viewed and adjusted using Digi’s
proprietary XCTU Software. Use the “PC Settings” tab to configure host settings. Use the
“Terminal” or “Modem Configuration” tabs to configure the RF Modem settings. Refer to the RF
Modem Configuration sections for more information (p21).
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
3.1.3. Flow Control
Figure 3.2. Internal Data Flow Diagram
(The five most commonly-used pin signals are shown.)
DI (Data In) Buffer and Flow Control
When serial data enters the XStream Modem through the DI Pin, then the data is stored in the DI
Buffer until it can be transmitted.
When the RO parameter threshold is satisfied (refer to Transmit Mode (p14) and Command
Descriptions (p25) sections for more information), the modem attempts to initialize an RF
connection. If the modem is already receiving RF data, the serial data is stored in the modem’s
DI Buffer. If the DI buffer becomes full, hardware or software flow control must be implemented
in order to prevent overflow (loss of data between the host and XStream RF Modem).
How to eliminate the need for flow control:
1.
Send messages that are smaller than the DI buffer size. The size of the DI buffer varies
according to the packet size and parity setting used.
2.
Interface at a lower baud rate (BD Command) than the fixed RF data rate.
Two cases in which the DI Buffer may become full and possibly overflow:
1.
If the serial interface data rate is set higher than the RF data rate of the modem, the modem
will receive data from the host faster than it can transmit the data over-the-air.
2.
If the modem is receiving a continuous stream of RF data or if the modem is monitoring data
on a network, any serial data that arrives on the DI pin is placed in the DI Buffer. The data in
the DI buffer will be transmitted over-the-air when the modem no longer detects RF data in
the network.
Hardware Flow Control (
). When the DI buffer is 17 bytes away from being full; by
default, the modem de-asserts (high)
to signal to the host device to stop sending data (refer
to the FT (Flow Control Threshold) and CS (DO2 Configuration) commands).
is re-asserted
after the DI Buffer has 34 bytes of memory available.
Software Flow Control (XON). XON/XOFF software flow control can be enabled using the FL
(Software Flow Control) Command. This option only works with ASCII data.
DO (Data Out) Buffer and Flow Control
When RF data is received, the data enters the DO buffer and is then sent out the serial port to a
host device. Once the DO Buffer reaches capacity, any additional incoming RF data is lost.
Two cases in which the DO Buffer may become full and possibly overflow:
1.
If the RF data rate is set higher than the interface data rate of the modem, the modem will
receive data from the transmitting modem faster than it can send the data to the host.
2.
If the host does not allow the modem to transmit data out from the DO buffer because of
being held off by hardware or software flow control.
Hardware Flow Control (
). If
is enabled for flow control (RT Parameter = 2), data will
not be sent out the DO Buffer as long as
is de-asserted.
Software Flow Control (XOFF). XON/XOFF software flow control can be enabled using the FL
(Software Flow Control) Command. This option only works with ASCII data.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
3.2. Modes of Operation
XStream RF Modems operate in five modes.
Figure 3.3. XStream Modes of Operation
Modem can only be in one mode at a time.
3.2.1. Idle Mode
When not receiving or transmitting data, the modem is in Idle Mode. The modem uses the same
amount of power in Idle Mode as it does in Receive Mode.
The modem shifts into the other modes of operation under the following conditions:
• Serial data is received in the DI Buffer (Transmit Mode)
• Valid RF data is received through the antenna (Receive Mode)
• Command Mode Sequence is issued (Command Mode)
• Sleep Mode condition is met (Sleep Mode)
After responding to any of the preceding conditions, the modem automatically transitions back
into Idle Mode.
3.2.2. Transmit Mode
Note: RF reception must
complete before the
modem is able to enter
into Transmit Mode.
When the first byte of serial data is received from the UART in the DI buffer, the modem
attempts to shift to Transmit Mode and initiate an RF connection with other modems. After
transmission is complete, the modem returns to Idle Mode.
RF transmission begins after either of the following criteria is met:
1.
RB bytes have been received in the DI buffer and are pending for RF transmission (refer to
RB (Packetization Threshold) command, p34).
The RB parameter may be set to any value between 1 and the RF packet size (PK), inclusive.
When RB = 0, the packetization threshold is ignored.
2.
At least one character has been received in the DI buffer (pending for RF transmission) and
RO time has been observed on the UART (refer to RO (Packetization Timeout) command).
The timeout can be disabled by setting RO to zero. In this case, transmission will begin after
RB bytes have been received in the DI buffer.
After either RB or RO conditions are met, the modem then initializes a communications channel.
(Channel initialization is the process of sending an RF initializer that synchronizes receiving
modems with the transmitting modem. During channel initialization, incoming serial data
accumulates in the DI buffer.)
Serial data in the DI buffer is grouped into RF packets (refer to PK (RF Packet Size)); converted
to RF data; then transmitted over-the-air until the DI buffer is empty.
RF data, which includes the payload data, follows the RF initializer. The payload includes up to
the maximum packet size (PK Command) bytes. As the transmitting modem nears the end of the
transmission, it inspects the DI buffer to see if more data exists to be transmitted. This could be
the case if more than PK bytes were originally pending in the DI buffer or if more bytes arrived
from the UART after the transmission began. If more data is pending, the transmitting modem
assembles a subsequent packet for transmission.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
Figure 3.4. Data Transmission Sequence
RF Data Packet
The RF packet is the sequence of data used for communicating information between Digi
Modems. An RF Packet consists of an RF Initializer and RF Data.
Figure 3.5. RF Data Packet Components
* When streaming multiple RF packets, the RF Initializer is only sent in front of the first packet.
RF Initializer
An RF initializer is sent each time a new connection sequence begins. The RF initializer contains
channel information that notifies receiving modems of information such as the hopping pattern
used by the transmitting modem. The first transmission always sends an RF initializer.
An RF initializer can be of various lengths depending on the amount of time determined to be
required to prepare a receiving modem. For example, a wake-up initializer is a type of RF
initializer used to wake remote modems from Sleep Mode (Refer to the FH, LH, HT and SM
Commands for more information). The length of the wake-up initializer should be longer than the
length of time remote modems are in cyclic sleep.
Header
The header contains network addressing information that filters incoming RF data. The receiving
modem checks for a matching Hopping Channel (HP parameter), Vendor Identification Number
(ID parameter) and Destination Address (DT parameter). Data that does not pass through all
three network filter layers is discarded.
CRC (Cyclic Redundancy Check)
To verify data integrity and provide built-in error checking, a 16-bit CRC (Cyclic Redundancy
Check) is computed for the transmitted data and attached to the end of each RF packet. On the
receiving end, the receiving modem computes the CRC on all incoming RF data. Received data
that has an invalid CRC is discarded (Refer to the Receive Mode section, next page).
© 2014 Digi International Inc.
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3.2.3. Receive Mode
If the modem detects RF data while in Idle Mode, the modem transitions into Receive Mode to
receive RF packets. Once a packet is received, the modem checks the CRC to ensure that the
data was transmitted without error. If the CRC data bits on the incoming packet are invalid, the
packet is discarded. If the CRC is valid, the packet proceeds to the DO Buffer.
The modem returns to Idle Mode when valid RF data is no longer detected or after an error is
detected in the received RF data.
Figure 3.6. Data Reception Sequence
Refer to the Addressing section (p41) of the
RF Communication Modes chapter for more information
regarding address recognition.
Note: If serial data exists in the DI buffer while the modem is in
Receive Mode, the UART data will be transmitted after the modem is
finished receiving the RF data and has returned to Idle Mode.
3.2.4. Sleep Modes
Sleep Modes enable the XStream Modem to operate at minimal power consumption when not in
use. Three Sleep Mode options are available:
• Pin Sleep (Host Controlled)
• Serial Port Sleep (Wake on Serial Port activity)
• Cyclic Sleep (Wake on RF activity)
For the modem to transition into Sleep Mode, the modem must have a non-zero SM (Sleep Mode)
parameter and one of the following must occur:
1.
The modem is idle (no data transmission or reception) for a user-defined period of time
(Refer to the ST (Time before Sleep) command).
2.
SLEEP pin is asserted (only for Pin Sleep option).
In Sleep Mode, the modem will not transmit or receive data until the modem first transitions to
Idle Mode. All Sleep Modes are enabled and disabled using SM Command. Transitions into and
out of Sleep Modes are triggered by various mechanisms as shown in the table below.
Table 3.2.
Summary of Sleep Mode Configurations
Sleep Mode
Setting
Pin Sleep
(SM = 1)
Serial Port Sleep
(SM = 2)
Cyclic Sleep
(SM = 3-8)
Transition into
Sleep Mode
A microcontroller can shut down and wake
modems by asserting (high) SLEEP pin.
Note: The modem will complete a
transmission or reception before activating
Pin Sleep.
Automatic transition to Sleep Mode occurs
after a user-defined period of inactivity (no
transmitting or receiving of data). The
period of activity is defined using the ST
(Time before Sleep) Command.
Automatic transition to Sleep Mode occurs
in cycles as defined by the SM (Sleep
Mode) Command.
Transition out of
Sleep Mode
Related
Commands
Typical Power
Consumption
De-assert SLEEP pin. SM
6 mA
When serial byte is
SM, ST
received on the DI pin.
25 mA
After the cyclic sleep
time interval elapses.
Note: Modem can be
Note: The cyclic sleep time interval must be forced into Idle Mode
shorter than the “Wake-up Initializer Timer” if PW (Pin Wake-up)
(set by LH Command).
Command is issued.
SM, ST, HT, LH, 6 mA
PW
when sleeping
For more information about Sleep Modes, refer to the individual commands listed in “Related Commands”
column of the table. The SM command is central to all Sleep Mode configurations.
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Pin Sleep (SM = 1)
Pin Sleep requires the least amount of power. In order to achieve this state, the DI3 (SLEEP) pin
must be asserted (high). The modem remains in Pin Sleep until the DI3 pin is de-asserted.
After enabling Pin Sleep, the SLEEP pin controls whether the XStream Modem is active or in Sleep
Mode. When DI3 is de-asserted (low), the modem is fully operational. When DI3 is asserted
(high), the modem transitions to Sleep Mode and remains in its lowest power-consuming state
until the DI3 (SLEEP) pin is de-asserted. DI3 is only active if the modem is setup to operate in
this mode; otherwise the pin is ignored.
Once in Pin Sleep Mode, DO2 (
) is de-asserted (high), indicating that data should not be sent
to the modem. The PWR pin is also de-asserted (low) when the modem is in Pin Sleep Mode.
Note: The modem will complete a transmission or reception before activating Pin Sleep.
Serial Port Sleep (SM = 2)
Serial Port Sleep is a Sleep Mode in which the XStream Modem runs in a low power state until
serial data is detected on the DI pin.
When Serial Port Sleep is enabled, the modem goes into Sleep Mode after a user-defined period
of inactivity (no transmitting or receiving of data). This period of time is determined by ST (Time
before Sleep) Command. Once a character is received through the DI pin, the modem returns to
Idle Mode and is fully operational.
Cyclic Sleep (SM = 3-8)
Cyclic Sleep is the Sleep Mode in which the XStream Modem enters into a low-power state and
awakens periodically to determine if any transmissions are being sent.
When Cyclic Sleep settings are enabled, the XStream Modem goes into Sleep Mode after a userdefined period of inactivity (no transmission or reception on the RF channel). The user-defined
period is determined by ST (Time before Sleep) Command.
While the modem is in Cyclic Sleep Mode, DO2 (
) is de-asserted (high) to indicate that data
should not be sent to the modem during this time. When the modem awakens to listen for data,
DO2 is asserted and any data received on the DI Pin is transmitted. The PWR pin is also deasserted (low) when the modem is in Cyclic Sleep Mode.
The modem remains in Sleep Mode for a user-defined period of time ranging from 0.5 seconds to
16 seconds (SM Parameters 3 through 8). After this interval of time, the modem returns to Idle
Mode and listens for a valid data packet for 100 ms. If the modem does not detect valid data (on
any frequency), the modem returns to Sleep Mode. If valid data is detected, the modem
transitions into Receive Mode and receives incoming RF packets. The modem then returns to
Sleep Mode after a Period of inactivity that is determined by ST “Time before Sleep” Command.
The modem can also be configured to wake from cyclic sleep when SLEEP/DI3 is de-asserted
(low). To configure a modem to operate in this manner, PW (Pin Wake-up) Command must be
issued. Once DI3 is de-asserted, the modem is forced into Idle Mode and can begin transmitting
or receiving data. It remains active until no data is detected for the period of time specified by
the ST Command, at which point it resumes its low-power cyclic state.
Note: The cyclic interval time defined by SM (Sleep Mode) Command must be shorter than the interval
time defined by LH (Wake-up Initializer Timer).
For example: If SM=4 (Cyclic 1.0 second sleep), the LH Parameter should equal 0x0B (“1.1” seconds).
