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Rockwell B-1 Lancer

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B-1 Lancer
Top view of B-1B in-flight with white clouds scattered underneath. Its wings are swept fully forward as the gray aircraft flies over the ocean.
A B-1B flying over the Pacific Ocean.
Role Supersonic heavy strategic bomber
National origin United States
Manufacturer North American Rockwell/Rockwell International
Boeing
First flight 23 December 1974
Introduction 1 October 1986
Status In service
Primary user United States Air Force
Produced 1973–74, 1983–88
Number built B-1A: 4
B-1B: 100
Unit cost
US$283.1 million in 1998 (B-1B)[1]

The Rockwell B-1 Lancer[N 1] is a four-engine supersonic variable-sweep wing, jet-powered heavy strategic bomber used by the United States Air Force (USAF). It was first envisioned in the 1960s as a supersonic bomber with Mach 2 speed, and sufficient range and payload to replace the Boeing B-52 Stratofortress. It was developed into the B-1B, primarily a low-level penetrator with long range and Mach 1.25 speed capability at high altitude. It is commonly called the "Bone" (originally from "B-One").

Designed by Rockwell International (now part of Boeing), development was delayed multiple times over its history due to changes in the perceived need for manned bombers. The initial B-1A version was developed in the early 1970s, but its production was canceled, and only four prototypes were built. The need for a new platform once again surfaced in the early 1980s, and the aircraft resurfaced as the B-1B version with the focus on low-level penetration bombing. However, by this point, development of stealth technology was promising an aircraft of dramatically improved capability. Production went ahead as the B version would be operational before the "Advanced Technology Bomber" (which became the B-2 Spirit), during a period when the B-52 would be increasingly vulnerable. The B-1B entered service in 1986 with the USAF Strategic Air Command (SAC) as a nuclear bomber.

In the early 1990s, following the Gulf War and concurrent with the disestablishment of SAC and its reassignment to the newly formed Air Combat Command (ACC), the B-1B was converted to conventional bombing use. It first served in combat during Operation Desert Fox in 1998 and again during the NATO action in Kosovo the following year. The B-1B has supported U.S. and NATO military forces in Afghanistan and Iraq. The B-1B is expected to continue to serve into the 2030s, with the Long Range Strike Bomber to start supplementing the B-1B in 2030.

Development

Background

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In 1955 the U.S. Air Force issued requirements for a new bomber combining the payload and range of the Boeing B-52 Stratofortress with the Mach 2 maximum speed of the Convair B-58 Hustler.[2] In December 1957, the U.S. Air Force selected North American Aviation's proposal to replace the B-52 with the B-70 Valkyrie.[3] The Valkyrie was a six-engine bomber that could reach Mach 3 speeds at high altitude (Lua error in Module:Convert at line 1851: attempt to index local 'en_value' (a nil value).)[4] to avoid interceptor aircraft, the only effective anti-bomber weapon in the 1950s.[5] Soviet aircraft were already unable to intercept the high-flying Lockheed U-2;[6] the Valkyrie would fly at similar altitudes but much higher speeds.[5] In combat, the B-70 was expected to simply fly right by the defenders.

By the late 1950s, however, anti-aircraft surface-to-air missiles (SAMs) could threaten high-altitude aircraft,[7] as demonstrated by the 1960 downing of Gary Powers's U-2.[8] The USAF Strategic Air Command (SAC) were aware of these development and had begun moving its bombers to low-level penetration even before the U-2 downing. This tactic greatly reduces radar detection distances by use of terrain masking; using features of the terrain like hills and valleys, the line-of-sight from the radar to the bomber can be broken, rendering the radar (and human observers) incapable of seeing the target.[9] Even at somewhat higher altitudes, radar systems of the era were subject to "clutter" from stray returns from the ground and other objects, requiring a minimum angle above the ground to be effective. Bombers flying at low altitudes could remain under these angles simply by keeping their distance from the radar sites. This combination of effects made SAMs of the era ineffective against low-flying aircraft.[9][10] The same effects also meant that low flying aircraft were difficult to detect by higher flying interceptor aircraft, since their radar systems could not readily pick out opposing aircraft against the clutter from ground reflections (lack of look-down/shoot-down capability).

The switch from high-altitude to low-altitude flight profiles severely affected the B-70, whose design was highly tuned to provide the desired high-altitude performance. Planners outlined a series of low-level profiles for the B-70, but higher aerodynamic drag at low level limited the B-70 to subsonic speed while dramatically decreasing its range.[7] The result would be an aircraft with somewhat higher subsonic speed, but less range than the B-52 it was meant to replace. Unsuited for the new low-altitude role, and because of a growing shift to the intercontinental ballistic missile (ICBM) force, the B-70 bomber program was canceled in 1961 by President John F. Kennedy,[5][11] and the two XB-70 prototypes were used in a supersonic research program.[12]

Although never intended for the low-level role, the B-52's flexibility allowed it to outlast its intended successor as the nature of the air war environment changed. The B-52's huge fuel load allowed it to operate at lower altitudes for longer times, and the large airframe allowed the addition of improved radar jamming and deception suites to deal with radars.[13] During the Vietnam War the concept that all future wars would be nuclear was turned on its head, and the "big belly" modifications increased the B-52's total bomb load to 60,000 pounds (27,000 kg),[14] turning it into a powerful tactical aircraft which could be used against ground troops along with strategic targets from high altitudes.[10] The much smaller bomb bay of the B-70 would have made it much less useful in this role.

Design studies and delays

Although effective, the B-52 was not ideal for the low-level role. This led to a number of aircraft designs known as penetrators, which were tuned specifically for long-range low-altitude flight. The first of these designs to see operation was the supersonic F-111 fighter-bomber, which used variable-sweep wings for tactical missions.[15] Similar aircraft also emerged for other users as well, notably the BAC TSR-2, and later, Panavia Tornado and Sukhoi Su-24. A number of studies on a strategic-range counterpart followed.

The first post-B-70 strategic penetrator study was known as the Subsonic Low Altitude Bomber (SLAB), which was completed in 1961. This produced a design that looked more like an airliner than a bomber, with a large swept wing, T-tail and large high-bypass engines.[16] This was followed by the similar Extended Range Strike Aircraft (ERSA), which added a variable-sweep wing, then in vogue in the aviation industry. ERSA envisioned a relatively small aircraft with a 10,000 pounds (4,500 kg) payload and a range of 8,750 nautical miles (16,200 kilometres), with 2,500 nmi (4,600 km) being flown at low altitudes. In August 1963 the similar Low-Altitude Manned Penetrator (LAMP) design was completed, which called for an aircraft with a 20,000 pounds (9,100 kg) bomb load and somewhat shorter range of 7,150 nmi (13,240 km).[17][18]

These all culminated in the October 1963 Advanced Manned Precision Strike System (AMPSS), which led to industry studies at Boeing, General Dynamics, and North American.[19][20] In mid-1964, the USAF had revised its requirements and retitled the project as Advanced Manned Strategic Aircraft (AMSA), which differed from AMPSS primarily in that it also demanded a high-speed high-altitude capability, similar to that of the existing Mach 2 class Convair B-58 Hustler.[21] Given the lengthy series of design studies, Rockwell engineers joked that the new name actually stood for "America's Most Studied Aircraft".[22][23]

