Joint Tactical Radio System: Difference between revisions
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{{ | {{Image|JTRSedge.png|right|250px|JTRS as the "last mile" of the Global Information Grid.}} | ||
Replacing a wide range of military | Replacing a wide range of military radios and communications security devices is the '''Joint Tactical Radio System (JTRS),''' (pronounced "jitters" by military personnel). JTRS is a large-scale project to deploy software-defined radio (SDR) technology in the U.S. and allied militaries. | ||
Under the U.S. Department of Defense, the applications that need wireless radio communications connectivity form the Global Information Grid (GIG), with the GIG being transmitted principally over fixed optical networks with massive bandwidth and extremely low error rates. In contrast, the JTRS edge networks will have limited bandwidth and not only electrically noisy environments, but may be under active electronic warfare|electronic attack. The edge networks will not only not be fixed, but may be moving at high speed, and the overall networks must be to cope with the occasional exceptionally high speed separation of the pieces of a host or router into a rapidly expanding fireball. | |||
Under the | |||
JTRS is the | JTRS is the locality of networks|"last mile" that connects the warfighters in the field to one another, and to their fixed facilities. JTRS equipment uses mobile ad hoc networking (MANET) with digital payloads encapsulated in Internet Protocol over a wide range of radio frequencies and waveforms. <ref name=MCC-GIG-Edge>{{citation | url = http://jpeojtrs.mil/files/news/03Oct06_JTRS_OVERVVIEW_MILCOM06_v12.pdf | ||
| journal = Military Communications Conference | | journal = Military Communications Conference | ||
| date = October 23-35, 2006 | | date = October 23-35, 2006 | ||
| title = Joint Tactical Radio System -- Connecting the GIG to the Tactical Edge | first1= Rich | last1 = North | first2 = Norm | last2 = Browne | first3 =Len |last3= Schiavone}}</ref> | | title = Joint Tactical Radio System -- Connecting the GIG to the Tactical Edge | first1= Rich | last1 = North | first2 = Norm | last2 = Browne | first3 =Len |last3= Schiavone}}</ref> | ||
Software-defined radio (SDR) is a radical departure from traditional | Software-defined radio (SDR) is a radical departure from traditional radio, in which many of the discrete electronic components, and even fundamental techniques such as superheterodyne operation, are replaced by computer-controlled digital signal processors.<ref name=JPRS-JPEO>{{citation | ||
| url = http://jpeojtrs.mil/ | | url = http://jpeojtrs.mil/ | ||
| title = Joint Tactical Radio System | | title = Joint Tactical Radio System | ||
| author = Joint Program Executive Office}}</ref> | | author = Joint Program Executive Office}}</ref> | ||
==Program management== | ==Program management== | ||
The proof-of-concept of SDR technology was | The proof-of-concept of SDR technology was the Army Special Operations Command AN-|AN/PRC-148 inter/intra-team radio for United States Army Special Forces, and the U.S. Army became the executive agent for what was becoming a massive and high-risk program. Versions of this SDR were also deployed by the United States Marine Corps|U.S. Marine Corps in a variety applications, the family being called the Tactical Handheld Radio (THHR).<ref name=USMC-THRR>{{citation | ||
| title = Tactical Handheld Radio (THHR), AN/PRC-148 | |||
| url = http://www.marcorsyscom.usmc.mil/sites/cins/CNS/Tactical%20Radios/PRC_148.html | |||
| author = United States Marine Corps|U.S. Marine Corps}}</ref> Used, at first, by reconnaissance units, it became an slightly less than 2 pound alternative to the PRC-119|AN/PRC-119, a backpack squad SINCGARS radio weighing approximately 22 pounds with batteries. The Marine vehicle-mounted version of this radio was designated the AN-|AN/VRC-111. It has built-in encryption and is interoperable with SINCGARS and HAVE QUICK II in both single-channel and frequency agility|frequency hopping modes. | |||
Even closer to JTRS standards is the AN/PRC-117. | |||
On March 31, 2006, Ken Krieg, undersecretary of defense for acquisition, technology and logistics, changed the program "big bang" procurement to an incremental one, lowering the risk and the capabilities of the radios that will initially be obtained. <ref name=Walker2006-07-10>{{citation | |||