With these parameters set, there is no risk of the receiving modem being asleep for the duration of
wake-up initializer transmission. “Cyclic Scanning” explains in further detail the relationship between
“Cyclic Sleep” and “Wake-up Initializer Timer”
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Cyclic Scanning. Each RF transmission consists of an RF Initializer and payload. The wake-up
initializer contains initialization information and all receiving modems must wake during the
wake-up initializer portion of data transmission in order to be synchronized with the transmitting
modem and receive the data.
Figure 3.7. Correct Configuration (LH > SM)
Length of the wake-up initializer exceeds the time interval of Cyclic Sleep. The receiver is guaranteed to detect
the wake-up initializer and receive the accompanying payload data.
Figure 3.8. Incorrect Configuration (LH < SM)
Length of wake-up initializer is shorter than the time interval of Cyclic Sleep. This configuration is vulnerable
to the receiver waking and missing the wake-up initializer (and therefore also the accompanying payload data).
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3.2.5. Command Mode
To modify or read modem parameters, the modem must first enter into Command Mode, the
state in which incoming characters are interpreted as commands. Two command types are
available for programming the modem:
• AT Commands
• Binary Commands
For modified parameter values to persist in the modem registry, changes must be saved to nonvolatile memory using WR (Write) Command. Otherwise, parameters are restored to previously
saved values when the modem is powered off and then on again.
AT Commands
To Enter AT Command Mode:
1.
Send the 3-character command sequence “+++” and observe guard times before and after
the command characters. (Refer to the “Default AT Command Mode Sequence” below.) The
“Terminal” tab (or other serial communications software) of the XCTU Software can be used
to enter the sequence.
(OR)
2.
Assert (low) the
pin and turn the power going to the modem off and back on. This
result can be achieved by keeping the configuration switch pressed while turning off, then on
again the power supplying the RF Modem)
Default AT Command Mode Sequence (for transition to Command Mode):
• No characters sent for one second (refer to the BT (Guard Time Before) Command)
• Input three plus characters (“+++”) within one second (refer to the CC (Command
Sequence Character) Command.)
• No characters sent for one second (refer to the AT (Guard Time After) Command.)
To Send AT Commands:
Send AT commands and parameters using the syntax shown below:
Figure 3.9. Syntax for sending AT Commands
NOTE: To read a parameter value stored in a register, leave the parameter field blank.
The preceding example would change the modem Destination Address to “1F”. To store the new
value to non-volatile (long term) memory, the Write (ATWR) Command must follow.
System Response. When a command is sent to the modem, the modem will parse and execute
the command. Upon successful execution of a command, the modem returns an “OK” message. If
execution of a command results in an error, the modem returns an “ERROR” message.
To Exit AT Command Mode:
1.
Send ATCN (Exit Command Mode) Command.
(OR)
2.
If no valid AT Commands are received within the time specified by CT (Command Mode
Timeout) Command, the Modem automatically returns to Idle Mode.
For examples that illustrate the steps of programming the modem using AT Commands, refer to
the RF Modem Configuration (p21) chapter.
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Binary Commands
Sending and receiving parameter values using binary commands is the fastest way to change
operating parameters of the XStream RF Modem. Binary commands are used most often to
sample signal strength (RS parameter) and/or error counts; or change modem addresses and
channels for polling data systems. Since the sending and receiving of register values takes place
through the same serial data path as “live” data (received RF payload), interference between the
two types of data can be a concern.
Common questions about using binary commands:
• What are the implications of asserting CMD while live data is being sent or received?
• After sending serial data, is there a minimum time delay before CMD can be asserted?
• Is a delay required after CMD is de-asserted before payload data can be sent?
• How does one discern between live data and data received in response to a command?
The CMD pin must be asserted in order to send binary commands to the RF modem. The CMD pin
can be asserted to recognize binary commands anytime during the transmission or reception of
data. The status of the CMD signal is only checked at the end of the stop bit as the byte is shifted
into the serial port. The application does not allow control over when data is received, except by
waiting for dead time between bursts of communication.
If the command is sent in the middle of a stream of payload data to be transmitted, the
command will essentially be executed in the order it is received. If the radio is continuously
receiving data, the radio will wait for a break in the received data before executing the command.
The
signal will frame the response coming from the binary command request (Figure 3.10).
A minimum time delay of 100 µs (after the stop bit of the command byte has been sent) must be
observed before the CMD pin can be de-asserted. The command executes after all parameters
associated with the command have been sent. If all parameters are not received within 0.5
seconds, the modem returns to Idle Mode.
Note: When parameters are sent, they are two bytes long with the least significant byte sent first.
Binary commands that return one parameter byte must be written with two parameter bytes.
Refer to p23 for a binary programming example.
Commands can be queried for their current value by sending the command logically ORed (bitwise) with the value 0x80 (hexadecimal) with CMD asserted. When the binary value is sent (with
no parameters), the current value of the command parameter is sent back through the DO pin.
Figure 3.10. Binary Command Write then Read
Signal #4 is CMD
Signal #1 is the DIN signal to the radio
Signal #2 is the DOUT signal from the radio
Signal #3 is
In this graph, a value was written to a register and
then read out to verify it. While not in the middle
of other received data, note that the
(DO2
pin) signal outlines the data response out of the
modem.
IMPORTANT:
For the XStream Modem to recognize a binary command, the RT (DI2
Configuration) parameter must be set to one. If binary programming is not
enabled (RT ≠ 1), the modem will not recognize that the CMD pin is asserted and
therefore will not recognize the data as binary commands.
© 2014 Digi International Inc.
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4. RF Modem Configuration
4.1. Automatic DIP Switch Configurations
Each time the RF Modem is powered-on, intelligence on the XIB-R Interface Board (RS-232/485
interfacing board located inside the RF Modem) sends AT Commands that program the RF Modem
based on positions of the DIP Switch. Automatic configurations that take place during the poweron sequence affect stored RF Modem parameter values as shown in the tables below.
Figure 4.1. RF Modem DIP Switch
Table 4.1.
RF Modem Power-up Options (J7 jumper and Config Switch)
Condition
Behavior
If J7 is populated
Processor is disabled and AT Commands are not sent to the RF Modem
If Config Switch is pressed
Processor is disabled and RF Modem enters into AT Command Mode
If J7 is NOT populated and Config Switch
is NOT pressed
Execute logic as shown in table below.
Table 4.2.
AT Commands Sent as result of DIP Switch Settings (SW = DIP Switch)
Condition
Behavior
Restore Default Parameter Values of the RF Modem
If SW1 and SW2 are ON (up)
AT Commands sent:
ATRE (Restore Defaults) Command
ATWR (Write) Command
AT Commands sent:
ATCS 0 (RS-232 Operation: CTS function for CTS line,
DB-9 pin 8)
ATCD 2 (DO3 - RX LED = low)
ATCS 3 (RS-485 or RS-422 Operation)
ATCD 2 (DO3 - RX LED = low)
Serial Interfacing Options
If SW1 is ON (up)
If SW1 is OFF (down)
AT Commands sent:
Parity Options
If SW5 and SW6 are OFF (down)
If SW5 is OFF (down) and SW6 is ON
(up)
If SW5 is ON (up) and SW6 is OFF
(down)
If SW5 is ON (up) and SW6 is ON (up)
AT Commands sent:
ATNB 0 (parity = none)
AT Commands sent:
ATNB 1 (parity = even)
AT Commands sent:
ATNB 2 (parity = odd)
AT Commands sent:
ATNB 5 (parity = 9th bit data over-the-air, v4.30 only)
AT Commands sent:
ATCN (Exit AT Command Mode)
Exit AT Command Mode
Always
IMPORTANT: To avoid overwriting previously stored custom configurations (due to the automatic
configurations that take place each time the RF Modem is powered-on), it is necessary to disable a
processor located on the XIB-R interface board. To disable the processor, populate the J7 jumper of
the XIB-R Interface Board. By default, J7 is not populated.
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4.2. Programming Examples
For information about entering and exiting AT and Binary Command Modes, refer to the
Command Mode section (p19).
4.2.1. AT Commands
Digi has provided XCTU software for programming the modem using an extensive list of AT
Commands. The XCTU software provides an interface that is divided into four tabs that facilitate
the following functions:
• PC Settings tab - Setup PC serial port to interface with an XStream RF Modem
• Range Test tab – Test XStream RF Modem's range in varying environments
• Terminal tab – Configure and read XStream RF Modem parameters using AT Commands
• Modem Configuration tab – Configure and read RF Modem parameters
To install the XCTU Software:
Navigate to: www.digi.com/support/ . Then select “XCTU” under the product list. Select the
appropriate driver to install the XCTU software.
PC Settings Tab
As stated in the Serial Communications section; in order to communicate data to the RF modem
through the PC, baud (serial data rate), data bit, parity and stop bit settings on the PC serial port
must match those of the RF modem. The PC Settings tab provides a software user interface that
facilitates the modification of PC serial port settings.
PC Setup
1.
Set the DIP Switch to RS-232 mode. Switch 1 is ON (up) and the remaining 5 switches are
OFF (down).
2.
Connect the male DB-9 connector of the PC with the female DB-9 connector of the RF
modem using an RS-232 cable.
3.
Power the RF modem through the power connector.
4.
Launch XCTU Software and select the PC Settings tab; then select parameter values from the
dropdown lists that match the current parameter values of the RF modem.
(Refer to
Table 3.1 on for more information.)
Figure 4.2. RF Modem Configurations through a Serial Cable
Terminal Tab
A terminal program has been built into the XCTU software and is located under the Terminal tab.
The Terminal tab provides an easy-to-use interface for programming the modem.
Multiple AT Commands. Multiple AT commands can be entered on one line with one carriage
return at the end of the line. Each command must be delimited by a comma (spaces in between
are optional). The “AT” prefix is only sent before the first command and should not be included
with subsequent commands in a line.
System Response. When a command is sent to the modem, the modem will parse and execute
the command. Upon successful execution of a command, the modem returns an “OK” message. If
execution of a command results in an error, the modem returns an “ERROR” message.
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EXAMPLE: Restore RF Modem Defaults using the Terminal tab
The following steps show how to read currently stored modem parameter values; then restore
the modem parameters to their factory-default states.
Method 1 (One line per command)
Issue AT Command
+++
ATHP
ATRE
ATWR
ATCN
System Response
OK (Enter into AT Command Mode)
(system shows current channel number)
OK (Restore modem default parameter values)
OK (Write new values to non-volatile memory)
OK (Exit AT Command Mode)
Method 2 (Multiple commands on one line)
Issue AT Command
System Response
+++
OK
ATRE, WR, CN
OK
NOTE: Default parameter values of the RF modem can also be restored by selecting the “Restore
Defaults” button located on the Modem Configuration tab (refer to the instructions below).
Modem Configuration tab
The “Modem Configuration” tab of the XCTU software provides an easy-to-use interface for
reading and setting RF modem parameters.
EXAMPLE: Read Parameters and Restore Defaults using the Modem Configuration tab
The following steps show how to read currently stored modem parameter values; then restore
the modem parameters to their factory-default states.
1.
Open the XCTU program (Start --> Programs --> Digi --> XCTU):
2.
Under the “PC Settings” tab, select the PC Serial Com Port from the dropdown list that will be
used to connect to the RF Modem.
3.
Select a "Baud rate" to match the default RF data rate of the RF Modem. Use default values
for all other fields.
4.
Select the “Modem Configuration” tab.
5.
Select the “Read” button to read currently stored parameter values of the modem.
6.
Select the “Restore” button to restore factory-default parameter values.
7.
Select the “Write” button to save default values to non-volatile (long-term) memory.
4.2.2. Binary Commands
Example: Send Binary Commands
Example: Use binary commands to change the XStream Modem’s destination address to 0x1A0D
and save the new address to non-volatile memory.
1. RT Command must be set to “1” in AT Command Mode to enable binary programming.
2. Assert CMD (Pin is driven high).
(Enter Binary Command Mode)
3. Send Bytes (Parameter bytes must be 2 bytes long):
00
(Send DT (Destination Address) Command)
0D
(Least significant byte of parameter bytes)
1A
(Most significant byte of parameter bytes)
08
(Send WR (Write) Command)
4. De-assert CMD (Pin is driven low).
Note:
(Exit Binary Command Mode)
is high when command is being executed. Hardware flow control must be disabled as
will hold off parameter bytes.
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4.3. Command Reference Table
Table 4.1.
XStream Commands (The RF Modem expects numerical values in hexadecimal. “d” denotes decimal equivalent.)