The arguments that led to the cancellation of the B-70 program had led some to question the need for a new strategic bomber of any sort. The U.S. Air Force was adamant about retaining bombers as part of the nuclear triad concept that included bombers, ICBMs, and submarine-launched ballistic missiles (SLBMs) in a combined package that complicated any potential defense. They argued that the bomber was needed to attack hardened military targets and to provide a safe counterforce option because the bombers could be quickly launched into safe loitering areas where they could not be attacked. However, the introduction of the SLBM mooted the mobility and survivability argument, and a newer generation of ICBMs, such as the Minuteman III, had the accuracy and speed needed to attack point targets. During this time, ICBMs were seen as a less costly option based on their lower unit cost,[24] but development costs were much higher.[7] Secretary of Defense Robert McNamara preferred ICBMs over bombers for the Air Force portion of the deterrent force[25] and felt a new expensive bomber was not needed.[26][27] McNamara limited the AMSA program to studies and component development beginning in 1964.[27]

Program studies continued; IBM and Autonetics were awarded AMSA advanced avionics study contracts in 1968.[27][28] McNamara remained opposed to the program in favor of upgrading the existing B-52 fleet and adding nearly 300 FB-111s for shorter range roles then being filled by the B-58.[10][27] He again vetoed funding for AMSA aircraft development in 1968.[28]

B-1A program

AN/APQ-140 radar for the B-1A[29]

President Richard Nixon reestablished the AMSA program after taking office, keeping with his administration's flexible response strategy that required a broad range of options short of general nuclear war.[30] Nixon's Secretary of Defense, Melvin Laird, reviewed the programs and decided to lower the numbers of FB-111s, since they lacked the desired range, and recommended that the AMSA design studies be accelerated.[30] In April 1969, the program officially became the B-1A.[10][30] This was the first entry in the new bomber designation series, first created in 1962. The Air Force issued a request for proposals in November 1969.[31]

 A B-1A flying with its wings swept back, showing its underside
B-1A Prototype 4 showing its underside in 1981
 The nose section of a B-1A on display with outline of the ejection capsule denoted
B-1A nose section with ejection capsule denoted. Three of the four B-1As were fitted with escape capsules.

Proposals were submitted by Boeing, General Dynamics and North American Rockwell in January 1970.[31][32] In June 1970, North American Rockwell's design was selected and was awarded a development contract.[31] The original program called for two test airframes, five flyable aircraft, and 40 engines. This was cut in 1971 to one ground and three flight test aircraft.[33] The company changed its name to Rockwell International and named its aircraft division North American Aircraft Operations in 1973.[34] A fourth prototype, built to production standards, was ordered in the fiscal year 1976 budget. Plans called for 240 B-1As to be built, with initial operational capability set for 1979.[35]

Rockwell's design featured a number of features common to 1960s U.S. designs. Among these was the use of a "crew capsule" that ejected as a unit during emergencies, which was introduced to improve survivability in the case of an ejection at high speed. Additionally, the design featured large variable-sweep wings in order to provide both high lift during takeoff and landing, and low drag during a high-speed dash phase.[36] With the wings set to their widest position the aircraft had considerably better lift and power than the B-52, allowing it to operate from a much wider variety of bases. Penetration of the Soviet Union's defenses would take place at supersonic speed, crossing them as quickly as possible before entering into the less defended "heartland" where speeds could be reduced again.[36] The large size and fuel capacity of the design would allow the "dash" portion of the flight to be relatively long.

In order to achieve the required Mach 2 performance at high altitudes, the exhaust nozzles and air intake ramps were variable.[37] Initially, it had been expected that a Mach 1.2 performance could be achieved at low altitude, which required that titanium be used in critical areas in the fuselage and wing structure. The low altitude performance requirement was later lowered to Mach 0.85, reducing the amount of titanium and therefore cost.[33] A pair of small vanes mounted near the nose are part of an active vibration damping system that smooths out the otherwise bumpy low-altitude ride.[38] The first three B-1As featured an escape capsule that ejected the cockpit with all four crew members inside. The fourth B-1A was equipped with a conventional ejection seat for each crew member.[39]

The B-1A mockup review occurred in late October 1971.[40] The first B-1A prototype (Air Force serial no. 74-0158) flew on 23 December 1974. Three more B-1A prototypes followed.[41] As the program continued the per-unit cost continued to rise in part because of high inflation during that period. In 1970, the estimated unit cost was $40 million, and by 1975, this figure had climbed to $70 million.[42]

New problems and cancellation

In 1976, Soviet pilot Viktor Belenko defected to Japan with his MiG-25 "Foxbat".[43] During debriefing he described a new "super-Foxbat" (almost certainly referring to the MiG-31) that had look-down/shoot-down radar in order to attack cruise missiles. This would also make any low-level penetration aircraft "visible" and easy to attack.[44] Given that the B-1's armament suite was similar to the B-52, and it now appeared no more likely to survive Soviet airspace than the B-52, the program was increasingly questioned.[45] In particular, Senator William Proxmire continually derided it in public, arguing it was an outlandishly expensive dinosaur. During the 1976 federal election campaign, Jimmy Carter made it one of the Democratic Party's platforms, saying "The B-1 bomber is an example of a proposed system which should not be funded and would be wasteful of taxpayers' dollars."[46]

When Carter took office in 1977 he ordered a review of the entire program. By this point the projected cost of the program had risen to over $100 million per aircraft, although this was lifetime cost over 20 years. He was informed of the relatively new work on stealth aircraft that had started in 1975, and he decided that this was a better avenue of approach than the B-1. Pentagon officials also stated that the AGM-86 Air Launched Cruise Missile (ALCM) launched from the existing B-52 fleet would give the USAF equal capability of penetrating Soviet airspace. With a range of 1,500 miles (2,400 km), the ALCM could be launched well outside the range of any Soviet defenses and penetrate at low altitude just like a bomber (and much lower radar cross-section due to size), but in much greater numbers at a lower cost.[47] A small number of B-52s could launch hundreds of ALCMs, saturating the defense. A program to improve the B-52 and develop and deploy the ALCM would cost perhaps 20% of the price to deploy the planned 244 B-1As.[46]

On 30 June 1977, Carter announced that the B-1A would be canceled in favor of ICBMs, SLBMs, and a fleet of modernized B-52s armed with ALCMs.[35] Carter called it "one of the most difficult decisions that I've made since I've been in office." No mention of the stealth work was made public with the program being top secret, but today it is known that in early 1978 he authorized the Advanced Technology Bomber (ATB) project, which eventually led to the B-2 Spirit.[48]

Domestically, the reaction to the cancellation was split along partisan lines. The Department of Defense was surprised by the announcement; internal expectations were that the number of B-1s ordered would be reduced to around 150.[49] Congressman Robert Dornan (R-CA) claimed, "They're breaking out the vodka and caviar in Moscow."[50] In contrast, it appears the Soviets were more concerned by large numbers of ALCMs representing a much greater threat than a smaller number of B-1s. Soviet news agency TASS commented that "the implementation of these militaristic plans has seriously complicated efforts for the limitation of the strategic arms race."[46] Western military leaders were generally happy with the decision. NATO commander Alexander Haig described the ALCM as an "attractive alternative" to the B-1. French General Georges Buis stated "The B-1 is a formidable weapon, but not terribly useful. For the price of one bomber, you can have 200 cruise missiles."[46]