| title = Restructuring Cuts Cost, Puts Radio Program Back on Track | | title = Restructuring Cuts Cost, Puts Radio Program Back on Track | ||
| first = Karen | last = Walker | | first = Karen | last = Walker | ||
Line 22: | Line 30: | ||
| journal = C4ISR Journal}}</ref> Still, while interoperability testing has been scheduled, not all the specifications have been set. | | journal = C4ISR Journal}}</ref> Still, while interoperability testing has been scheduled, not all the specifications have been set. | ||
Originally, each military service had a separate development program for a group of physical | Originally, each military service had a separate development program for a group of physical implementations, called a "cluster", with the joint program office in charge of the software communications architecture and software waveforms used by all the radios. Problems with the Army-led Cluster 1 program to develop radios for ground vehicles and rotorcraft forced the restructuring. | ||
At a May 3, 2006 briefing, the JTRS | At a May 3, 2006 briefing, the JTRS executive officer, said that trying to bring out all the systems at once would take about USD $4 billion more than was in the research and development budget. The new method separated systems into phases based on difficulty, assuming that each new phase would learn from the success of the less complex phases that preceded it. The earlier system put the radios for Army helicopters and Army trucks under the same leadership because they were Army. Unfortunately, that meant five different programs that dealt with helicopters, rather than concentrating the knowledge of radios for flight. Under the new JTRS plan, the groupings are: | ||
#ground: land vehicles and Handheld, Manpack and Small form-fit (HMS); HMS leading to the | #ground: land vehicles and Handheld, Manpack and Small form-fit (HMS); HMS leading to the Future Combat System. | ||
#airborne and maritime: helicopters airborne (including helicopters), maritime and fixed-site Airborne and Maritime Fixed station (AMF), and the multifunctional information distribution system (MIDS). | #airborne and maritime: helicopters airborne (including helicopters), maritime and fixed-site Airborne and Maritime Fixed station (AMF), and the multifunctional information distribution system (MIDS). | ||
#network enterprise: | #network enterprise: routers, application gateways, and waveform specification | ||
#special radio systems: Special operations, concentrating on upgrading the hand-held multiband inter/intra-team radio | #special radio systems: Special operations, concentrating on upgrading the hand-held multiband inter/intra-team radio to the AN/PRC-148 (JEM)<ref name=AN/PRC-148-JEM>{{citation | ||
| title = AN/PRC-148 (JEM) JTRS Enhanced Multi-Band Inter/Intra Team Radio | |||
| url = http://www.defense-update.com/products/j/JTRS-JEM.htm | |||
| journal = Defense Update | |||
| year=2004 | |||
| issue= 4}}</ref> | |||
These groupings matrix against a set of physical packaging requirements. | These groupings matrix against a set of physical packaging requirements. | ||
==Radio set physical implementations== | ==Radio set physical implementations== | ||
Most of the basic electronics of JTRS implementations will be common, but they will vary in | Most of the basic electronics of JTRS implementations will be common, but they will vary in form factor, or physical packaging for different applications. | ||
26 different form factors were identified as being in military use, and, with the smaller size and programmability of the JTRS electronics, reduced to 13 form factors: | 26 different form factors were identified as being in military use, and, with the smaller size and programmability of the JTRS electronics, reduced to 13 form factors: | ||
:#Manpack | :#Manpack | ||
Line 39: | Line 53: | ||
:#Airborne, Maritime and Fixed Site Small Airborne (AMF-SA) | :#Airborne, Maritime and Fixed Site Small Airborne (AMF-SA) | ||
:#AMF-MF (Maritime/fixed site) | :#AMF-MF (Maritime/fixed site) | ||
:#Small form factor (SFF) A&H (for Intelligent Munitions Systems and | :#Small form factor (SFF) A&H (for Intelligent Munitions Systems and Unattended Ground Sensors (UGS) in the Future Combat Systems (FCS)) | ||