AT
Command
AM v4.30*
AT
Binary
Command
0x3A (58d)
0x05 (5d)
BD v4.2B*
0x15 (21d)
Baud Rate
BK v4.30*
BO v4.30*
BT
CB v4.30*
CC
CD v4.2B*
CE v4.30*
CF v4.30*
CL v4.30*
CM v4.30*
CN
CO v4.30*
CS v4.27D*
CT
DC v4.30*
DR v4.30*
DT
E0
E1
ER
FH
FL
FT v4.27B*
GD
HP
HT
0x2E (46d)
0x30 (48d)
0x04 (4d)
0x33 (51d)
0x13 (19d)
0x28 (40d)
0x34 (52d)
0x35 (53d)
0x39 (57d)
0x38 (56d)
0x09 (9d)
0x2F (47d)
0x1F (31d)
0x06 (6d)
0x37 (55d)
0x2D (45d)
0x00 (0d)
0x0A (10d)
0x0B (11d)
0x0F (15d)
0x0D (13d)
0x07 (7d)
0x24 (36d)
0x10 (16d)
0x11 (17d)
0x03 (3d)
Serial Break Passing
Serial Break Timeout
Guard Time Before
Connection Duration Timeout
Command Sequence Character
DO3 Configuration
Connection Inactivity Timeout
Connection Failure Count
Last Connection Address
Connection Message
Exit AT Command Mode
DO3 Timeout
DO2 Configuration
Command Mode Timeout
Disconnect
DI3 Configuration
Destination Address
Echo Off
Echo On
Receive Error Count
Force Wake-up Initializer
Software Flow Control
Flow Control Threshold
Receive Good Count
Hopping Channel
Time before Wake-up Initializer
ID v4.2B*
0x27 (39d)
Modem VID
IU v4.30*
LH
MD v4.30*
MK
MY v4.30*
NB v4.30*
PC v4.22*
PK v4.30*
PW v4.22*
RB v4.30*
RE
RN v4.22*
RO v4.2A*
RP v4.2A*
RR v4.22*
RS v4.22*
RT
RZ v4.30*
SB v4.2B*
SH v4.27C*
SL v4.27C*
SM
ST
SY
TO v4.30*
TR v4.22*
TT v4.22*
VR
WR
0x3B (59d)
0x0C (12d)
0x32 (50d)
0x12 (18d)
0x2A (42d)
0x23 (35d)
0x1E (30d)
0x29 (41d)
0x1D (29d)
0x20 (32d)
0x0E (14d)
0x19 (25d)
0x21 (33d)
0x22 (34d)
0x18 (24d)
0x1C (28d)
0x16 (22d)
0x2C (44d)
0x36 (54d)
0x25 (37d)
0x26 (38d)
0x01 (1d)
0x02 (2d)
0x17 (23d)
0x31 (49d)
0x1B (27d)
0x1A (26d)
0x14 (20d)
0x08 (8d)
DI2, DI3 Update Timer
Wake-up Initializer Timer
RF Mode
Address Mask
Source Address
Parity
Power-up Mode
RF Packet Size
Pin Wake-up
Packetization Threshold
Restore Defaults
Delay Slots
Packetization Timeout
RSSI PWM Timer
Retries
RSSI
DI2 Configuration
DI Buffer Size
Stop Bits
Serial Number High
Serial Number Low
Sleep Mode
Time before Sleep
Time before Initialization
DO2 Timeout
Transmit Error Count
Streaming Limit
Firmware Version
Write
AT Command Name
Range
Command Category
Auto-set MY
Guard Time After
0x02 – 0xFFFF (x 100 msec)
Standard baud rates: 0 – 6
(custom rates also supported)
0–1
0 - 0xFFFF (x 1 second)
0 – 0xFFFF (x 100 msec)
0x01 – 0xFFFF (x 100 msec)
0x20 – 0x7F
0–4
0 – 0xFFFF (x 10 msec)
0 – 0xFFFF
(read-only)
0–1
0 - 0xFFFF (x 1 second)
0–4
0x02 – 0xFFFF (x 100 msec)
0–4
0 – 0xFFFF
0 – 0xFFFF
0–1
0 – 0xFF (bytes)
0 – 0xFFFF
0–6
0 – 0xFFFF (x 100 msec)
User-settable: 0x10 - 0x7FFF
Read-only: 0x8000 – 0xFFFF
0 - 0xFFFF (x 100 msec)
0 – 0xFF (x 100 msec)
0–4
0 – 0xFFFF
0 – 0xFFFF
0–5
0–1
0 - 0x100 (bytes)
0–1
0 - 0x100 (bytes)
0 – 0xFF (slots)
0 – 0xFFFF (x 200 µsec)
0 - 0x7F (x 100 msec)
0 – 0xFF
0x06 – 0x36 (read-only)
0-2
(read-only)
0-1
0 – 0xFFFF (read-only)
0 – 0xFFFF (read-only)
0–8
0x10 – 0xFFFF (x 100 msec)
0 – 0xFF (x 100 msec)
0 - 0xFFFF (x 1 sec)
0 – 0xFFFF
0 – 0xFFFF (0 = disabled)
0 x 0xFFFF (read-only)
-
Networking and Security
Command Mode Options
# Bytes
Returned
2
Serial Interfacing
2
Serial Interfacing
Serial Interfacing
Command Mode Options
Networking and Security
Command Mode Options
Serial Interfacing
Networking and Security
Networking and Security
Diagnostics
Networking and Security
Command Mode Options
Serial Interfacing
Serial Interfacing
Command Mode Options
Networking and Security
Serial Interfacing
Networking and Security
Command Mode Options
Command Mode Options
Diagnostics
Sleep (Low Power)
Serial Interfacing
Serial Interfacing
Diagnostics
Networking and Security
Sleep (Low Power)
1
2
2
2
1
1
2
2
2
1
2
1
2
1
2
2
1
2
2
1
2
Factory
Default
0x0A (10d)
factory-set
RF data rate
0
0
0x0A (10d)
0x28 (4d sec)
0x2B (“+”)
0
0x64 (1d sec)
0
0
0x03
0
0xC8 (200d)
0
0
0
0
varies
0
0
0xFFFF
Networking and Security
2
-
Serial Interfacing
Sleep (Low Power)
Networking and Security
Networking and Security
Networking and Security
Serial Interfacing
Command Mode Options
Serial Interfacing
Sleep (Low Power)
Serial Interfacing
(Special)
Networking and Security
Serial Interfacing
Diagnostics
Networking and Security
Diagnostics
Serial Interfacing
Diagnostics
Serial Interfacing
Diagnostics
Diagnostics
Sleep (Low Power)
Sleep (Low Power)
Networking and Security
Serial Interfacing
Diagnostics
Networking and Security
Diagnostics
(Special)
2
1
1
2
2
1
1
2
1
2
1
2
1
1
1
1
1
2
2
1
2
1
2
2
2
2
-
0x0A (10d)
0x01
0
0xFFFF
0xFFFF
0
0
0x40 (64d)
0
0x01
0
0
0
0
0
0
0
0x64 (100d)
0 (disabled)
0x03
0
0xFFFF
-
* Firmware version in which command and parameter options were first supported.
NOTE: AT Commands issued without a parameter value will return the currently stored parameter.
© 2014 Digi International Inc.
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4.4. Command Descriptions
Commands in this section are listed alphabetically. Command categories are designated between
the “< >” symbols that follow each command title. XStream Modems expect numerical values in
hexadecimal and those values are designated by a “0x” prefix.
AM (Auto-set MY) Command
AT Command: ATAM
AM Command is
Binary Command: 0x3A (58 decimal)
used to automatically set the MY (Source
Minimum firmware version required: 4.30
Address) parameter from the factory-set modem
serial number. The address is formed with bits 29, 28 and 13-0 of the serial number (in that
order).
AT (Guard Time After) Command
AT Command is used
to set the time-of-silence that follows the
command sequence character (CC Command). By
default, AT Command Mode will activate after one
second of silence.
Refer to the AT Commands section (p19) to view
the default AT Command Mode sequence.
AT Command: ATAT
Binary Command: 0x05 (5 decimal)
Parameter Range: 0x02 – 0xFFFF
(x 100 milliseconds)
Number of bytes returned: 2
Default Parameter Value: 0x0A (10 decimal)
Related Commands: BT (Guard Time Before),
CC (Command Sequence Character)
BD (Interface Data Rate) Command
BD Command allows the
user to adjust the UART interface data rate and
thus modify the rate at which serial data is sent
to the RF modem. The new baud rate does not
take effect until the CN command is issued. The
RF data rate is unaffected by the BD parameter.
Most applications will require one of the seven
standard baud rates; however, non-standard
baud rates are also supported.
Note: If the serial data rate is set to exceed the
fixed RF data rate of the modem,
flow control
may need to be implemented in the Flow Control
section (p13) of this manual.
AT Command: ATBD
Binary Command: 0x15 (21 decimal)
Parameter Range (Standard baud rates): 0 – 6
(Non-standard baud rates): 0x7D – 0xFFFF
BAUD (bps)
Parameter
Configuration
0
1200
1
2400
2
4800
3
9600
4
19200
5
38400
6
57600
Number of bytes returned: 2
Default Parameter Value: Set to equal to
modem’s factory-set RF data rate.
Minimum firmware version required: 4.2B
(Custom baud rates not previously supported)
Non-standard Interface Data Rates: When
parameter values outside the range of standard
baud rates are sent, the closest interface data
rate represented by the number is stored in the
BD register. For example, a rate of 19200 bps can be set by sending the following command line
"ATBD4B00". NOTE: When using Digi’s XCTU Software, non-standard interface data rates can
only be set and read using the XCTU “Terminal” tab. Non-standard rates are not accessible
through the “Modem Configuration” tab.
When the BD command is sent with a non-standard interface data rate, the UART will adjust to
accommodate the requested interface rate. In most cases, the clock resolution will cause the
stored BD parameter to vary from the parameter that was sent (refer to the table below).
Reading the BD command (send "ATBD" command without an associated parameter value) will
return the value that was actually stored to the BD register.
Table 4.2.
Parameter Sent vs. Parameter Stored
BD Parameter Sent (HEX)
0
4
7
12C
1C200
© 2014 Digi International Inc.
Interface Data Rate (bps)
1200
19,200
115,200
300
115,200
BD Parameter Stored (HEX)
0
4
7
12B
1B207
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BK (Serial Break Passing) Command
Pass a serial break condition
on the DI pin to the DO pin of another modem.
AT Command: ATBK
Binary Command: 0x2E (46 decimal)
Parameter Range: 0 – 1
Parameter
Configuration
0
disable
1
enable
Default Parameter Value: 0
Number of bytes returned: 1
Related Commands: BO (Serial Break Timeout)
Minimum Firmware Version Required: 4.30
BO (Serial Break Timeout) Command
DO pin will return to default
after no serial break status information is
received during the timeout period.
AT Command: ATBO
Use with BK parameter = 1.
Default Parameter Value: 0
Binary Command: 0x30 (48 decimal)
Parameter Range: 0 – 0xFFFF (x 1 second)
Number of bytes returned: 2
Related Commands: BK (Serial Break Passing)
Minimum Firmware Version Required: 4.30
BT (Guard Time Before) Command
BT Command is
used to set the DI pin silence time that must
precede the command sequence character (CC
Command) of the AT Command Mode Sequence.
Refer to the AT Commands section (p19) to view
the default AT Command Mode sequence.
AT Command: ATBT
Binary Command: 0x04 (4 decimal)
Parameter Range: 2 – 0xFFFF
(x 100 milliseconds)
Default Parameter Value: 0x0A (10 decimal)
Number of bytes returned: 2
Related Commands: AT (Guard Time After), CC
(Command Sequence Character)
CB (Connection Duration Timeout) Command
Set/Read the
maximum amount of time an exclusive
connection between a base and remote modem
in a point-to-multipoint network is sustained. The
remote modem will disconnect when this timeout
expires.
AT Command: ATCB
Binary Command: 0x33 (51 decimal)
Parameter Range: 0x01 – 0xFFFF
(x 100 milliseconds)
Default Parameter Value: 0x28 (4d seconds)
Number of bytes returned: 2
Related Commands: CE (Connection Inactivity
Timeout), DC (Disconnect), MD (RF Mode)
Minimum Firmware Version Required: 4.30
CC (Command Sequence Character) Command
CC Command is
used to set the ASCII character to be used
between Guard Times of the AT Command Mode
Sequence (BT+ CC + AT). The AT Command
Mode Sequence activates AT Command Mode
(from Idle Mode).
Refer to the AT Commands section (p19) to view
the default AT Command Mode sequence.
© 2014 Digi International Inc.
AT Command: ATCC
Binary Command: 0x13 (19 decimal)
Parameter Range: 0x20 – 0x7F
Default Parameter Value: 0x2B (ASCII “+” sign)
Number of bytes returned: 1
Related Commands: AT (Guard Time After), BT
(Guard Time Before)
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CD (DO3 Configuration) Command
CD Command is
used to redefine the behavior of the DO3 (Data
Output 3)/RX LED line.
AT Command: ATCD
Binary Command: 0x28 (40 decimal)
Parameter Range: 0 – 2
Parameter
Configuration
0
RX LED
1
Default high
2
Default low
3
(reserved)
Assert only when packet
addressed to modem sent
4
Default Parameter Value: 0
Number of bytes returned: 1
Minimum Firmware Version Required: 4.2B
CE (Connection Inactivity Timeout) Command
Set/Read the
duration of inactivity that will cause a break in a
connection between modems. The base modem
will disconnect when no payload has been
transferred for the time specified by the CE
parameter.