Flight tests of the four B-1A prototypes for the B-1A program continued through April 1981. The program included 70 flights totaling 378 hours. A top speed of Mach 2.22 was reached by the second B-1A. Engine testing also continued during this time with the YF101 engines totaling almost 7,600 hours.[51]

Shifting priorities

 A right side view of a B-1A on the ground in 1984
A Rockwell B-1A in 1984

It was during this period that the Soviets started to assert themselves in several new theaters of action, in particular through Cuba during the Angolan Civil War starting in 1975 and the Soviet invasion of Afghanistan in 1979. U.S. strategy to this point had been focused on containing Communism and preparation for war in Europe. The new Soviet actions revealed that the military lacked capability outside these narrow confines.[52]

The U.S. Army responded by accelerating its Rapid Deployment Forces concept but suffered from major problems with airlift and sealift capability.[53] In order to slow an enemy invasion of other countries, air power was critical; however the key Iran-Afghanistan border was outside the range of the U.S. Navy's carrier-based attack aircraft, leaving this role to the U.S. Air Force. Although the B-52 had the range to support on-demand global missions, its long runway requirements limited the forward basing possibilities.[54]

During the 1980 presidential campaign, Ronald Reagan campaigned heavily on the platform that Carter was weak on defense, citing the cancellation of the B-1 program as an example, a theme he continued using into the 1980s.[55] During this time Carter's defense secretary, Harold Brown, announced the stealth bomber project, apparently implying that this was the reason for the B-1 cancellation.[56]

B-1B program

On taking office, Reagan was faced with the same decision as Carter before: whether to continue with the B-1 for the short term, or to wait for the development of the ATB, a much more advanced aircraft. Studies suggested that the existing B-52 fleet with ALCM would remain a credible threat until 1985, as it was predicted that 75% of the B-52 force would survive to attack its targets.[57] After this, the introduction of the SA-10 missile, the MiG-31 interceptor and the first Soviet Airborne Early Warning and Control (AWACS) systems would make the B-52 increasingly vulnerable.[58] During 1981, funds were allocated to a new study for a bomber for the 1990s time-frame. This led to the Long-Range Combat Aircraft (LRCA) project. The LRCA evaluated the B-1, F-111 and ATB as possible solutions; an emphasis was placed on multi-role capabilities, as opposed to purely strategic operations.[57]

 The first B-1B at its roll-out ceremony outside a hangar in Palmdale, California in 1984
First B-1B debuted outside a hangar in Palmdale, California, 1984

In 1981, it was believed the B-1 could be in operation before the ATB, covering the transitionary period between the B-52's increasing vulnerability and the ATB's introduction. Reagan decided the best solution was to procure both the B-1 and ATB, and on 2 October 1981 Reagan announced that 100 B-1s were to be ordered to fill the LRCA role.[36][59]

In January 1982 the U.S. Air Force awarded two contracts to Rockwell worth a combined $2.2 billion for the development and production of 100 new B-1 bombers.[60] Numerous changes were made to the design to make it better suited to the now expected missions, resulting in the new B-1B.[47] These changes included a reduction in maximum speed,[56] which allowed the variable-aspect intake ramps to be replaced by simpler fixed geometry intake ramps in the newer design. This reduced the B version's radar signature; the reduction in radar cross-section was seen as a good trade off for the speed decrease.[36] High subsonic speeds at low altitude became a focus area for the revised design,[56] and low-level speeds were increased from about Mach 0.85 to 0.92. The B-1B has a maximum speed of Mach 1.25 at higher altitudes.[36][61]

The B-1B's maximum takeoff weight was increased to 477,000 pounds (216,000 kg) from the B-1A's 395,000 pounds (179,000 kg).[36][62] The weight increase was to allow for takeoff with a full internal fuel load and for external weapons to be carried. Rockwell engineers were able to reinforce critical areas and lighten non-critical areas of the airframe, so the increase in empty weight was minimal.[62] In order to deal with the introduction of the MiG-31 (Zaslon) and other aircraft with look-down capability (which reduced the B-1s low-flying advantage), the B-1B's electronic warfare suite was significantly upgraded.[36]

File:B-1b fly-by 2004.jpg
B-1B banking during a demonstration in 2004

Opposition to the plan was widespread within Congress. Critics pointed out that many of the original problems remained in both areas of performance and expense.[63] In particular it seemed the B-52 fitted with electronics similar to the B-1B would be equally able to avoid interception, as the speed advantage of the B-1 was now minimal. It also appeared that the "interim" time frame served by the B-1B would be less than a decade, being rendered obsolete shortly after the introduction of a much more capable ATB design.[64] The primary argument in favor of the B-1 was its large conventional weapon payload, and that its takeoff performance allowed it to operate with a credible bombload from a much wider variety of airfields. The USAF spread production subcontracts across many congressional districts, making the aircraft more popular on Capitol Hill.[57]

B-1A #1 was disassembled and used for radar testing at the Rome Air Development Center at the former Griffiss Air Force Base, New York.[65] B-1As #2 and #4 were modified to include B-1B systems. The first B-1B was completed and began flight testing in March 1983. The first production B-1B was rolled out on 4 September 1984 and first flew on 18 October 1984.[66] The 100th and final B-1B was delivered on 2 May 1988;[41] before the last B-1B was delivered, the USAF had determined that the aircraft was vulnerable to Soviet air defenses.[67]

Design

Overview

The B-1 has a blended wing body configuration, with variable-sweep wing, four turbofan engines, triangular fin control surfaces and cruciform tail. The wings can sweep from 15 degrees to 67.5 degrees (full forward to full sweep). Forward-swept wing settings are used for takeoff, landings and high-altitude maximum cruise. Aft-swept wing settings are used in high subsonic and supersonic flight.[68] The B-1's variable-sweep wings and thrust-to-weight ratio provide it with better takeoff performance, allowing it to use more runways than previous bombers.[69] The length of the aircraft presented a flexing problem due to air turbulence at low altitude. To alleviate this, Rockwell included small triangular fin control surfaces or vanes near the nose on the B-1. The B-1's Structural Mode Control System rotates the vanes automatically to counteract turbulence and smooth out the ride.[70]

 A rear view of a B-1B at Royal International Air Tattoo air show in 2004
Rear view of B-1B in flight, 2004

Unlike the B-1A, the B-1B cannot reach Mach 2+ speeds; its maximum speed is Mach 1.25 (about 950 mph or 1,530 km/h at altitude),[71] but its low-level speed increased to Mach 0.92 (700 mph, 1,130 km/h).[61] The speed of the current version of the aircraft is limited by the need to avoid damage to its structure and air intakes. To help lower its radar cross section (RCS), the B-1B uses serpentine air intake ducts (see S-duct) and fixed intake ramps, which limit its speed compared to the B-1A. Vanes in the intake ducts serve to deflect and shield radar emissions from the highly reflective engine compressor blades.[72]