:#SFF B, C and I (for Ground Soldier Systems) | :#SFF B, C and I (for Ground Soldier Systems) | ||
:#SFF D (for aerial systems) | :#SFF D (for aerial systems) | ||
:#SFF J (for Networked Missile Launcher System in FCS) | :#SFF J (for Networked Missile Launcher System in FCS) | ||
== | |||
In electronics, a waveform generically describes the nature of an electronic signal, typically as viewed in the | ==Waveforms== | ||
In electronics, a waveform generically describes the nature of an electronic signal, typically as viewed in the time domain on an oscilloscope. JTRS uses "JTRS waveform|waveform" in a broader context: "the entire set of radio and/or communications functions that occur from the user input to the radio frequency output and vice versa. JTRS waveform implementation consists of a Waveform Application Code, Radio Set Devices and Radio System Applications. Every waveform involves the tuning of a mobile ad hoc networking "to its peculiar environment. These protocols interact with the IP layers in the radios to hide the network mobility and dynamics from the external commercial-based networking equipment to facilitate interoperability."<ref name=MCC-GIG-Edge /> | |||
Originally, there were 32 JTRS waveforms which have since been reduced to the following list:<ref name=SPAWAR-Waveform>{{citation | Originally, there were 32 JTRS waveforms which have since been reduced to the following list:<ref name=SPAWAR-Waveform>{{citation | ||
| author = | | author = United States Navy Space and Naval Systems Warfare Command (SPAWAR) | ||
| title = JPEO JTRS - What is a waveform? | | title = JPEO JTRS - What is a waveform? | ||
| url = http://enterprise.spawar.navy.mil/body.cfm?type=c&category=27&subcat=80}}</ref> | | url = http://enterprise.spawar.navy.mil/body.cfm?type=c&category=27&subcat=80}}</ref> | ||
* | *Operational | ||
* | **UHF amplitude modulation|amplitude modulated/frequency modulation|frequency modulated (AM/FM) phase shift keying (PSK) <ref name=MIL-STD-188-181 /> <ref name=MIL-STD-188-243 /> | ||
**VHF FM: VHF FM operates in the 30-88 MHZ frequency range. VHF FM supports analog voice and digital voice at 16 KBPS. <ref name=MIL-STD-188-242>{{citation| id = MIL-STD-188-242| title = Interoperability and Performance Standards for Tactical Single Channel Very High Frequency (VHF) Radio Equipment | |||
|url = http://assist.daps.dla.mil/quicksearch/basic_profile.cfm?ident_number=35584 | |||
* | |date = June 20, 1985}}</ref> | ||
**HAVE QUICK II frequency agility radio system: carries, but in UHF rather than HF, the basic types of user information that SINCGARS provides.<ref name=MIL-STD-188-220 /> <ref name=MIL-STD-188-243>{{citation | |||
**HAVE QUICK II | |||
<ref name=MIL-STD-188-243>{{citation | |||
| id = MIL-STD-188-243 | | id = MIL-STD-188-243 | ||
| title = Interoperability and Performance Standards for Tactical Single Channel Ultra High Frequency (UHF) Radio Communications | | title = Interoperability and Performance Standards for Tactical Single Channel Ultra High Frequency (UHF) Radio Communications | ||
| date = March 15, 1988 | | date = March 15, 1988 | ||
}}</ref> | }}</ref> <ref name=JIEO-9120A>{{citation|id = JIEO-9120A| title = UHF HAVEQUICK/SATURN Waveform Technical Interface Specification}}</ref> | ||
<ref name=JIEO-9120A>{{citation|id = JIEO-9120A| title = UHF HAVEQUICK/SATURN Waveform Technical Interface Specification}}</ref> | **ITU frequency bands|High Frequency (HF) Independent Side Band (ISB) with Automatic Link Establishment (ALE) | ||
** | **HF Single Side Band (SSB) with ALE | ||
* | **STANAG 5066 HF Data Protocol | ||
|url = http:// | **STANAG 4529 HF narrowband modem | ||
| | **ITU frequency bands|Ultra High Frequency (UHF)<ref name=240-320 /> satellite communications (SATCOM) <ref name=MIL-STD-188-181>{{citation |id = MIL-STD-188-181 | date = D revision of 30 January 2004 | title = Interoperability Standard for Access | ||
to 5 kHz and 25 kHz UHF Satellite Communications Channels}}</ref><ref name=MIL-STD-188-182>{{citation | id = MIL-STD-188-182| date = 30 January 2004 | title = Interoperability Standard for UHF SATCOM DAMA Orderwire Messages and Protocols}}</ref><ref name=MIL-STD-188-183>{{citation | id = MIL-STD-188-183| date = 18 September 1992 | title = Interoperability Standard for 25 kHz UHF TDMA/DAMA Terminal Waveform}}</ref><ref name=MIL-STD-188-184>{{citation | id = MIL-STD-188-184| date = 20 August 1999 | title = Interoperability and Performance Standard for Data Control Waveform}}</ref> | |||