AT Command: ATCE
Binary Command: 0x34 (52 decimal)
Parameter Range: 0 – 0xFFFF
(x 10 milliseconds)
Default Parameter Value: 0x64 (1d second)
Number of bytes returned: 2
Related Commands: CB ( Connection Duration
Timeout), DC (Disconnect), MD (RF Mode)
Minimum Firmware Version Required: 4.30
CF (Connection Failure Count) Command
Set/Read the number of times the
base modem expired retries attempting to send a
Connection Grant Packet.
AT Command: ATCF
Set the parameter value to zero to clear the
register.
Default Parameter Value: 0
Binary Command: 0x35 (53 decimal)
Parameter Range: 0 – 0xFFFF
Number of bytes returned: 2
Minimum Firmware Version Required: 4.30
CL (Last Connection Address) Command
Read
the address of the remote modem that last
connected to the base modem. A remote modem
will return its DT (Destination Address)
parameter.
AT Command: ATCL
Binary Command: 0x39 (57 decimal)
Parameter Range: 0 – 0xFFFF (read-only)
Number of bytes returned: 2
Minimum Firmware Version Required: 4.30
CM (Connection Message) Command
Select whether base
sends connect messages to the host when a
connection is established. When enabled, a
“CONNECTXXXX” string is sent to the host of the
base modem. “XXXX” is the MY (Source Address)
of the connected remote modem.
AT Command: ATCM
Binary Command: 0x38 (56 decimal)
Parameter Range: 0 – 1
Parameter
Configuration
0
enable
1
disable
Default Parameter Value: 0
Number of bytes returned: 1
Minimum Firmware Version Required: 4.30
© 2014 Digi International Inc.
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CN (Exit AT Command Mode) Command
CN Command is
used to explicitly exit AT Command Mode.
AT Command: ATCN
Binary Command: 0x09 (9 decimal)
CO (DO3 Timeout) Command
DO3 (Data Output 3) output
will return to default after no DI3 (Data Input 3)
status information is received during the timeout
period.
AT Command: ATCO
Use with CD = 1 or 2, DR = 1.
Number of bytes returned: 2
Binary Command: 0x2F (47 decimal)
Parameter Range: 0 – 0xFFFF (x 1 second)
Default Parameter Value: 3
Related Commands: CD (DO3 Configuration),
DR (DI3 Configuration)
Minimum Firmware Version Required: 4.30
CS (DO2 Configuration) Command
CS Command is used to
select the behavior of the DO2 (Data Output 2)
pin signal. This output can provide RS-232 flow
control, control the TX enable signal (for RS-485
or RS-422 operations), or set the default level
for the I/O line passing function.
By default, DO2 provides RS-232
Send) flow control.
(Clear-to-
AT Command: ATCS
Binary Command: 0x1F (31 decimal)
Parameter Range: 0 – 4
Parameter
Configuration
0
RS-232
flow control
1
RS-485 TX enable low
2
high
3
RS-485 TX enable high
4
low
Default Parameter Value: 0
Number of bytes returned: 1
Related Commands: RT (DI2 Configuration), TO
(DO2 Timeout)
Minimum Firmware Version Required: 4.27D
CT (Command Mode Timeout) Command
CT Command sets
the amount of time before AT Command Mode
terminates automatically. After a CT time of
inactivity, the modem exits AT Command Mode
and returns to Idle Mode. AT Command Mode can
also be exited manually using CN (Exit AT
Command Mode) Command.
AT Command: ATCT
Binary Command: 0x06 (6 decimal)
Parameter Range: 0x02 – 0xFFFF
(x 100 milliseconds)
Default Parameter Value: 0xC8 (200 decimal,
20 seconds)
Number of bytes returned: 2
DC (Disconnect) Command
DC Command is
used (when in Multi-Streaming Mode (MD = 1 or
2)) to explicitly force the disconnection of an
active exclusive connection. If MD = 1, the base
modem will force the disconnection of an
exclusive connection. If MD = 2, the remote
modem will send a “Disconnect Request Packet”
to the base modem.
© 2014 Digi International Inc.
AT Command: ATDC
Binary Command: 0x37 (55 decimal)
Related Commands: CB (Connection Duration
Timeout), CE (Connection Inactivity Timeout),
MD (RF Mode)
Minimum Firmware Version Required: 4.30
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DR (DI3 Configuration) Command
The DR Command is used to
configure the DI3 (Data Input 3 / SLEEP) line for
I/O line passing (use with CD = 1 or 2 and CO)
or controlling connection status (use with MD = 1
or 2).
AT Command: ATDR
Binary Command: 0x2D (45 decimal)
Parameter Range: 0 – 4
Parameter
Configuration
0
Disabled
1
DI3 I/O passing enabled
2
Connect on low
3
Disconnect on high
4
Connect and Disconnect
Default Parameter Value: 0
Number of bytes returned: 1
Related Commands: CD (DO3 Configuration),
CO (DO3 Timeout), MD (RF Mode)
Minimum Firmware Version Required: 4.30
DT (Destination Address) Command
DT Command is used to set the
AT Command: ATDT
networking address of an XStream Modem.
Binary Command: 0x00
XStream Modems use three filtration layers –
Parameter Range: 0 – 0xFFFF
Vendor Identification Number (ATID), Channels
(ATHP) and Destination Addresses (ATDT). DT
Default Parameter Value: 0
Command assigns an address to a modem that
Number of bytes returned: 2
enables it to communicate only with other
Related Commands: HP (Hopping Channel), ID
modems having the same addresses. All modems
(Modem VID), MK (Address Mask)
that share the same Destination Address can
communicate freely with each other. Modems in
the same network with a different Destination Address (than that of the transmitter) will listen to
all transmissions to stay synchronized, but will not send any of the data out their serial ports.
E0 (Echo Off) Command
E0 Command turns
off character echo in AT Command Mode. By
default, echo is off.
AT Command: ATE0
Binary Command: 0x0A (10 decimal)
E1 (Echo On) Command
E1 Command turns
on the echo in AT Command Mode. Each typed
character will be echoed back to the terminal
when ATE1 is active. E0 is the default.
AT Command: ATE1
Binary Command: 0x0B (11 decimal)
ER (Receive Error Count) Command
Set/Read the receive-error. The
error-count records the number of packets
partially received then aborted on a reception
error. This value returns to 0 after a reset and is
not non-volatile (Value does not persist in the
modem’s memory after a power-up sequence).
Once the “Receive Error Count” reaches its
maximum value (up to 0xFFFF), it remains at its
maximum count value until the maximum count
value is explicitly changed or the modem is reset.
© 2014 Digi International Inc.
AT Command: ATER
Binary Command: 0x0F (15 decimal)
Parameter Range: 0 – 0xFFFF
Default Parameter Value: 0
Number of bytes returned: 2
Related Commands: GD (Receive Good Count)
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FH (Force Wake-up Initializer) Command
FH Command is used to
force a Wake-up Initializer to be sent on the next
transmit. WR (Write) Command does not need to
be issued with FH Command.
AT Command: ATFH
Binary Command: 0x0D (13 decimal)
Use only with cyclic sleep modes active on remote modems.
FL (Software Flow Control) Command
FL Command is used to
configure software flow control. Hardware flow
control is implemented with the XStream Modem
as the DO2 pin (
), which regulates when
serial data can be transferred to the modem. FL
Command can be used to allow software flow
control to also be enabled. XON character used is
0x11 (17 decimal). XOFF character used is 0x13
(19 decimal).
AT Command: ATFL
Binary Command: 0x07 (7 decimal)
Parameter Range: 0 – 1
Parameter
0
1
Configuration
Disable software
flow control
Enable software
flow control
Default Parameter Value: 0
Number of bytes returned: 1
FT (Flow Control Threshold) Command
Set/Read the flow control
threshold. When FT bytes have accumulated in
the DI buffer,
is de-asserted or the XOFF
software flow control character is transmitted.
AT Command: ATFT
Binary Command: 0x24 (36 decimal)
Parameter Range: 0 – (Receiving modem DO
buffer size minus 0x11 bytes)
Default Parameter Value: Receiving modem DO
Buffer size minus 0x11
Number of bytes returned: 2
Minimum Firmware Version Required: 4.27B
GD (Receive Good Count) Command
Set/Read the count of good
received RF packets. Parameter value is reset to
0 after every reset and is not non-volatile (Value
does not persist in the modem’s memory after a
power-up sequence). Once the “Receive Good
Count” reaches its maximum value (up to
0xFFFF), it remains at its maximum count value
until the maximum count value is manually
changed or the modem is reset.
AT Command: ATGD
Binary Command: 0x10 (16 decimal)
Parameter Range: 0 – 0xFFFF
Default Parameter Value: 0
Number of bytes returned: 2
Related Commands: ER (Receive Error Count)
HP (Hopping Channel) Command
HP Command is used to set the
modem’s hopping channel number. A channel is
one of three layers of addressing available to the
XStream modem. In order for modems to
communicate with each other, the modems must
have the same channel number since each
network uses a different hopping sequence.
Different channels can be used to prevent
modems in one network from listening to
transmissions of another.
© 2014 Digi International Inc.
AT Command: ATHP
Binary Command: 0x11 (17 decimal)
Parameter Range: 0 – 6
Default Parameter Value: 0
Number of bytes returned: 1
Related Commands: DT (Destination Address),
ID (Modem VID), MK (Address Mask)
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HT (Time before Wake-up Initializer) Command
RR Command specifies the number
AT Command: ATRR
of retries that can be sent for a given RF packet.
Binary Command: 0x18 (24 decimal)
Once RR Command is enabled (set to a non-zero
Parameter Range: 0 – 0xFF
value), RF packet acknowledgements and retries
are enabled. After transmitting a packet, the
Default Parameter Value: 0 (disabled)
transmitter will wait to receive an
Number of bytes returned: 1
acknowledgement from a receiver. If the
Minimum Firmware Version Required: 4.22
acknowledgement is not received in the period of
time specified by the RN (Delay Slots) Command,
the transmitter will transmit the original packet again. The packet will be transmitted repeatedly
until an acknowledgement is received or until the packet has been sent RR times.
Note: For retries to work correctly, all modems in the system must have retries enabled.
© 2014 Digi International Inc.
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RS (RSSI) Command
RS Command returns the signal
level of the last packet received. This reading is
useful for determining range characteristics of the
XStream Modems under various conditions of
noise and distance.
AT Command: ATRS
Binary Command: 0x1C (28 decimal)
Parameter Range: 0x06 – 0x36 (Read-only)
Number of bytes returned: 1
Once the command is issued, the modem will
Minimum Firmware Version Required: 4.22
return a value between 0x6 and 0x36 where
0x36 represents a very strong signal level and 0x4 indicates a low signal level.
RT (DI2 Configuration) Command
RT command is used to
dictate the behavior of the DI2/
/CMD line. RT
Command must be issued to enable
flow
control or binary programming.
AT Command: ATRT
Binary Command: 0x16 (22 decimal)
Parameter Range: 0 – 2
Parameter
Configuration
0
disabled
1
Enable Binary Programming
2
Enable
Flow Control
Default Parameter Value: 0
Number of bytes returned: 1
RZ (DI Buffer Size) Command
The RZ command is used to read
the size of the DI buffer (UART RX (Receive)).
AT Command: ATRZ
Note: The DO buffer size can be determined by
multiplying the DI buffer size by 1.5.
Parameter Range: Read-only
Binary Command: 0x2C (44 decimal)
Number of bytes returned: 2
Minimum Firmware Version Required: 4.30
SB (Stop Bits) Command
SB Command is used to
set/read the number of stop bits in the data
packets.
AT Command: ATSB
Binary Command: 0x36 (54 decimal)
Parameter Range: 0 – 1
Parameter
Configuration
0
1 stop bits
1
2 stop bits
Default Parameter Value: 0
Number of bytes returned: 1
Minimum Firmware Version Required: 4.2B
SH (Serial Number High) Command
Set/Read the serial number high
word of the modem.
AT Command: ATSH
Binary Command: 0x25 (37 decimal)
Parameter Range: 0 – 0xFFFF (Read-only)
Number of bytes returned: 2
Related Commands: SL (Serial Number Low)
Minimum Firmware Version Required: 4.27C
© 2014 Digi International Inc.
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SL (Serial Number Low) Command
Set/Read the serial number low
word of the modem.
AT Command: ATSH
Binary Command: 0x26 (38 decimal)
Parameter Range: 0 – 0xFFFF (Read-only)
Number of bytes returned: 2
Related Commands: SH (Serial Number High)
Minimum Firmware Version Required: 4.27C
SM (Sleep Mode) Command
SM Command is
used to adjust Sleep Mode settings. By default,
Sleep Mode is disabled and the modem remains
continually active. SM Command allows the
modem to run in a lower-power state and be
configured in one of eight settings.