The B-1A's engine was modified slightly to produce the GE F101-102 for the B-1B, with an emphasis on durability, and increased efficiency.[73] The core of this engine has since been re-used in several other engine designs, including the GE F110 which has seen use in the F-14 Tomcat, F-15K/SG variants and most recent versions of the General Dynamics F-16 Fighting Falcon.[74] It is also the basis for the non-afterburning GE F118 used in the B-2 Spirit and the U-2S.[74] The F101 engine was the basis for the core of the extremely popular CFM56 civil engine, which can be found on some versions of practically every small-to-medium-sized airliner.[75] The nose gear cover door has controls for the auxiliary power units (APUs), which allow for quick starts of the APUs upon order to scramble.[76][77]

Avionics

The interior of a B-1B cockpit at night
B-1B cockpit at night

The B-1's main computer is the IBM AP-101, which is also used on the Space Shuttle orbiter and the B-52 bomber.[78] The computer is programmed with the JOVIAL programming language.[79] The Lancer's offensive avionics include the Westinghouse (now Northrop Grumman) AN/APQ-164 forward-looking offensive passive electronically scanned array radar set with electronic beam steering (and a fixed antenna pointed downward for reduced radar observability), synthetic aperture radar, ground moving target indication (GMTI), and terrain-following radar modes, Doppler navigation , radar altimeter, and an inertial navigation suite.[80] The B-1B Block D upgrade added a Global Positioning System (GPS) receiver beginning in 1995.[81]

The B-1's defensive electronics include the Eaton AN/ALQ-161A radar warning and defensive jamming equipment,[82] which has three sets of antennas; one at the front base of each wing and the third rear-facing in the tail radome.[83][84] Also in the tail radome is the AN/ALQ-153 Missile Approach Warning (Pulse-Doppler radar).[85] The ALQ-161 is linked to a total of eight AN/ALE-49 flare dispensers located on top behind the canopy, which are handled by the AN/ASQ-184 avionics management system.[86] Each AN/ALE-49 dispenser has a capacity of 12 MJU-23A/B flares. The MJU-23A/B flare is one of the world's largest infrared countermeasure flares at a weight of over 3.3 pounds (1.5 kg).[87] The B-1 has also been equipped to carry the ALE-50 Towed Decoy System.[88]

Also aiding the B-1's survivability is its relatively low radar cross-section (RCS). Although not technically a stealth aircraft in a comprehensive sense, thanks to the aircraft's structure, serpentine intake paths and use of radar-absorbent material its RCS is about 1/50th of the similar sized B-52's RCS; this is about 26 ft² or 2.4 m², roughly equivalent to the RCS of a small fighter aircraft.[86][89][90]

Upgrades

Sideview of a B-1B's nose section, which features a Sniper XR pod mounted on its chin
Nose of B-1 with the Sniper XR pod hanging below

The B-1 has been upgraded since production, beginning with the "Conventional Mission Upgrade Program" (CMUP), which added a new MIL-STD-1760 smart-weapons interface to enable the use of precision-guided conventional weapons. CMUP began with Block A, which was the standard B-1B with the capability to deliver non-precision gravity bombs. Block B brought an improved Synthetic Aperture Radar, and upgrades to the Defensive Countermeasures System and was fielded in 1995. Block C provided an "enhanced capability" for delivery of up to 30 cluster bomb units (CBUs) per sortie with modifications made to 50 bomb racks.[91]

Block D added a "Near Precision Capability" via improved weapons and targeting systems, and added advanced secure communications capabilities.[91] The first part of the electronic countermeasures upgrade added Joint Direct Attack Munition (JDAM), ALE-50 Towed Decoy System, and anti-jam radios.[82][92][93] Block E upgraded the avionics computers and incorporated the Wind Corrected Munitions Dispenser (WCMD), the AGM-154 Joint Standoff Weapon (JSOW) and the AGM-158 JASSM (Joint Air to Surface Standoff Munition), substantially improving the bomber's capability. Upgrades were completed in September 2006.[94] Block F was the Defensive Systems Upgrade Program (DSUP) to improve the aircraft's electronic countermeasures and jamming capabilities, but it was canceled in December 2002 due to cost overruns and schedule slips.[95]

In 2005, a program began to upgrade crew stations and integrate data linking.[96] A B-1 equipped with the Fully Integrated Data Link (FIDL) first flew on 29 July 2009; the FIDL enables electronic data sharing, eliminating the need to enter information between systems by hand.[97] In January 2013, Boeing delivered the first Integrated Battle Station (IBS) equipped B-1. This replaced several displays with new multi-function color display units, an upgraded Central Integrated Test System, and a newer Aircraft Performance Monitoring Computer.[98][99][100] In June 2012, the B-1Bs are receiving Sustainment-Block 16 upgrades to add Link 16 networking and digital flight instrumentation.[101]

In 2007 the Sniper XR targeting pod was integrated on the B-1 fleet. The pod is mounted on an external hardpoint at the aircraft's chin near the forward bomb bay.[102] Following accelerated testing, the Sniper pod was fielded in summer 2008.[103][104] Future precision munitions include the Small Diameter Bomb.[105] In 2011, the Air Force was considering upgrading the B-1s with multiple ejector racks so that they can carry three times as many smaller JDAMs than they currently can.[106]

In February 2014, work began on a multi-year upgrade of 62 B-1Bs, scheduled to be completed by 2019. The vertical situation display upgrade (VDSU) shall replace existing flight instruments with multifunction color displays, a second display shall aid threat evasion and targeting, and act as a back-up display. Additional memory capacity is to be installed for the diagnostics database. Procurement and installation of the IBS upgrades is expected to cost $918 million, research and engineering costs are estimated at $391 million. Other additions are to replace the two spinning mass gyroscopic inertial navigation system with ring laser gyroscopic systems and a GPS antenna, replacement of the APQ-164 radar with the Scalable Agile Beam Radar - Global Strike (SABR-GS) active electronically scanned array,[107] and a new attitude indicator.[108]

Operational history

Strategic Air Command

The second B-1B, "The Star of Abilene", was the first B-1B delivered to the USAF Strategic Air Command (SAC) in June 1985. Initial operational capability was reached on 1 October 1986 and the B-1B was placed on nuclear alert status.[109][110] The B-1 received the official name "Lancer" on 15 March 1990. However, the bomber has been commonly called the "Bone"; a nickname that appears to stem from an early newspaper article on the aircraft wherein its name was phonetically spelled out as "B-ONE" with the hyphen inadvertently omitted.[111]

A dismantled decommissioned B-1 being transported by flatbed truck

In late 1990 engine fires in two Lancers caused the grounding of the fleet. The cause was traced back to problems in the first-stage fan, the aircraft were placed on "limited alert"; in other words, they were grounded unless a nuclear war broke out. Following inspections and repairs they were returned to duty beginning on 6 February 1991.[112][113] Due to the engine problems, the B-1B was effectively sidelined in the Gulf War.[67]