**Link-16 for the Joint Tactical Information Distribution System: 960 to 1215 MHZ frequency range. LINK 16 will support voice mode of operation at 2.4 and 16 KBPS and data with error control#forward error correction|forward error correction (FEC) at rates of 28.8 KBPS to 1.137 MBPS. Link 16 will be compliant with <ref name=MIL-STD-6016>MIL-STD 6016 for Tactical Command, Control, Communications, and Intelligence (C4I) systems that implement the Link 16 Tactical Data Link (TDL)</ref> and NATO Standardization Agreement (STANAG) 5516</ref> | |||
**Enhanced Position Location Reporting System (EPLRS): 420-450 MHZ frequency range. EPLRS will start at a 57 Kbps data rate, and then, through a value engineering change process, upgrade to 228 Kbps. | |||
*In development or early deployment | |||
**Soldier Radio Waveform (SRW): 1.755-1.850 GHZ frequency range. The Soldier Radio and wireless local area network (WLAN) with digital 16 KBPS voice and data at 1 MBPS.<ref>The WLAN will be compliant with IEEE 802.11b, 802.11e and 802.11g</ref> | |||
**Mobile User Objective System (satellite)|Mobile User Objective System (MUOS): a narrowband (i.e., 2.4 to 64 Kbps) satellite communications system, <ref name=240-320>Operating in the 240-320 MHz range, at the high end of VHF and the low end of UHF</ref> replacing the current UHF Follow-On (satellite)|UHF Follow-On (UFO) system | |||
**SINCGARS Enhanced SINCGARS Improvement Program (ESIP) operates in the 30-88 MHz VHF frequency band, for data, analog voice, and 16Kbps digital voice. <ref name=MIL-STD-188-220> MIL-STD 188-220 for Digital Message Transfer Device</ref><ref>MIL-STD MIL-STD-2045-47001 for Connectionless Data Transfer Application Layer Standard Subsystems for Combat Net Radio (CNR) systems</ref> <ref name=MIL-STD-188-241>{{citation | id = MIL-STD 188-241-1/2 (classified SECRET)|title = Frequency Hopping Standard for Very High Frequency (VHF) Frequency Hopping Radios | date = November 2006}}</ref> | |||
*In design | |||
**Joint Airborne Networking–Tactical Edge (JAN-TE): The precise technology for this part of the network, which will connect manned and unmanned aircraft, as well as precision-guided munitions, has not been selected, although the Tactical Targeting Network Technology waveform is under active consideration.<ref name=Walker2006-07-10 /> | |||
**Wideband Networking Waveform (WNW): still not fully defined, the waveform will operate in the 2 MHZ to 2 GHZ frequency range at up to 5 MBPS networked throughput. This is sponsored by the Army, and the Air Force has a competing alternative called Tactical Targeting Network (TTNT)<ref name=Friedman>{{citation | |||
| title = The Naval Institute guide to world naval weapon systems | |||
| author = Norman Friedman | |||
| url =http://books.google.com/books?id=4S3h8j_NEmkC&pg=PA43&lpg=PA43&dq=Family+of+Advanced+Beyond+Line-of-Sight-Terminal&source=bl&ots=hHVvOW_Y6Z&sig=vAPr-W0YY61BWXDmYmvTluEsAW0&hl=en&ei=1aU_Su35F5vMMsHMlKAO&sa=X&oi=book_result&ct=result&resnum=5 | |||
| year = 2006 | |||
| publisher = Naval Institute Press}}, pp. 43-44</ref> | |||
==References== | ==References== | ||
{{reflist|2}} | {{reflist|2}}[[Category:Suggestion Bot Tag]] |
Latest revision as of 12:00, 6 September 2024
This article may be deleted soon. | ||
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Replacing a wide range of military radios and communications security devices is the Joint Tactical Radio System (JTRS), (pronounced "jitters" by military personnel). JTRS is a large-scale project to deploy software-defined radio (SDR) technology in the U.S. and allied militaries. Under the U.S. Department of Defense, the applications that need wireless radio communications connectivity form the Global Information Grid (GIG), with the GIG being transmitted principally over fixed optical networks with massive bandwidth and extremely low error rates. In contrast, the JTRS edge networks will have limited bandwidth and not only electrically noisy environments, but may be under active electronic warfare|electronic attack. The edge networks will not only not be fixed, but may be moving at high speed, and the overall networks must be to cope with the occasional exceptionally