Cyclic Sleep settings wake the modem after the
amount of time designated by SM Command. If
the modem detects a wake-up initializer during
the time it is awake, it will synchronize with the
transmitter and start receiving data after the
wake-up initializer runs its duration. Otherwise, it
returns to Sleep Mode and continue to cycle in
and out of inactivity until the Wake-up Initializer
is detected. If a Cyclic Sleep setting is chosen,
the ST, LH and HT parameters must also be set
as described in the “Sleep Modes” section of this
manual.
Refer to the Sleep Mode sections (p16) for more
information.
AT Command: ATSM
Binary Command: 0x01
Parameter Range: 0 – 8
Parameter
Configuration
0
Disabled
1
Pin Sleep
2
4
Serial Port Sleep
Cyclic 0.5 second sleep
(Modem wakes every 0.5
seconds)
Cyclic 1.0 second sleep
5
Cyclic 2.0 second sleep
6
Cyclic 4.0 second sleep
3
7
Cyclic 8.0 second sleep
8
Cyclic 16.0 second sleep
Default Parameter Value: 0
Number of bytes returned: 1
Related Commands:
For Pin Sleep – PC (Power-up Mode), PW (Pin
Wake-up)
For Serial Port Sleep – ST (Time before Sleep)
For Cyclic Sleep – ST (Time before Sleep), LH
(Wake-up Initializer Timer), HT (Time Before
Wake-up Initializer), PW (Pin Wake-up)
ST (Time before Sleep) Command
ST Command sets
the period of time (in tenths of seconds) in which
the modem remains inactive before entering into
Sleep Mode. For example, if the ST Parameter is
set to 0x64 (100 decimal), the modem will enter
into Sleep mode after 10 seconds of inactivity (no
transmitting or receiving). This command can
only be used if Cyclic Sleep or Serial Port Sleep
Mode settings have been selected using SM
(Sleep Mode) Command.
© 2014 Digi International Inc.
AT Command: ATST
Binary Command: 0x02
Parameter Range: 0x10 – 0xFFFF
(x 100 milliseconds)
Default Parameter Value: 0x64 (100 decimal)
Number of bytes returned: 2
Related Commands: SM (Sleep Mode), LH
(Wake-up Initializer Timer), HT (Time before
Wake-up Initializer)
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SY (Time before Initialization) Command
SY Command keeps a
communication channel open as long as modem
transmits or receives before the active connection
expires. It can be used to reduce latency in a
query/response sequence and should be set 100
ms longer than the delay between transmissions.
AT Command: ATSY
Binary Command: 0x17 (23 decimal)
Parameter Range: 0 – 0xFF
(x 100 milliseconds)
Default Parameter Value: 0 (Disabled - channel
initialization information is sent with each RF
packet.)
This command allows multiple XStream Modems
to share a hopping channel for a given amount of
Number of bytes returned: 1
time after receiving data. By default, all packets
include an RF initializer that contains channel
information used to synchronize any listening receivers to the transmitter’s hopping pattern.
Once a new modem comes within range or is powered on within range, it is able to instantly
synchronize to the transmitter and start receiving data. If no new modems are introduced into
the system, the synchronization information becomes redundant once modems have become
synchronized.
SY Command allows the modems to remove this information from the RF Initializer after the
initial synchronization. For example, changing the SY Parameter to 0x14 (20 decimal) allows all
modems to remain in sync for 2 seconds after the last data packet was received. Synchronization
information is not re-sent unless transmission stops for more than 2 seconds. This command
allows significant savings in packet transmission time.
Warning:
Not recommended for use in an interference-prone environment. Interference can
break up the session and the communications channel will not be available again
until SY time expires.
With SY set to zero, the channel session is opened and closed with each transmission - resulting
in a more robust link with more latency.
TO (DO2 Timeout) Command
DO2 output will return to
default after no DI2 status information is
received during the timeout period.
AT Command: ATTO
Use with CS = 2 or 4.
Default Parameter Value: 3
Binary Command: 0x31 (49 decimal)
Parameter Range: 0 – 0xFFFF (x 1 second)
Number of bytes returned: 2
Minimum Firmware Version Required: 4.30
TR (Transmit Error Count) Command
TR Command records the number
of retransmit failures. This number is
incremented each time a packet is not
acknowledged within the number of retransmits
specified by the RR (Retries) Command. It
therefore counts the number of packets that were
not successfully received and have been dropped.
The TR Parameter is not non-volatile and will
therefore be reset to zero each time the modem
is reset.
© 2014 Digi International Inc.
AT Command: ATTR
Binary Command: 0x1B (27 decimal)
Parameter Range: 0 – 0xFFFF
Default Parameter Value: 0
Number of bytes returned: 2
Related Commands: RR (Retries)
Minimum Firmware Version Required: 4.22
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TT (Streaming Limit) Command
TT Command defines a limit on
the number of bytes that can be sent out before
a random delay is issued. TT Command is used to
simulate full-duplex behavior.
AT Command: ATTT
If a modem is sending a continuous stream of RF
data, a delay is inserted which stops its
transmission and allows other modems time to
transmit (once it sends number of bytes specified
by TT Command). Inserted random delay lasts
between 1 and “RN + 1” delay slots, where each
delay slot lasts 38ms.
Default Parameter Value: 0xFFFF (65535
decimal)
Binary Command: 0x1A (26 decimal)
Parameter Range: 0 – 0xFFFF (0 = disabled)
Number of bytes returned: 2
Related Commands: RN (Delay Slots)
Minimum Firmware Version Required: 4.22
VR (Firmware Version) Command
Read the Firmware Version of the
XStream Modem.
AT Command: ATVR
Binary Command: 0x14 (20 decimal)
Parameter Range: 0 – 0xFFFF (Read-only)
Number of bytes returned: 2
WR (Write) Command
WR Command writes configurable
AT Command: ATWR
parameters to the modem’s non-volatile memory
Binary Command: 0x08
(Parameter values remain in the modem’s
memory until overwritten by future use of WR Command).
If changes are made without writing them to non-volatile memory, the modem reverts back to
previously saved parameters the next time the modem is powered-on.
© 2014 Digi International Inc.
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5. RF Communication Modes
Network configurations covered in this chapter are described in terms of the following:
• Network Topology (Point-to-Point, Point-to-Multipoint or Peer-to-Peer)
• RF Communication Type (Basic or Acknowledged)
• RF Mode (Streaming, Repeater, Acknowledged or Multi-Streaming)
The following table provides a summary of the network configurations supported.
Table 5.1.
Summary of network configurations supported by the XStream RF Modem
Point-to-Point
Definition
An RF data link between two modems.
Sample Network Profile *
(Broadcast Communications)
Use default values for all modems.
Sample Network Profile *
(Acknowledged Communications)
All Modems: ATAM (auto-set MY (Source Address) parameter) **
ATDT FFFF (set Destination Address to 0xFFFF)
Basic Communication RF Modes
Streaming Mode (p42), Repeater Mode (p43)
Acknowledged Communication RF Mode
Acknowledged Mode (p46)
Definition
RF data links between one base and multiple remotes.
Point-to-Multipoint
Base:
ATMY 0 (set Source Address to 0x00)
ATDT FFFF (set Destination Address to 0xFFFF)
Remotes:
ATAM (auto-set MY (Source Address) parameter) **
ATDT 0 (set Destination Address to 0x00)
Base:
Sample Network Profile *
(Acknowledged Communications)
ATMY 0 (set Source Address to 0x00)
ATDT FFFF (set Destination Address to 0xFFFF)
ATRR 3 (set number of Retries to 3)
Remotes:
ATAM (auto-set MY (Source Address) parameter) **
ATDT 0 (set Destination Address to 0x00)
ATRR 3 (set number of Retries to 3)
Basic Communication RF Modes
Streaming Mode (p42), Repeater Mode (p43)
Acknowledged Communication RF Modes
Acknowledged Mode (p46), Multi-Streaming Mode (p48)
Definition
Modems remain synchronized without use of a master/server. Each
modem shares the roles of master and slave. Digi’s peer-to-peer
architecture features fast synch times (35ms to synchronize
modems) and fast cold start times (50ms before transmission).
Sample Network Profile *
(Basic Communications)
Use default values for all modems.
Sample Network Profile *
(Acknowledged Communications)
All Modems: ATAM (auto-set MY (Source Address) parameter) **
ATDT FFFF (set Destination Address to 0xFFFF)
ATRR 3 (set number of Retries to 3)
Basic Communication RF Mode
Streaming Mode (p42)
Acknowledged Communication RF Mode
Acknowledged Mode (p46)
Sample Network Profile *
(Basic Communications)
Peer-to-Peer
* Assume default values for parameters not listed. Profiles do not reflect addressing implementations.
** AM (Auto-set MY) Command must be issued through a terminal program such as the one incorporated in
the XCTU “Terminal” tab.
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5.1. Addressing
Each RF packet contains addressing information that is used to filter incoming RF data. Receiving
modems inspect the Hopping Channel (HP parameter), Vendor Identification Number (ID
parameter) and Destination Address (DT parameter) contained in each RF packet. Data that does
not pass through all three network security layers is discarded (Figure 5.1).
Figure 5.1.
Filtration layers contained in the RF packet header
5.1.1. Address Recognition
Transmissions can be addressed to a specific modem or group of modems using the DT
(Destination Address) and MK (Address Mask) parameters. The transmitting modem dictates
whether the packet is intended for a specific modem (local address) or multiple modems (global
address) by comparing the packet’s DT parameter to its own MK parameter (Figure 5.2).
Figure 5.2. Local Packets vs. Global Packets (Transmitting Modem)
TX_DT = Transmitter Destination Address
TX_MK = Transmitter Address Mask
Note: When TX_DT = 0xFFFF (default), RF packets are global and are
received by all modems within range. (Receivers do not send ACKs.)
A receiving modem will only accept a packet if a packet is addressed to it (either as a global or
local packet). The RX modem makes this determination by inspecting the destination address of
the RF packet and comparing it to its own address and mask (Figure 5.3). The Destination
Address of the TX modem is logically “ANDed” with the Address Mask of the RX modem.
Figure 5.3. Address Recognition (Receiving Modem)
TX_DT = Transmitter Destination Address
RX_DT = Receiver Destination Address
RX_MY = Receiver Source Address
NOTE: For more information regarding addressing and masks, refer to Application Note “XSTAN004b”. (Located on the Digi Support site at www.digi.com/support).
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5.2. Basic Communications
Basic Communications are accomplished through two sub-types:
• Broadcast - By default, XStream Modems communicate through Broadcast communications
and within a peer-to-peer network topology. When any modem transmits, all other modems
within range will receive the data and pass it directly to their host device.
• Addressed - If addressing parameters match, received RF data is forwarded to the DO (Data
Out) buffer; otherwise, the RF data is discarded.
When using Basic Communications, any functions such as acknowledgements are handled at the
application layer by the OEM/integrator. The Broadcast Modes provide transparent
communications, meaning that the RF link simply replaces a wired link.
5.2.1. Streaming Mode (Default)
Characteristics:
Highest data throughput
Lowest latency and jitter
Reduced immunity to interference
Transmissions never acknowledged (ACK) by receiving modem(s)
Required Parameter Values (TX Modem): RR (Retries) = 0
Related Commands: Networking (DT, MK, MY), Serial Interfacing (PK, RB, RO, TT)
Recommended Use: Mode is most appropriate for data systems more sensitive to latency
and/or jitter than to occasional packet loss. For example: streaming audio or video.
Streaming Mode Data Flow
Figure 5.4. Streaming Mode State Diagram (TX Modem)
Events and processes in this mode are common to all of the other RF
Communication Modes.
NOTE: When streaming data, RB and RO parameters are only observed on
the first packet.
After transmission begins, the TX event will continue uninterrupted until
the DI buffer is empty or the streaming limit (TT Command) is reached.
As with the first packet, the payload of each subsequent packet includes
up to the maximum packet size (PK Command).
The streaming limit (TT Command) is specified by the transmitting
modem as the maximum number of bytes the transmitting modem can
send in one transmission event. After the TT parameter threshold is
reached, the transmitting modem will force a random delay of 1 to RN
delay slots (exactly 1 delay slot if RN = 0).
Subsequent packets are sent without an RF initializer since receiving
modems stay synchronized with the transmitting modem for the
duration of the transmission event (from preceding packet information).
However, due to interference, some receiving modems may lose data
(and synchronization to the transmitting modem), particularly during
long transmission events.
Once the transmitting modem has sent all pending data or has reached
the TT limit, the transmission event ends. The transmitting modem will
not transmit again for exactly RN delay slots if the local (i.e.
transmitting modem’s) RN parameter is set to a non-zero value. The
receiving modem(s) will not transmit for a random number of delay
slots between 0 and (RN-1) if the local (i.e. receiving modem’s) RN
parameter is set to a non-zero value. These delays are intended to lessen congestion following
long bursts of packets from a single transmitting modem, during which several receiving modems
may have become ready to transmit.