Originally designed strictly for nuclear war, the B-1's development as an effective conventional bomber was delayed until the 1990s. The collapse of the Soviet Union had brought the B-1's nuclear role into question, leading to President George H. W. Bush ordering a $3 billion conventional refit.[114] By 1991, the B-1 had a fledgling conventional capability, forty of them able to drop the 500 pounds (230 kg) Mk-82 General Purpose (GP) bomb, although mostly from low altitude. Despite being cleared for this role, the problems with the engines precluded their use in Operation Desert Storm.[115] B-1s were primarily reserved for strategic nuclear strike missions at this time, providing the role of airborne nuclear deterrent against the Soviet Union.[115] The B-52 was more suited to the role of conventional warfare and it was used by coalition forces instead.[115]

After the inactivation of Strategic Air Command (SAC) and the establishment of the Air Combat Command (ACC) in 1992, the B-1 developed a greater conventional weapons capability. Part of this development was the start-up of the U.S. Air Force Weapons School B-1 Division.[116] In 1994, two additional B-1 bomb wings were also created in the Air National Guard, with former fighter wings in the Kansas Air National Guard and the Georgia Air National Guard converting to the aircraft.[117] By the mid-1990s, the B-1 could employ GP weapons as well as various CBUs. By the end of the 1990s, with the advent of the "Block D" upgrade, the B-1 boasted a full array of guided and unguided munitions. The B-1B no longer carries nuclear weapons;[36] its nuclear capability was disabled by 1995 with the removal of nuclear arming and fuzing hardware.[118]

Conventional role

Top forward view of gray aircraft with wings swept forward banking right. Underneath are strips of white clouds and uninhabited terrain.
A B-1B Lancer with wings swept full forward

The B-1 was first used in combat in support of operations against Iraq, during Operation Desert Fox in December 1998, employing unguided GP weapons. B-1s have been subsequently used in Operation Allied Force (Kosovo) and, most notably, in Operation Enduring Freedom in Afghanistan and the 2003 invasion of Iraq.[36] The B-1's role in Operation Allied Force has been criticized as the aircraft was not used until after enemy defenses had been suppressed by aircraft like the older B-52 it was intended to replace.[67] The B-1 has deployed an array of conventional weapons in war zones, most notably the GBU-31, 2,000 pounds (910 kg) Joint Direct Attack Munition (JDAM).[36] In the first six months of Operation Enduring Freedom, eight B-1s dropped almost 40 percent of aerial ordnance, including some 3,900 JDAMs.[108] JDAM munitions were heavily used by the B-1 over Iraq, notably on 7 April 2003 in an unsuccessful attempt to kill Saddam Hussein and his two sons.[119] At the height of the Iraq War, a B-1 was permanently airborne to provide rapid precision bombardment upon important targets as intelligence identified them.[120] During Operation Enduring Freedom, the B-1 was able to raise its mission capable rate to 79%.[88]

The B-1 has higher survivability and speed when compared to the older B-52, which it was intended to replace. It also holds 61 FAI world records for speed, payload, distance, and time-to-climb in different aircraft weight classes.[121][122] In November 1983, three B-1Bs set a long distance record for the aircraft, which demonstrated its ability to conduct extended mission lengths to strike anywhere in the world and return to base without any stops.[123] The National Aeronautic Association recognized the B-1B for completing one of the 10 most memorable record flights for 1994.[88]

Of the 100 B-1Bs built, 93 remained in 2000 after losses in accidents. In June 2001, the Pentagon sought to place one-third of its then fleet into storage; this proposal resulted in several U.S. Air National Guard officers and members of Congress lobbying against the proposal, including the drafting of an amendment to prevent such cuts.[67] The 2001 proposal was intended to allow money to be diverted to further upgrades to the remaining B-1Bs, such as computer modernization.[67] In 2003, accompanied by the removal of B-1Bs from the two bomb wings in the Air National Guard, the USAF decided to retire 33 aircraft to concentrate its budget on maintaining availability of remaining B-1Bs.[124] In 2004, a new appropriation bill called for some of the retired aircraft to return to service,[125] and the USAF returned seven mothballed bombers to service to increase the fleet to 67 aircraft.[126]

Ammunition and yellow bombs lay as two crew member, using lift truck, transfer them to a gray B-1 parked nearby in the background
Crew members transferring a GBU-31 Joint Direct Attack Munition (JDAM) to a lift truck for loading onto a B-1B on 29 March 2007, in Southwest Asia

On 14 July 2007, the Associated Press reported on the growing USAF presence in Iraq, including reintroduction of B-1Bs as a close-at-hand platform to support Coalition ground forces.[127] Since 2008, B-1s have been used in Iraq and Afghanistan in an "armed overwatch" role, loitering for surveillance purposes while ready to deliver guided bombs in support of ground troops if contacted.[128][129]

The B-1B underwent a series of flight tests using a 50/50 mix of synthetic and petroleum fuel; on 19 March 2008, a B-1B from Dyess Air Force Base, Texas, became the first USAF aircraft to fly at supersonic speed using a synthetic fuel during a flight over Texas and New Mexico. This was conducted as part of an ongoing Air Force testing and certification program to reduce reliance on traditional oil sources.[130] On 4 August 2008, a B-1B flew the first Sniper Advanced Targeting Pod equipped combat sortie where the crew successfully targeted enemy ground forces and dropped a GBU-38 guided bomb in Afghanistan.[103]

In March 2011, B-1Bs from Ellsworth Air Force Base attacked undisclosed targets in Libya as part of Operation Odyssey Dawn.[131] The USAF had 66 B-1Bs in service in September 2012, split between four squadrons organized into two Bomb Wings: the 7th Bomb Wing at Dyess AFB, Texas, and the 28th Bomb Wing at Ellsworth AFB, South Dakota.[99][132]

With upgrades to keep the B-1 viable, the air force may keep it in service until approximately 2038.[133] Despite upgrades, the B-1 has repair and cost issues; every flight hour needs 48.4 hours of repair. The fuel, repairs and other needs for a 12-hour mission costs $720,000 as of 2010.[134] The $63,000 cost per flight hour is, however, less than the $72,000 for the B-52 and the $135,000 of the B-2.[135] In June 2010, senior USAF officials met to consider retiring the entire fleet to meet budget cuts.[136] The Pentagon plans to supplement the aircraft with the Long Range Strike Bomber beginning in 2030.[137][138] In the meantime, its "capabilities are particularly well-suited to the vast distances and unique challenges of the Pacific region, and we'll continue to invest in, and rely on, the B-1 in support of the focus on the Pacific" as part of President Obama's "Pivot to East Asia".[139]

In August 2012, the 9th Expeditionary Bomb Squadron returned from a six-month tour in Afghanistan. Their nine B-1Bs flew 770 sorties, the most of any B-1B squadron on a single deployment. The squadron spent 9,500 hours airborne, having one of its bombers in the air at all times. They accounted for a quarter of all combat aircraft sorties over the country while there and averaged 2–3 requests for air support per day.[140] On 4 September 2013, a B-1B participated in a maritime evaluation exercise, deploying munitions such as laser-guided 500 lb GBU-54 bombs, 500 lb and 2,000 lb Joint Direct Attack Munitions (JDAM), and Long Range Anti-Ship Missiles (LRASM). The aim was to detect and engage several small craft using existing weapons and tactics developed from conventional warfare against ground targets; the B-1 is seen as a useful asset for maritime duties such as patrolling shipping lanes.[141]