high speed separation of the pieces of a host or router into a rapidly expanding fireball. JTRS is the locality of networks|"last mile" that connects the warfighters in the field to one another, and to their fixed facilities. JTRS equipment uses mobile ad hoc networking (MANET) with digital payloads encapsulated in Internet Protocol over a wide range of radio frequencies and waveforms. [1] Software-defined radio (SDR) is a radical departure from traditional radio, in which many of the discrete electronic components, and even fundamental techniques such as superheterodyne operation, are replaced by computer-controlled digital signal processors.[2] Program managementThe proof-of-concept of SDR technology was the Army Special Operations Command AN-|AN/PRC-148 inter/intra-team radio for United States Army Special Forces, and the U.S. Army became the executive agent for what was becoming a massive and high-risk program. Versions of this SDR were also deployed by the United States Marine Corps|U.S. Marine Corps in a variety applications, the family being called the Tactical Handheld Radio (THHR).[3] Used, at first, by reconnaissance units, it became an slightly less than 2 pound alternative to the PRC-119|AN/PRC-119, a backpack squad SINCGARS radio weighing approximately 22 pounds with batteries. The Marine vehicle-mounted version of this radio was designated the AN-|AN/VRC-111. It has built-in encryption and is interoperable with SINCGARS and HAVE QUICK II in both single-channel and frequency agility|frequency hopping modes. Even closer to JTRS standards is the AN/PRC-117. On March 31, 2006, Ken Krieg, undersecretary of defense for acquisition, technology and logistics, changed the program "big bang" procurement to an incremental one, lowering the risk and the capabilities of the radios that will initially be obtained. [4] Still, while interoperability testing has been scheduled, not all the specifications have been set. Originally, each military service had a separate development program for a group of physical implementations, called a "cluster", with the joint program office in charge of the software communications architecture and software waveforms used by all the radios. Problems with the Army-led Cluster 1 program to develop radios for ground vehicles and rotorcraft forced the restructuring. At a May 3, 2006 briefing, the JTRS executive officer, said that trying to bring out all the systems at once would take about USD $4 billion more than was in the research and development budget. The new method separated systems into phases based on difficulty, assuming that each new phase would learn from the success of the less complex phases that preceded it. The earlier system put the radios for Army helicopters and Army trucks under the same leadership because they were Army. Unfortunately, that meant five different programs that dealt with helicopters, rather than concentrating the knowledge of radios for flight. Under the new JTRS plan, the groupings are:
These groupings matrix against a set of physical packaging requirements. Radio set physical implementationsMost of the basic electronics of JTRS implementations will be common, but they will vary in form factor, or physical packaging for different applications. 26 different form factors were identified as being in military use, and, with the smaller size and programmability of the JTRS electronics, reduced to 13 form factors:
WaveformsIn electronics, a waveform generically describes the nature of an electronic signal, typically as viewed in the time domain on an oscilloscope. JTRS uses "JTRS waveform|waveform" in a broader context: "the entire set of radio and/or communications functions that occur from the user input to the radio frequency output and vice versa. JTRS waveform implementation consists of a Waveform Application Code, Radio Set Devices and Radio System Applications. Every waveform involves the tuning of a mobile ad hoc networking "to its peculiar environment. These protocols interact with the IP layers in the radios to hide the network mobility and dynamics from the external commercial-based networking equipment to facilitate interoperability."[1] Originally, there were 32 JTRS waveforms which have since been reduced to the following list:[6]
References
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