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5.2.2. Repeater Mode
Characteristics:
Self-organizing - No route configuration is necessary
Self-healing / Fault-tolerant
Low power consumption and Minimized interference
Network throughput is determined by number of hops, not by number of
repeaters. Multiple repeaters within range of source node count as one hop.
Supports “transparent” multi-drop mode or addressed data filtering mode.
Duplicate RF packets are automatically filtered out.
All packets propagate to every node in the network (filtering rules apply).
Broadcast communications - each packet comes out every node exactly once.
Addressed communications - all radios see every packet. Only the modem
with a matching address will forward it to the DO buffer (UART IN).
Data entering the network on any modem is transmitted and forwarded
through every repeater modem until it reaches the ends of the network.
Each repeater will repeat a packet only once.
Constraints:
Requires that each modem have a unique MY (Source Address) parameter.
System must introduce just one packet at a time to the network for
transmission (256 bytes max).
Each hop (H) decreases network throughput by a factor of 1/(H+1).
Additional repeaters add network redundancy without decreasing throughput.
Required Parameter Values (TX Modem): MD = 3 or 4, MY = unique value (can be
accomplished by issuing the AM (Auto-set MY) and WR (Write) commands to all modems in the
network)
Related Commands: Networking (MD, DT, MY, AM), Serial Interfacing (RN, PK, RO, RB)
Recommended Use: Use in networks where intermediary nodes are needed to relay data to
modems that are beyond the transmission range of the base modem.
Theory of Operation
OEMs and integrators can extend the effective range and reliability of a data radio system by
forwarding traffic through one or more repeaters.
Instead of using routing tables and path discovery to establish dynamic paths through a network,
the repeater system uses a sophisticated algorithm to propagate each RF packet through the
entire network.
The network supports RF packets up to 256 bytes. The repeater network can operate using
broadcast or addressed communications for multi-drop networks and works well in many systems
with no special configuration.
When in Repeater Mode, the network repeats each message among all available nodes exactly
one time. This mechanism eliminates the need for configuring specific routes. The network is selforganizing and self-healing so that the system is able to receive transmissions in the event of a
modem going down.
Figure 5.5.
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Repeater Network Configuration
A network may consist of End Nodes (EN), End/Repeater Nodes (ERN) and a Base Node (BN).
The base node initiates all communications.
The repeater network can be configured to operate using Basic Broadcast or Basic Addressed
communications. The addressing capabilities of the modems allow integrators to send a packet as
a global packet (DT = 0xFFFF) and shift out of every radio in the network (Basic Broadcast).
Alternatively, the packet can be sent with a specific DT (Destination Address) parameter so that it
is only accepted by a specific remote node (Basic Addressed).
Configuration Instruction (Basic Broadcast Communications)
Assign each radio modem a unique MY (source) address. (The AM (Auto-set MY) command will
configure a unique source address that is based on modem serial number.)
Enable Basic Broadcast Communications (DT = 0xFFFF) or Addressed Broadcast Communications
(ATDT specifies a specific destination)
Configure PK, RO and RB to ensure that RF packet aligns with protocol packet. (ex. PK=0x100,
RB=0x100, RO depends on baud rate).
Configure one or more repeaters in the system (ATMD = 3).
Configure remote nodes as destinations (MD = 4). This will ensure that the remote node waits for
the repeater traffic to subside before it transmits a response.
The configuration instructions above reflect configuration for a Basic Broadcast Repeater system.
To configure a Basic Addressed Repeater system, use the DT (Destination Address) parameter to
assign unique addresses to each modem in the network.
Algorithm details
• Packet ID (PID) is composed of transmitting modem MY address and packet serial number.
• Incoming packets with a PID already found in the PID buffer will be ignored.
• Each modem maintains a PID buffer 8 deep of previously received packets (managed as
FIFO).
Packets may be shifted out the serial port and/or repeated depending on the DT parameter
contained in the RF packet.
Table 5.2.
DT (Destination Address) parameter truth table
Address Match
Send out serial port?
Repeat?
Global
Yes
Yes
Local
Yes
No
None
No
Yes
Repeat delay based on RSSI
A transmitted packet may be received by more that one repeater at the same time. In order to
reduce the probability that the repeaters will transmit at the same instant, resulting in a collision
and possible data loss; an algorithm has been developed that will allow a variable back-off prior
to retransmission of the packet by a repeater. The algorithm allows radios that receive the packet
with a stronger RF signal (RSSI) to have the first opportunity to retransmit the packet.
The RN (Delay Slots) parameter is used to configure this delay. Set RN=0 (no delays) for small
networks with few repeaters or repeaters that are not within range of each other. Set RN=1 for
systems with 2 to 5 repeaters that may be within range of each other.
The actual length of the delay is computed by the formula:
Delay (ms) = L * DS
DS = (-41-RSSI)/10*RN)+RandomInt(0,RN)
Where L is the length of the transmitted packet in milliseconds, DS is the number of delay slots
to wait, RSSI is the received signal strength in dBm, RN is the value of the RN register and
RandomInt(A,B) is a function that returns a random integer from A to B-0
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Response packet delay
As a packet propagates through the repeater network, if any node receives the data and
generates a quick response, the response needs to be delayed so as not to collide with
subsequent retransmissions of the original packet. To reduce collisions, both repeater and end
node radios in a repeater network will delay transmission of data shifted in the serial port to allow
any repeaters within range to complete their retransmissions.
The time for this delay is computed by the formula:
Maximum Delay (ms) = L * DS
DS = ((-41-(-100))/10)*RN)+RN+1
Where L is the length of the transmitted packet in milliseconds, DS is the number of delay slots
to wait, RSSI is the received signal strength in dBm, and RN is the value of the RN register.
Use Case - Broadcast Repeater Network
Consider modems R1 through R10 each communicating to a PLC using the ModBus protocol and
spaced evenly in a line. All ten nodes are configured as “destinations and repeaters” within the
scope of Basic Broadcast Communications (MD=3, AM, DT=0xFFFF, PK=0x100, RO=0x03,
RB=0x100, RN=1). The Base Host (BH) shifts payload that is destined for R10 to R1. R1
initializes RF communication and transmits payload to nodes R2 through R5 which are all within
range of R1. Modems R2 through R5 receive the RF packet and retransmit the packet
simultaneously. They also send the data out the serial ports, to the PLC's.
Table 5.3. Commands used to configure repeater functions
AT
Binary
AT Command Name
Command
Command
AM
0x3A (58d)
Auto-set MY
DT
0x00 (0d)
Destination Address
MD
0x3C (60d)
RF Mode
MY
0x2A (42d)
Source Address
RN
0x19 (25d)
Delay Slots
WR
0x08 (8d)
Write
Range
0 – 0xFFFF
3-4
0 – 0xFFFF
0 – 0xFF (slots)
-
# Bytes
Returned
2
1
2
1
-
Factory
Default
0
0
0xFFFF
0
-
Bandwidth Considerations
Using broadcast repeaters in a network reduces the overall network data throughput as each
repeater must buffer an entire packet before retransmitting it. For example: if the destination is
within range of the transmitter and the packet is 32 bytes long, the transmission will take 72ms
on a 9600 baud XStream modem (much faster modems are available). If that same packet has to
propagate through two repeaters, it will take 72ms to arrive at the first repeater, another 72 ms
to get to the second and a final 72ms to get to the destination for a total of 216ms. Taking into
account UART transfer times (~1ms/byte at 9600 baud), a server to send a 32 byte query and
receive a 32 byte response is ~200ms, allowing for 5 polls per second. With the two repeaters in
the path, the same query/response sequence would take about 500ms for 2 polls per second.
To summarize, this system is sending and receiving 64 bytes 5 times per second for a throughput
of 320 bytes per second with no repeaters and 128 bytes per second with 2 repeaters. Generally,
the network throughput will decrease by a factor of 1/(R+1), with R representing the number of
repeaters between the source and destination.
Note that these numbers are absolutely worst case to illustrate how the system would perform in
a typical, low bandwidth system. As a counter example the 115kbps 9XTend radio can transfer
the same 32 byte packet in 12 ms for a round trip with UART transfer times of ~30ms or 33 polls
per second (1066 bytes per second) with no repeaters. With two repeaters the time would be
~100ms round trip time for 10 polls per second or 320 bytes per second network throughput with
two repeaters.
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5.3. Acknowledged Communications
5.3.1. Acknowledged Mode
Characteristics:
Reliable delivery through positive acknowledgements for each packet
Throughput, latency and jitter vary depending on the quality of the channel
and the strength of the signal.
Recommended Use: Acknowledge Mode configuration is appropriate when reliable delivery is
required between modems. If messages are smaller than 256 bytes, use RB and RO commands
to align RF packets with application packets.
Required Parameter Values (TX Modem): RR (Retries) >= 1
Related Commands: Networking (DT, MK, RR), Serial Interfacing (PK, RN, TT, RO, RB)
Table 5.4.
Sample Network Profile
Modem
Parameter Settings (assume default values for parameters not listed)
All
ATRR A
ATRN 5
(set number of Retries to 0x0A)
(set number of Delay Slots to 5)
Connection Sequence
Figure 5.6.
Acknowledged Mode State Diagram
After sending a packet while
in Acknowledged Mode, the
transmitting modem listens
for an ACK
(acknowledgement). If it
receives the ACK, it will either
send a subsequent packet (if
more transmit data is
pending), or will wait for
exactly RN random delay slots
before allowing another
transmission (if no more data
is pending for transmission).
If the transmitting modem
does not receive the ACK
within the allotted time, it will
retransmit the packet with a
new RF initializer following the
ACK slot. There is no delay
between the first ACK slot and
the first retransmission.
Subsequent retransmissions
incur a delay of a random
number of delay slots,
between 0 and RN. If RN is
set to 0 on the transmitting
modem, there are never any
back-off delays between
retransmissions. Note that
during back-off delays, the
transmitting modem will go
into Idle Mode and may
receive RF data. This can have
the effect of increasing the
back-off delay, as the radio cannot return to RF transmit (or retransmit) mode as long as it is
receiving RF data.
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After receiving and acknowledging a packet, the receiving modem will move to the next
frequency and listen for either a retransmission or new data for a specific period of time. Even if
the transmitting modem has indicated that it has no more pending transmit data, it may have not
received the previous ACK, and so it may retransmit the packet (potentially with no delay after
the ACK slot). In this case, the receiving modem will always detect the immediate
retransmission, which will hold off the communications channel and thereby reduce collisions.
Receiving modems acknowledge each retransmission they receive, but they only pass the first
copy of a packet they receive out the UART.
RB and RO parameters are not applied to subsequent packets. This means that once transmission
has begun, it will continue uninterrupted until the DI buffer is empty or the streaming limit (TT)
has been reached. As with the first packet, the payload of each subsequent packet includes up to
the maximum packet size (PK parameter). The transmitting modem checks for more pending
data near the end of each packet.
The streaming limit (TT parameter) specifies the maximum number of bytes that the transmitting
modem will send in one transmission event, which may consist of many packets and retries. If
the TT parameter is reached, the transmitting modem will force a random delay of 1 to RN delay
slots (exactly 1 delay slot if RN is zero). Each packet is counted only once toward TT, no matter
how many times the packet is retransmitted.
Subsequent packets in acknowledged mode are similar to those in streaming mode, with the
addition of an acknowledgement between each packet, and the possibility of retransmissions.
Subsequent packets are sent without an RF initializer, as the receiving modems are already
synchronized to the transmitting modem from the preceding packet(s) and they remain
synchronized for the duration of the transmission event. Each retransmission of a packet includes
an RF initializer.
Once the transmitting modem has sent all pending data or has reached the TT limit, the
acknowledged transmission event is completed. The transmitting modem will not transmit again
for exactly RN delay slots, if the local RN parameter is set to a nonzero value. The receiving
modem will not transmit for a random number of delay slots between 0 and (RN-1), if the local
RN parameter is set to a nonzero value. These delays are intended to lessen congestion following
long bursts of packets from a single transmitting modem, during which several receiving modems
may have themselves become ready to transmit.
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5.3.2. Multi-Streaming Mode
Characteristics:
definition)
Enables exclusive connections (refer to Theory of Operation section for
Supports the passing of large data streams (> 256 bytes) from multiple
remote modems to a base modem (If a complete data stream from a remote
modem is less than 256 bytes, data can be sent from several remotes to a
base location without enabling this mode and latencies will be much less.)
Transmissions never acknowledged (ACK) by receiving modem(s)
Required Parameter Values (TX Modem): MD = 1 (Base), MD = 2 (Remote), RN > 0, RR > 0,
MY ≠ 0xFFFF
Recommended Use: Use this mode in point-to-multipoint networks where remote modems
initiate communications and require exclusive (uninterrupted) connections to the base modem.
Table 5.5.