Beginning in 2014, the B-1 was used by the U.S. against ISIL in the Syrian Civil War.[142] From August 2014 to January 2015, the B-1 accounted for eight percent of USAF sorties during Operation Inherent Resolve.[143] The 9th Bomb Squadron was deployed to Qatar in July 2014 for support of missions for Afghanistan, but when the air campaign against ISIL began on 8 August the unit's B-1's were redirected to Iraq. During the Battle of Kobane in Syria, the squadron's B-1s dropped 660 bombs over five months in support of Kurdish forces defending the city, one-third of all bombs used during OIR during the period, killing some 1,000 ISIL fighters. The 9th Bomb Squadron’s B-1s went "Winchester," dropping all weapons on board, 31 times during its deployment. Over 2,000 JDAMs were dropped in its sixth-month rotation.[144]

As part of a USAF organizational realignment announced in April 2015, all B-1B aircraft are to be reassigned from Air Combat Command to Global Strike Command (GSC) effective 1 October 2015.[145]

Variants

The rear section showing the B-1A's pointed radome
B-1A

The B-1A was the original B-1 design with variable engine intakes and Mach 2.2 top speed. Four prototypes were built; no production units were manufactured.[126][146]

B-1B

The B-1B is a revised B-1 design with reduced radar signature and a top speed of Mach 1.25. It was otherwise optimized for low-level penetration. A total of 100 B-1Bs were produced.[146]

B-1R

The B-1R is a proposed upgrade of existing B-1B aircraft.[147] The B-1R (R for "regional") would be fitted with advanced radars, air-to-air missiles, and new Pratt & Whitney F119 engines. This variant would have a top speed of Mach 2.2, but with 20% shorter range.[148]

Existing external hardpoints would be modified to allow multiple conventional weapons to be carried, increasing overall loadout. For air-to-air defense, an Active electronically scanned array (AESA) radar would be added and some existing hardpoints modified to carry air-to-air missiles. If needed the B-1R could escape from unfavorable air-to-air encounters with its Mach 2+ speed. Few aircraft are currently capable of sustained speeds over Mach 2.[147]

Operators

Front view of B-1 parked on ramp at night. Nearby yellow flood lights illuminate the area. In the background are buildings
A 28th Bomb Wing B-1B on the ramp in the early morning at Ellsworth Air Force Base, South Dakota
A B-1B on public display at Ellsworth AFB, 2003
Gray aircraft before landing, flying left, with gears extended. Green grass make up the foreground. Buildings and communication towers are in the background
USAF B-1B arrives at Royal International Air Tattoo 2008
 United States

United States Air Force

Strategic Air Command 1985–92
Air Combat Command 1992–2015
Air Force Global Strike Command 2015–present
9th Bomb Squadron 1993–present
13th Bomb Squadron 2000–05
28th Bomb Squadron 1994–present
337th Bomb Squadron 1993–94
34th Bomb Squadron 1994–97, 2002–present
37th Bomb Squadron 1986–present
77th Bomb Squadron 1985–95, 1997–2002
337th Test and Evaluation Squadron (Dyess AFB, Texas) 2004–present
77th Weapons Squadron (Dyess) 2003–present
337th Bomb Squadron 1985–93
338th Combat Crew Training Squadron 1986–93
4018th Combat Crew Training Squadron 1985–86
46th Bomb Squadron
34th Bomb Squadron
28th Bomb Squadron
Air National Guard
128th Bomb Squadron
  • 184th Bomb Wing – McConnell AFB, Kansas 1994–2002
127th Bomb Squadron
Air Force Flight Test CenterEdwards AFB, California
410th Flight Test Squadron
419th Flight Test Squadron
  • 6510th Test Wing 1974–89
6519th Flight Test Squadron

Aircraft on display

B-1A
B-1B

Accidents and incidents

Ten B-1s have been lost due to accidents. Between 1984 and 2001, 17 crew members and people on board have been killed in B-1 accidents.[159]

Crashes

  • On 29 August 1984, B-1A (AF Ser. No. 74-0159) stalled and crashed while performing minimum control speed tests at low altitude. The crew used the escape capsule to leave the bomber, but the parachutes deployed improperly, causing the capsule to hit nose down. The impact killed the B-1's pilot, Rockwell test pilot Doug Benefield, and seriously injured two other crew members.[160][161]
  • In September 1987, B-1B (s/n 84-0052) from the 96th Bomb Wing, 338th Combat Crew Training Squadron, Dyess AFB crashed near La Junta, Colorado while flying on a low-level training route. This was the only B-1B crash to occur with six crew members aboard. The two crew members in jump seats, and one of the four crew members in ejection seats perished. The root cause of the accident was thought to be a bird strike on a wing's leading edge during the low-level flight. The impact was severe enough to sever fuel and hydraulic lines on one side of the aircraft, the other side's engines functioned long enough to allow for ejection. The B-1B fleet was later modified to protect these supply lines.[162]
  • In November 1988, B-1B (s/n 85-0063) from the 96th Bomb Wing, 337th Bomb Squadron, Dyess AFB crashed near Tye, Texas after a fire broke out above the left engines. All four crew members successfully ejected from the aircraft.[162]
  • In November 1988, B-1B (s/n 85-0076) from the 28th Bomb Wing, 37th Bomb Squadron, Ellsworth AFB crashed short of the runway at Ellsworth AFB during adverse weather. All four crew members ejected successfully.[162]
  • In November 1992, B-1B (s/n 86-0106) from the 7th Bomb Wing, 337th Bomb Squadron, Dyess AFB, Texas, flying on a low-level training flight crashed into a mountain near Van Horn, Texas. All four members of the crew were killed, and the cause was attributed to pilot error.[162]
  • In September 1997, B-1B (s/n 85-0078) from the 28th Bomb Wing, 37th Bomb Squadron, Ellsworth AFB, South Dakota, flying in the Powder River Military Operating Area crashed Lua error in Module:Convert at line 272: attempt to index local 'cat' (a nil value). north of Alzada, Montana. All four members of the crew were killed.[162][163] The review board found that the bomber struck the ground due to pilot error, while performing a defensive maneuver during training.[164]
  • On 18 February 1998, B-1B (s/n 84-0057) from the 7th Bomb Wing, Dyess AFB, Texas crashed near Marion, Kentucky when a fire detected by a cockpit instrument panel shut down the aircraft's power.[165] All four crew members were able to eject and were rescued safely.[166]
  • In December 2001, B-1B (s/n 86-0114) from the 28th Bomb Wing, 37th Bomb Squadron, Ellsworth AFB, South Dakota, was lost over the Indian Ocean. All four crew members successfully ejected and were rescued.[167] The bomber was flying en route to a long-range combat mission over Afghanistan when the crew declared an in-flight emergency. The pilot, Captain William Steele, attributed the crash to "multiple malfunctions" causing the bomber to go "out of control".[159] Because of the water's depth, the structural data collector (SDC) or "Black Box" was not recovered and the cause was not positively determined. The aircraft had recently returned from a routine Phase Inspection, and was on its first combat mission after returning to the island of Diego Garcia in the British Indian Ocean Territory. This was the first B-1B to be lost during combat operations.[159][168]
  • On 4 April 2008, B-1B (s/n 86-0116) lost hydraulic power while taxiing, then crashed into a concrete barrier and caught fire at Al Udeid AB, Qatar. The crew safely evacuated the aircraft. The B-1B was carrying two 2,000 lb bombs at the time, which did not detonate. The aircraft was destroyed.[169]
  • On 19 August 2013, B-1B (AF Ser. No. 85-0091) out of Ellsworth AFB, South Dakota crashed in a remote area near Broadus, Montana. All four crew members survived by ejecting before the aircraft crashed.[170] A report found that the crash was due to a mechanical failure leading to a fuel leak and explosions.[171][172]

Other accidents and notable incidents

Black aircraft trailed by column of black smoke and fire on runway as fire trucks close in on the flame from behind
A B-1B with a brake fire after a hard landing at Rhein-Main AB, Germany, June 1994.
  • On 4 October 1989, B-1B (s/n 85-0070) from the 96th Bomb Wing, 337th Bomb Squadron, Dyess AFB, Texas, was forced to make an emergency landing at Edwards Air Force Base after suffering an in-flight failure of the No. 2 hydraulic system, which required use of the No 3 system to deploy the landing gear. After the nose gear failed to deploy, the crew attempted to lower the nose gear via the alternate emergency gear-extension method. After several hours of attempting different means to lower the nose gear, the decision was made to perform a nose-gear-up landing on Rogers Dry Lake at Edwards. The lower portion of the forward bulkhead used to mount the radar antenna was the only part of the aircraft to suffer damage, and after repairs, the jet was returned to Dyess in January 1990 by the same crew which performed the emergency landing.[173]
  • In October 1990, while flying a training route in eastern Colorado, B-1B (s/n 86-0128) from the 384th Bomb Wing, 28th Bomb Squadron, McConnell AFB, experienced an explosion as the engines reached full power without afterburners. Fire on the aircraft's left was spotted. The #1 engine was shut down and its fire extinguisher was activated. The accident investigation determined that the engine had suffered catastrophic failure, engine blades had cut through the engine mounts and the engine became detached from the aircraft.[162]
  • In December 1990, B-1B (s/n 83-0071) from the 96th Bomb Wing, 337th Bomb Squadron, Dyess AFB, Texas, experienced a jolt that caused the #3 engine to shut down with its fire extinguisher activating. This event, coupled with the October 1990 engine incident, led to a 50+ day grounding of the B-1Bs not on nuclear alert status. The problem was eventually traced back to problems in the first-stage fan, and all B-1Bs were equipped with modified engines.[162]
  • In June 1994, B-1B (s/n 84-0057) from the 7th Bomb Wing, 9th Bomb Squadron, made an emergency divert to Rhein-Main Air Base, Germany due to a wing sweep malfunction. The crew made a high speed landing at Rhein-Main and stopped 100 feet short of the end of the runway. Afterward the overheated brakes led to a fire in the right main landing gear, but it was quickly extinguished.[174]
  • On 15 September 2005, B-1B (s/n 85-0066) was extensively damaged by fire while landing at Andersen Air Force Base, Guam. The investigation into the incident concluded that leaking hydraulic fluid and sparks from a wheel being gouged caused a fire to start in the aircraft's right main landing gear as it touched down. The resulting fire damaged the B-1's right wing, engine nacelle, airframe and landing gear, leading to an estimated repair cost of more than $32 million.[175]
  • On 8 May 2006, B-1B (s/n 86-0132) from the 7th Bomb Wing, 9th Bomb Squadron, Dyess AFB, Texas, landed "gear-up" during recovery from an 11-hour ferry flight to the island of Diego Garcia. A resulting fire was quickly extinguished and the crew escaped through the top hatch with only a minor back injury to the co-pilot. The air force investigation concluded that the crew "forgot to lower the landing gear" based on the following reasons: 1) co-pilot task oversaturation, 2) co-pilot's wanting to complete a long mission, 3) neither pilot completed the landing checklist, 4) co-pilot's belief that the pilot had lowered the landing gear when he had not, 5) pilot had turned over control to the co-pilot on the final approach and the pilot had reported to base that the landing gear was down when it was not - indicator lights showing the landing gear was still up were working and apparently ignored. As a result, the B-1B impacted and slid on the runway, which caused approximately $8 million of damage to the aircraft and runway.[176]

Specifications (B-1B)

Three sketched diagrams showing the front, top and side views of the B-1. The top view, in particular, shows the maximum sweep angles of the wings
A flightdeck, dominated by a mix of new and analogue instruments. On both sides are control yokes. Light enters through the forward windows
B-1B cockpit
B-1B forward bomb bay fitted with a rotary launcher
External image
Rockwell B-1A Cutaway
image icon Rockwell B-1A Cutaway from Flightglobal.com

Data from USAF Fact Sheet,[88] Jenkins,[177] Pace,[61] Lee[82] except where noted

General characteristics

  • Crew: four (aircraft commander, copilot, offensive systems officer and defensive systems officer)
  • Payload: 125,000 lb (56,700 kg) ; internal and external ordnance combined
  • Length: 146 ft (44.5 m)
  • Wingspan:
    • Extended: 137 ft (42 m)
    • Swept: 79 ft (24 m)
  • Height: 34 ft (10.4 m)
  • Wing area: 1,950 ft² (181.2 m²)
  • Airfoil: NACA69-190-2
  • Empty weight: 192,000 lb (87,100 kg)
  • Loaded weight: 326,000 lb (148,000 kg)
  • Max. takeoff weight: 477,000 lb (216,400 kg)
  • Powerplant: 4 × General Electric F101-GE-102 augmented turbofans
    • Dry thrust: 14,600 lbf (64.9 kN) each
    • Thrust with afterburner: 30,780 lbf (136.92 kN) each
  • Fuel capacity, optional: 10,000 U.S. gal (37,900 L) fuel tank each in 1–3 internal weapons bays

Performance

  • Maximum speed:
    • At altitude: Mach 1.25 (721 kn or 830 mph or 1,335 km/h) at 50,000 ft or 15,000 m altitude
    • At low level: Mach 0.92 (700 mph or 1,100 km/h) at 200–500 ft or 61–152 m altitude
  • Range: 6,478 nmi (7,455 mi; 11,997 km)
  • Combat radius: 2,993 nmi (3,444 mi; 5,543 km)
  • Service ceiling: 60,000 ft (18,000 m)
  • Wing loading: 167 lb/ft² (816 kg/m²)
  • Thrust/weight: 0.38