Sample Network Profile
Modem
Parameter Settings (assume default values for parameters not listed)
Base
ATMD 1
(configure modem as Multi-Stream Base) *
Remotes
ATMD 2
(configure modem as Multi-Stream Remote) *
* When Multi-Streaming is enabled, the following parameters are consequently modified (if they have not
already been modified from their default states): RR, RN, MY, CD, AT and BT. (refer to Table 5.6)
Theory of Operation
When in Multi-Streaming Mode, all remote modems can initiate communications with the base
modem at the same time, but only one remote is granted an exclusive connection. After an
exclusive connection begins, data is transferred exclusively between two modems without
interruption from any other modems in the network.
An exclusive connection is a bi-directional connection that can only be established when in MultiStreaming Mode. An exclusive connection is immune to other remote modems interrupting the
connection and interleaving data (The interleaved data potentially renders the base modem
unable to discern from which remote modem the data was transmitted).
When an exclusive connection is granted to a single remote, the other remotes are notified that
the connection exists. The notification causes the remote modems to postpone transmissions
until the base modem sends notification that the exclusive connection has ended.
Figure 5.7.
Sample Connection Sequence Diagram
CRP = Connection Request Packet
CGP = Connection Grant Packet
DRP = Disconnect Request Packet (not
shown in diagram – applicable when
remote connection is disconnected using
the pin sleep I/O line.
DGP = Disconnect Grant Packet
ACK = Acknowledgement of reception.
Base modem = The central
transmitting/receiving modem in a network
of modems that maintains communications
with remote modems.
Remote modem = A modem in a network
that sends data to and receives data from a
base modem.
Payload = Data contained inside the RF
Data of the RF Packet that originates from a
host to be transmitted over-the-air.
In the connection sequence above, an exclusive connection is first granted to “Remote m”. The
CGP (Connection Grant Packet) is broadcast to all remote modems in the network to
communicate the base in engaged in an exclusive connection. Upon receipt of the CGP
notification, remote modems will wait for a DGP (Disconnect Grant Packet) before attempting
again to send data to the base modem.
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Initiating a Connection
Connection Guidelines:
• A remote modem can only request a connection with the base modem.
• The base modem may hold off or grant a connection request to another modem.
• A remote modem will not try to establish a connection if one already exists.
• A connection fails if no response is received after RR (Retries) CRP packets. After a failure,
whatever condition was causing a connection to be established is cleared. If the condition
was data to be sent, all data in the DI buffer will be flushed. If the condition was DI3
transition, then no connection will be attempted until another correct DI3 transition.
• A global connection cannot fail. (Definition is on next page.)
Once in Multi-Streaming Mode (MD > 0), several events can initiate an exclusive connection:
1.
Remote modem has payload to transmit. After a remote modem receives data from its host,
the modem will attempt to establish a connection with the base modem. The connection is
defined by the remote’s DT (Destination Address) parameter. If another remote has a
connection with the base, no connection will be established until the connection runs its
course. Any remotes requesting a connection will then arbitrate for the next connection. RR
(Retries) and RN (Random back-off) parameters control this arbitration.
2.
Base sets the DT (Destination Address) parameter. When the base modem sets the DT
(Destination Address) parameter, an exclusive connection is immediately initiated with the
remote modem that has a matching DT parameter. After the DT command is sent (If
ATCM=1), the base modem indicates a successful connection with a “CONNECT XXXX” string
where "XXXX" is the remote's address. An unsuccessful connection is indicated with an
“ERROR” string. If the connection is successful, the modem immediately exits AT Command
Mode and data can be sent to and received from the connected remote modem. If an error is
returned, the modem stays in AT Command Mode. If a base is connected to a remote when
the DT command is executed, the current connection is disconnected before a new
connection is created.
3.
DI3 pin (pin 2, SLEEP) is asserted (set low). Both base and remote modems can create a
connection (defined by the current DT (Destination Address) parameter) when the DI3 pin is
asserted (driven high). DR (DI3 Configuration) Command is used to establish this mode. If a
remote asserts DI3, a connection request will be sent when no connection is active. If the
base asserts DI3, a connection will immediately be established with the remote after any
connection.
Initiating a Disconnection
To disconnect, the base modem sends a DGP (disconnect grant packet). A remote modem can
only request a disconnect. The following conditions cause a disconnect:
1.
No over-the-air data sent or received for CE (Connection Inactivity Timeout) time. If no overthe-air data is successfully sent (no acknowledgement received) or received (any good
packet) for CE time, the connection will be dropped. Only a base modem can detect this
condition. Refer to CE Command.
2.
Absolute CB (Connection Duration Timeout). The CB parameter defines an absolute timeout.
A timer is started on the remote units when a connection is established. When the
connection has been active for CB time, the base will close the connection. A remote that
detects this condition will automatically disconnect (it will not send a DRP (disconnect
request packet)). Remotes that monitor a connection between the base and another remote
will disregard any connection after the CB time. Refer to CB Command.
3.
DI3 pin (pin 2, SLEEP) is de-asserted (set high). A base or remote modem can cause a
disconnect by setting the DI3 line high. If no connection is active, the de-assertion is
ignored. A remote will request a disconnect if DI3 is de-asserted and the remote is currently
connected the base. Refer to DR (DI3 Configuration) Command.
4.
A remote or a base modem receives the ATDC (Disconnect) Command.
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Configuration
AT Command Mode
AT command mode is used for all commands on base and remote modems. Binary command
mode is not available when MD = 1 or 2.
The base is in AT command mode when not engaged in an exclusive connection with a remote.
No AT Command Mode sequence is needed. When a base modem is connected to a remote
modem, the AT Command Mode sequence is used to enter AT command mode. The connection
with the remote is maintained. Care should be taken that the CE (Connection Inactivity) timeout
does not occur while in AT Command Mode.
The remote must use the AT command sequence to enter AT Command Mode. When a
connection exists with a base modem, the connection is maintained. Care must be taken that the
CB (Connection Duration) timeout does not occur while in AT Command Mode.
As of firmware version, 4.30, a faster method is available for entering AT Command Mode. If the
BT and AT parameters are set to 0, BT (Guard Time Before) and AT (Guard Time After) times are
set to 6 milliseconds.
Beware that this will also mean that AT Command Mode cannot be entered by manually typing
the AT command sequence (usually “+++”), because the AT time will occur faster than the
characters can be typed.
Auto Configuration
When enabling Multi-Streaming Modes (by setting the MD (RF Mode) parameter to 1 or 2), other
parameter values are automatically modified to support the mode. For example, when the MD
parameter is changed to 1 or 2, the RR parameter is changed to 0x0A (hex). The modification
only occurs if the RR parameter is 0 (its default) before the MD command was executed. If any
other value is found for the RR parameter, the RR parameter will not be changed. Auto
configuration occurs every time the modem is powered-up.
Table 5.6.
Auto Configurations
Parameter changed
when MD = 1 or 2
Condition for modification
to take place (default values)
Resulting Parameter Value
RR (Retries)
If RR = 0
RR = 0x0A (10 decimal)
RN (Delay Slots)
If RN = 0
RN = 5
MY (Source Address)
If MY = 0xFFFF (and MD = 2)
Unique value based on serial number *
CD (DO3 Configuration)
If CD = 0
CD = 3
BT (Guard Time Before)
If BT = 0x0A
BT = 0
AT (Guard Time After)
If AT = 0x0A
AT = 0
* The system requires that each remote have a unique address. The automatic address is based on the serial
number and is not guaranteed unique, although the chances for a duplicate address are 1 in 16,000. No method
currently exists for detecting and reassigning duplicate remote addresses.
Global Connection
The base modem can connect to all remote modems (to send a broadcast message) by
connecting with a DT address of 0xFFFF (hex). There will be no acknowledgements from the
remote radios and each packet from the base will be sent RR times. A remote cannot send
messages to a base during a global connect.
The CGP and DGP packets will be sent RR times to begin and end the global connection
respectively. The connection can be terminated by CE, CB timers, DI3 or ATDC Command as any
other connections.
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Sleep Modes and Connections
Cyclic sleep can be used with the remote modems to conserve power. ST “Time before Sleep”
Parameter defines how long after a disconnect a remote will stay awake. A modem is not allowed
to enter sleep mode when it is engaged in a connection. A modem will wake as defined by SM
parameter and check for an RF message. If a message is detected, the modem will stay awake
only if the message is a connect message from the base for this modem. DI3 (pin 2) wake-up can
be used to wake a remote modem. Usually the connection on DI3 should also be enabled so that
a connection is established on wake-up.
NOTE: The ST (Time Before Sleep) time must be set long enough to account for the time it could take
to make a connection if several remote modems get a connection before a remote’s ST times out.
Pin sleep can also be used with a remote modem. A modem will not be allowed into pin sleep
while a connection is active. Usually the connection on DI3 (DR = 4) should also be enabled so
that a connection is established on wakeup. Pin wake-up could also be used to scan for a
connection at an interval not defined by the cyclic sleep modes.
I/O Passing and Connections
I/O lines can be passed between a remote and base modem by enabling I/O line passing (see the
RT, DR, CD, CO, CS, BK, BO commands). When a connection is not active, the output lines on the
base and remote modems will be in their default state. When a connection is established, the
base and remote output line will be set to reflect the corresponding input lines.
Monitoring Connections
The DO3 pin (RX LED) can be used to show when a connection is active on both remote and base
modems. This is the default condition. This line will be asserted (high) during a connection and
de-asserted (low) when there is no connection.
A base modem can also be set to send the “CONNECT XXXX” string (where “XXXX” is the
connecting modem’s MY (Source Address) parameter) anytime a connection is established. Refer
to CM (Connection Message) Command.
© 2014 Digi International Inc.
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Appendix A: Agency Certifications
FCC Certification
The XStream RF Modem complies with Part 15 of the FCC rules and regulations. Compliance with
the labeling requirements, FCC notices and antenna usage guidelines is required.
To fulfill the FCC Certification requirements, the OEM must comply with the following FCC
regulations:
1.
The system integrator must ensure that the text on the external label provided with this
device is placed on the outside of the final product (Refer to Figure A.1 for 900 MHz
operations. Refer to Figure A.2 for 2.4 GHz operations).
2.
The XStream RF Modem may be used only with Approved Antennas that have been tested
with this modem. (Table A.1 or Table A.2)
FCC Notices:
IMPORTANT: The 9XStream (900 MHz) and 24XStream (2.4 GHz) OEM Modems have been certified by
the FCC for use with other products without any further certification (as per FCC section 2.1091).
Changes or modifications not expressly approved by Digi could void the user’s authority to operate
the equipment.
IMPORTANT: OEMs must test their final product to comply with unintentional radiators (FCC section
15.107 and 15.109) before declaring compliance of their final product to Part 15 of the FCC Rules.
IMPORTANT: The XStream RF Modems have been certified for remote and base radio applications. If
the XStream will be used for portable applications, the device must undergo SAR testing.
This equipment has been tested and found to comply with the limits for a Class B digital device,
pursuant to Part 15 of the FCC Rules. These limits are designed to provide reasonable protection
against harmful interference in a residential installation. This equipment generates, uses and can
radiate radio frequency energy and, if not installed and used in accordance with the instructions,
may cause harmful interference to radio communications. However, there is no guarantee that
interference will not occur in a particular installation. If this equipment does cause harmful
interference to radio or television reception, which can be determined by turning the equipment
off and on, the user is encouraged to try to correct the interference by one or more of the
following measures:
• Re-orient or relocate the receiving antenna.
• Increase the separation between the equipment and receiver.
• Connect the equipment into an outlet on a circuit different from that to which the receiver is
connected.
• Consult the dealer or an experienced radio/TV technician for help.
© 2014 Digi International Inc.
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OEM Labeling Requirements
Label Warning
WARNING
The Original Equipment Manufacturer (OEM) must ensure that FCC labeling
requirements are met. This includes a clearly visible label on the outside of the
final product enclosure that displays the contents shown in the figure below.
Figure A.1.
Required FCC Label for OEM products containing 9XStream (900 MHz) RF Modem
Contains FCC ID: OUR9XSTREAM
The enclosed device complies with Part 15 of the FCC Rules. Operation is subject to the following
two conditions: (1) this device may not cause harmful interference and (2) this device must accept
any interference received, including interference that may cause undesired operation.
Figure A.2.
Required FCC Label for OEM products containing 24XStream (2.4 GHz) RF Modem
Contains FCC ID: OUR-24XSTREAM
The enclosed device complies with Part 15 of the FCC Rules. Operation is subject to the following
two conditions: (1) this device may not cause harmful interference and (2) this device must accept
any interference received, including interference that may cause undesired operation.
Antenna Usage
Antenna Warning
WARNING:
This device has been tested with Reverse Polarity SMA connectors with the
antennas listed in Tables A.1 and A.2 of Appendix A. When integrated in OEM
products, fixed antennas require installation preventing end-users from replacing
them with non-approved antennas. Antennas not listed in the tables must be
tested to comply with FCC Section 15.203 (unique antenna connectors) and Section
15.247 (emissions).