Armament

Avionics

B-1B Lancer internal weapons load options
Bomb rack & Stores[185] Bay 1 Bay 2 Bay 3 Total
conventional
CBM
2816 to 3513 lb
1 1 1
28 28 28 84
conventional
SECBM
(CBM w/ TMD upgrade)
2816 lb empty
1 1 1
10 10 10 30
GBU-38 6 6 3 15
multi-purpose
MPRL
1300 to 2055 lb
1 1 1
8 8 8 24
Mk-65 naval mines 4 4 4 12
8 8 8 96 or 144
multi-purpose (mixed)
MPRL
(MER upgrade)[186]
1 1 1
4 4 4 36
GBU-38 16 16 16 48
ferry/range extension
fuel tank
2975 gal[187]
1 1 1 3
9157 gal[188]
nuclear (uniform)(out of use)
1 1 1
B28[189] 4 4 4 12
8 8 8 24
nuclear (mixed)(out of use)[190]
1
AGM-86B small fuel tank
8
8
external weapons load options
(mostly not in use due to RCS concerns)
Bomb rack & Stores[185] FWD Stations 1 & 2 INT Stations 3-6 AFT Stations 7 & 8 Total
nuclear (out of use)
dual-pylon 2 2 2
single-pylon 2
2x2 2x2 + 2 2x2 14
(restricted to 12 under SALT II)[190]
conventional (uniform)
Mk-82 2x6 2x6 + 2x6 2x6 44
targeting[191]
Pylon
884 lb
1 (right station)
Sniper XR targeting pod 1 (right station) 1
440 lb
ferry/range extension[188][192]
fuel tank
923 gal
2 2 2 6
5538 gal

Notable appearances in media

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See also

  • ASALM, Advanced Strategic Air-Launched Missile
Aircraft of comparable role, configuration and era
Related lists

References

Notes

  1. The name "Lancer" is only applied to the B-1B version, after the program was revived.
  2. As per B-1B Weapons Loading Checklist T.O. 1B-1B-33-2-1CL-13
  3. both Mk-84 general purpose and BLU-109 penetrating bombs
  4. As per B-1B Weapons Loading Checklist T.O. 1B-1B-33-2-1CL-12 Section 3.4 (Only six each in forward and intermediate bays and three each in the aft bay)
  5. 96 if using four-packs, 144 if using six-packs. This capability has not yet been fielded on the B-1

Citations

  1. Skaarup 2002, p. 17.
  2. Jenkins 1999, p. 10.
  3. Jenkins 1999, pp. 12–13.
  4. Jenkins 1999, pp. 15–17.
  5. 5.0 5.1 5.2 Schwartz 1998, p. 118.
  6. Rich, Ben and Leo Janos. Skunk Works. Boston: Little, Brown & Company, 1994. ISBN 0-316-74300-3.
  7. 7.0 7.1 7.2 Jenkins 1999, p. 21.
  8. "May 1960 – The U-2 Incident. – Soviet and American Statements." Keesing's Record of World Events, Volume 6, 1960.
  9. 9.0 9.1 Spick 1986, pp. 6–8.
  10. 10.0 10.1 10.2 10.3 Schwartz 1998, p. 119.
  11. "NASA-CR-115702, B-70 Aircraft Study Final Report, Vol. I, p. I-38." NASA, 1972.
  12. Jenkins 1999, pp. 14–16.
  13. Knaack 1988, pp. 279–280.
  14. Knaack 1988, p. 256.
  15. Gunston 1978, pp. 12–13.
  16. Gordon Taylor, "Subsonic Low Altitude Bomber", Wright-Patterson Air Force Base ASD-TDR-62-426, June 1962
  17. Pace 1998, pp. 11–14.
  18. Knaack 1988, pp. 575–576.
  19. Casil 2003, p. 8.
  20. Knaack 1988, p. 576.
  21. Knaack 1988, p. 575.
  22. Wykes, J. H. "The Evolution of a Strategic Bomber." AIAA, 12–14 May 1981. Retrieved: 8 October 2009.
  23. Jenkins 1999, p. 23.
  24. Pace 1998, p. 10.
  25. Knaack 1988, pp. 576–577.
  26. "B-1A page." fas.org. Retrieved: 20 March 2008.
  27. 27.0 27.1 27.2 27.3 Knaack 1988, pp. 576–578.
  28. 28.0 28.1 Jenkins 1999, pp. 23–26.
  29. Lua error in package.lua at line 80: module 'strict' not found.
  30. 30.0 30.1 30.2 Knaack 1988, p. 579.
  31. 31.0 31.1 31.2 Pace 1998, pp. 22–23.
  32. Kocivar, Ben. "Our New B-1 Bomber – High, Low, Fast, and Slow." Popular Science, Volume 197, Issue 5, November 1970, p. 86.
  33. 33.0 33.1 Knaack 1988, p. 584.
  34. "Rockwell International history 1970–1986." Boeing. Retrieved: 8 October 2009.
  35. 35.0 35.1 Sorrels 1983, p. 27.
  36. 36.0 36.1 36.2 36.3 36.4 36.5 36.6 36.7 36.8 36.9 Lee 2008, p. 13.
  37. Whitford 1987, p. 136.
  38. Schefter, Jim. "The Other Story About The Controversial B-1." Popular Science, Volume 210. Issue 5, May 1977, p. 112.
  39. Spick 1986, pp. 30–32.
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  41. 41.0 41.1 "B-1B Background Information." Boeing. Retrieved: 8 October 2009.
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  44. Donald 2004, p. 120.
  45. Knaack 1988, p. 590.
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  47. 47.0 47.1 Withington 2006, p. 7.
  48. Pace 1999, pp. 20–27.
  49. Sorrels 1983, p. 23.
  50. Belcher, Jerry. "Dropping B-1 Would Bring World War III, Dornan Says." Los Angeles Times, 11 June 1977.
  51. Jenkins 1999, p. 46.
  52. Liggett, Lieutenant Colonel William R. "Long-Range Combat Aircraft and Rapid Deployment Forces." Maxwell Air Force Base, Air University Review, July–August 1982. Retrieved: 8 October 2009.
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  55. Reagan, President Ronald. "Reagan's Radio Address to the Nation on Foreign Policy." presidentreagan.info. 20 October 1984.
  56. 56.0 56.1 56.2 Schwartz 1998, p. 120.
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  66. Jenkins 1999, pp. 63–64.
  67. 67.0 67.1 67.2 67.3 67.4 Dao 2001, p. 1.
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  69. Knaack 1988, p. 587.
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  73. Spick 1987, p. 498.
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  78. Lua error in package.lua at line 80: module 'strict' not found.
  79. Jovial to smooth U.S. Air Force shift to Ada. (processing language) |HighBeam Business: Arrive Prepared
  80. "AN/APQ-164 B-1B Radar". Northrop Grumman. Retrieved: 25 January 2010.
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  85. Lua error in package.lua at line 80: module 'strict' not found.
  86. 86.0 86.1 Skaarup 2002, p. 18.
  87. Humphries, J. A. and D. E. Miller. "AIAA-1997-2963: B-1B/MJU-23 flare strike test program." American Institute of Aeronautics and Astronautics, AIAA/ASME/SAE/ASEE Joint Propulsion Conference and Exhibit, 33rd, Seattle, Washington, 6–9 July 1997. Retrieved: 8 October 2009.
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  89. Radar Cross Section Measurements (8-12 GHz)
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Bibliography

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External links