RF Exposure
WARNING:
This equipment is approved only for mobile and base station transmitting devices,
separation distances of (i) 20 centimeters or more for antennas with gains < 6 dBi
or (ii) 2 meters or more for antennas with gains ≥ 6 dBi should be maintained
between the antenna of this device and nearby persons during operation. To
ensure compliance, operation at distances closer than this is not recommended.
The preceding statement must be included as a CAUTION statement in manuals for OEM products
to alert users on FCC RF Exposure compliance.
Digi radio modems are pre-FCC approved for use in fixed base station and mobile applications. As
long as the antenna is mounted at least 20 cm (8 in) from nearby persons, the application is
considered a mobile application. If the antenna will be mounted closer than 20 cm to nearby
persons, then the application is considered “portable” and requires an additional test performed
on the final product. This test is called the Specific Absorption Rate (SAR) testing and measures
the emissions from the radio modem and how they affect the person.
Over 100 additional antennas have been tested and are approved for use with Digi 900 MHz
Radio Modems (including “Mag Mount”, “Dome”, “Multi-path” and “Panel” antennas). Because of
the large number of approved antennas, Digi requests that you send specific information about
an antenna you would like to use with the modem and Digi will evaluate whether the antenna is
covered under our FCC filing.
© 2014 Digi International Inc.
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FCC-Approved Antennas
Table A.1.
Antennas approved for use with 9XStream (900 MHz) RF Modems.
Manufacturer
Part Number
Type
Gain
Application
Min. Separation Distance
*
*
Digi
*
*
Digi
Digi
Digi
Digi
*
*
Digi
Digi
Digi
Digi
*
*
A09-Y8
*
*
A09-Y11 (FCC pending)
A09-F2
A09-F5
A09-F8
*
*
A09-M7
A09-H
A09-HBMM-P5I
A09-QBMM-P5I
6.2 dBi
7.2 dBi
8.2 dBi
9.2 dBi
10.2 dBi
11.2 dBi
2.2 dBi
5.2 dBi
8.2 dBi
9.2 dBi
7.2 dBi
7.2 dBi
2.1 dBi
2.1 dBi
1.9 dBi
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
20 cm
1 cm
1 cm
*
*
Yagi
Yagi
Yagi
Yagi
Yagi
Yagi
Omni Direct.
Omni Direct.
Omni Direct.
Omni Direct.
Omni Direct.
Omni Direct.
1/2 wave antenna
1/2 wave antenna
1/4 wave antenna
1/4 wave integrated wire
antenna
1.9 dBi
Fixed/Mobile **
1 cm
Table A.2.
Antennas approved for use with 24XStream (2.4 GHz) RF Modems.
Manufacturer
Part Number
Type
Gain
Application
Min. Separation Distance
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
Digi
Digi
*
*
*
Digi
Digi
Digi
Digi
Digi
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
*
A24-P8
A24-P13
*
*
*
A24-P19
A24-HABMM-P6I
A24-HBMM-P6I
A24-HABSM
A24-QABMM-P6I
A24-Q1
*
Yagi
Yagi
Yagi
Yagi
Yagi
Yagi
Yagi
Yagi
Yagi
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Omni Direct
Panel
Panel
Panel
Panel
Panel
Panel
Dipole
Dipole
Dipole
Monopole
Monopole
Monopole
6 dBi
8.8 dBi
9 dBi
10 dBi
11 dBi
12 dBi
12.5 dBi
13.5 dBi
15 dBi
2.1 dBi
3 dBi
5 dBi
7.2 dBi
8 dBi
9.5 dBi
10 dBi
12 dBi
15 dBi
8.5 dBi
13 dBi
14 dBi
15 dBi
16 dBi
19 dBi
2.1 dBi
2.1 dBi
2.1 dBi
1.9 dBi
1.9 dBi
1.9 dBi
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
Fixed/Mobile **
2m
2m
2m
2m
2m
2m
2m
2m
2m
20 cm
20 cm
20 cm
2m
2m
2m
2m
2m
2m
2m
2m
2m
2m
2m
2m
20 cm
20 cm
20 cm
20 cm
20 cm
20cm
* FCC-approved antennas not inventoried by Digi – Contact Digi (866) 765-9885 for information.
** Can be approved for portable applications if integrator gains approval through SAR testing
© 2014 Digi International Inc.
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IC (Industry Canada) Certification
Labeling requirements for Industry Canada are similar to those of the FCC. A clearly visible label
on the outside of the final product enclosure must display the following text:
Contains Model 9XStream Radio (900 MHz), IC: 4214A-9XSTREAM
Contains Model 24XStream Radio (2.4 GHz), IC: 4214A 12008
Integrator is responsible for its product to comply with IC ICES-003 and FCC Part 15, Sub. B Unintentional Radiators. ICES-003 is the same as FCC Part 15 Sub. B and Industry Canada
accepts FCC test report or CISPR 22 test report for compliance with ICES-003.
© 2014 Digi International Inc.
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�XStream-PKG-R™ RS-232/485 RF Modem – Product Manual v5.x00
Appendix B: Development Guide
RS-232 Accessories Kit Contents
The accessories listed below are included with XStream RF Modems that carry the “-RA” suffix on
the product number. For example: Part number “X09-019PKC-RA” includes the listed accessories
and part number “X09-019PKC-R” does not. The accessories kit includes hardware and software
needed for developing long range wireless links. For testing the modem’s range, Digi
recommends the purchase of one RF Modem with the accessories and one without.
Table B.1.
Accessories Kit Contents
Item
Qty.
Description
Part Number
Quick Start Guide
1
Familiarizes users with some of the modem’s most
important functions.
MD0019
CD
1
Contains documentation, software and tools needed for
RF operation.
MD0030
XStream-PKG-R™
RS-232/485 RF Modem
1
Long Range RF Modem with RPSMA Connector
X09… or
X19…
Antenna
1
RPSMA, 6" Half-Wave, dipole, articulating
A09-HASM-675
Serial Loopback Adapter
1
Connects to the female RS-232 (DB-9) serial connector of
the Interface Board and can be used to configure the
modem to function as a repeater (for range testing)
JD2D3-CDL-A
NULL Modem Adapter
(male-to-male)
1
Connects to the female RS-232 (DB-9) serial connector of
the Interface Board and can be used to connect the
modem to another DCE (female DB9) device
JD2D2-CDN-A
NULL Modem Adapter
(female-to-female)
1
Used to bypass radios to verify serial cabling is
functioning properly
JD3D3-CDN-A
Male DB-9 to RJ-45
Adapter
1
Facilitates adapting the DB-9 Connector of the Interface
Board to a CAT5 cable (male DB9 to female RJ45)
JE1D2-CDA-A
Female DB-9 to RJ-45
Adapter
1
Facilitates adapting the DB-9 Connector of the Interface
Board to a CAT5 cable (female DB9 to female RJ45)
JE1D3-CDA-A
Power Adapter
1
Allows Interface Board to be powered by a 110 Volt AC
power supply
JP4P2-9V10-6F
RS-232 Cable (6’)
1
Connects interface board to devices having an RS-232
serial port
JD2D3-CDS-6F
© 2014 Digi International Inc.
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Adapters
The XStream Development Kit comes with several adapters that support the following functions:
• Performing Range Tests (Serial Loopback)
• Connecting to other RS-232 DCE and DTE devices (Male-to-Male NULL modem)
• Testing Cables (Female-to-Female NULL modem)
• Connecting to terminal blocks or RJ-45 (for RS-485/422 devices)
Serial Loopback Adapter
Part Number: JD2D3-CDL-A (Red, DB-9 M-F) The serial loopback adapter is used for range
testing. During a range test, the serial loopback adapter configures the radio modem to function
as a repeater by looping serial data back into the radio for retransmission.
Figure B.1.
Serial loopback adapter and pinouts
NULL Modem Adapter (male-to-male)
Part Number: JD2D2-CDN-A (Black, DB-9 M-M) The male-to-male NULL modem adapter is used
to connect two DCE devices. A DCE device connects with a straight-through cable to the male
serial port of a computer (DTE).
Figure B.2.
Male NULL modem adapter and pinouts
Figure B.3.
Example of a Digi Radio Modem (DCE Device) connecting to another DCE device)
NULL Modem Adapter (female-to-female)
Part Number: JD3D3-CDN-A (Gray, DB-9 F-F) The female-to-female NULL modem adapter is
used to verify serial cabling is functioning properly. To test cables, insert the female-to-female
NULL modem adapter in place of a pair of modem assemblies (XIB-R-R interface board +
XStream Modem) and test the connection without radio modems in the connection.
Figure B.4.
Female NULL modem adapter and pinouts
For use in RS-485/422 systems:
DB-9 to RJ-45 adapters are
illustrated in the RS-485/422
Connection Guidelines section.
© 2014 Digi International Inc.
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Antennas
(Refer to Appendix A for a list of FCC-Approved Antennas)
Factors that determine wireless link range:
• Ambient RF noise (interference)
• Line-of-sight obstructions
• Transmit power
• Receive sensitivity
• Antenna configuration
• XStream Antenna Connector Options
To comply with the FCC rules and obtain a “modular” certification, it is required that XStream
Modems utilize a “non-standard” connector. This is to ensure the modems are used only with
approved antennas.
RPSMA
The Reverse Polarity SMA (RPSMA) connector uses the same body as
a regular SMA connector. In order to be a “non standard” connector,
the gender of the center conductor is changed. The female RPSMA
actually has a male center conductor.
Antenna Cables
RF cables are typically used to connect a radio installed in a cabinet to an antenna mounted
externally. As a general rule, it is best to keep the RF cable as short as possible. All cables
promote signal loss which is usually measured in dB loss per 100 ft. Digi provides LMR-195 rated
cables. Common cables and dB losses are included in this table:
Table B.2.
Potential Signal Strength Loss due to Antenna Cable Length
Cable
Type
Loss at 900 MHz per 100’
(loss per 100m)
Loss at 2.4 GHz per 100’
(loss per 100m)
Diameter
RG-58
14.5 dB (47.4 dB)
25.3 dB (83.2 dB)
0.20” (4.95 mm)
RG-174
25.9 dB (85.0 dB)
44.4 dB (145.8 dB)
0.10” (2.54 mm)
RG-316
24.7 dB (81.0 dB)
42.4 dB (139.0 dB)
0.10” (2.59 mm)
LMR-195
11.1 dB (36.5 dB)
19.0 dB (62.4 dB)
0.20” (4.95 mm)
LMR-240
7.6 dB (24.8 dB)
12.9 dB (42.4 dB)
0.24“ (6.10 mm)
LMR-600
2.5 dB (8.2 dB)
4.4 dB (14.5 dB)
0.59” (15.0 mm)
© 2014 Digi International Inc.
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Appendix C: Additional Information
1-Year Warranty
XStream RF Modems from Digi International Inc. (the "Product") are warranted against defects in
materials and workmanship under normal use, for a period of 1-year from the date of purchase. In
the event of a product failure due to materials or workmanship, Digi will repair or replace the
defective product. For warranty service, return the defective product to Digi, shipping prepaid, for
prompt repair or replacement.
The foregoing sets forth the full extent of Digi's warranties regarding the Product. Repair or
replacement at Digi's option is the exclusive remedy. THIS WARRANTY IS GIVEN IN LIEU OF ALL
OTHER WARRANTIES, EXPRESS OR IMPLIED, AND DIGI SPECIFICALLY DISCLAIMS ALL
WARRANTIES OF MERCHANTABILITY OR FITNESS FOR A PARTICULAR PURPOSE. IN NO
EVENT SHALL DIGI, ITS SUPPLIERS OR LICENSORS BE LIABLE FOR DAMAGES IN EXCESS OF
THE PURCHASE PRICE OF THE PRODUCT, FOR ANY LOSS OF USE, LOSS OF TIME,
INCONVENIENCE, COMMERCIAL LOSS, LOST PROFITS OR SAVINGS, OR OTHER
INCIDENTAL, SPECIAL OR CONSEQUENTIAL DAMAGES ARISING OUT OF THE USE OR
INABILITY TO USE THE PRODUCT, TO THE FULL EXTENT SUCH MAY BE DISCLAIMED BY
LAW. SOME STATES DO NOT ALLOW THE EXCLUSION OR LIMITATION OF INCIDENTAL OR
CONSEQUENTIAL DAMAGES. THEREFOR, THE FOREGOING EXCLUSIONS MAY NOT APPLY
IN ALL CASES. This warranty provides specific legal rights. Other rights which vary from state to
state may also apply.
Ordering Information
Figure C.1 Digi RF Modem Part Numbers Key
© 2014 Digi International Inc.
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Contact Digi
If you need assistance, contact technical support:
Documentation:
www.digi.com/support/
Technical Support:
Phone
Online
© 2014 Digi International Inc.
(866) 765-9885 toll-free U.S. and Canada
(801) 765-9885 Worldwide
8:00 am – 5:00 pm (U.S. Central Time)
www.digi.com/support/eservice
60
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