Commentary: Laser Communications Will Transform How Government and Industry Use Space

by Dr. Daniel Goure


Space is definitely the high ground when it comes to many military, scientific and economic activities. As the world becomes more information-intensive, the ability to move data rapidly, reliably, and cheaply will be of enormous advantage. Governments, private companies, and scientific organizations are rushing to build large satellite constellations to enhance surveillance of the Earth, explore space, and improve the movement of data. Nations able to deploy robust space-based laser communications systems will reap military, scientific and commercial benefits.

Government and private satellite networks are growing in capability and scale. Currently, there are about 4,500 satellites in orbit, the vast majority in low Earth orbit (LEO). But there are plans to deploy thousands more over the next few decades to surveil both Earth and airspace and enhance reliable global communications.

For instance, the U.S. Space Force is considering deploying two large satellite constellations, one to image the Earth and detect missile launches and a second to facilitate global communications. As for the private sector, SpaceX’s Starlink global information constellation could consist of up to 42,000 satellites. These emerging networks will require faster and dependable ways of moving always-increasing amounts of information around the world.

At present, satellites rely on radio frequency (RF) communications. This means they have limited data transmission rates. Exponential growth in information will cause these transmission networks to slow down. Satellite operators will also need a series of ground stations within line-of-sight of the satellites in order to provide two-way RF communications. As satellites proliferate, their ability to communicate will run up against bandwidth limitations. In addition, as more satellites are deployed, the danger grows that their communications links will interfere with those of other nearby platforms.

Space-based laser communications systems will be key to moving enormous amounts of data and communicating with satellites far out in space. Why use lasers (also referred to as optical technology) for communications? The essential answer is that they provide much higher data transmission rates: 10 to 100 times the rate available from RF communications depending on the type of laser. This not only means a low cost to move information but also much more information moved per second.

Laser communications terminals also require less onboard power than do RF transmitters to send communications over a given distance. This means that space-based laser communications systems will be smaller and lighter than standard RF systems, opening up additional space and weight aboard satellites to deploy other capabilities. Laser crosslinks between satellites also allow for simplified architectures to control constellations with fewer ground stations.

Efforts to interfere with U.S. military satellite communications by jamming RF transmissions are becoming commonplace. Fortunately, because lasers produce extremely narrow beams of energy compared to radiofrequency communications, there is less chance of interference between satellites and a reduced ability for adversaries to intercept a communications link. In addition, by using laser crosslinks, the military can reduce the need to deploy satellite ground stations in locations that could be vulnerable to interference or attack.

The U.S. is investing in a variety of laser communications systems to support scientific, military, and commercial activities. For scientific missions and limited applications on one-of-a-kind military satellites, the government can buy expensive, hand-built optical terminals. The challenge when planning proliferated architecture is building low-cost, low-power, dependable and reconfigurable laser terminals.

NASA is looking to employ laser communications to enhance the flow of information from space-based platforms and improve its ability to control satellites. The agency’s Laser Communications Relay Demonstration (LCRD) seeks to develop laser communications with satellites in various orbits and future manned missions in space and to the Moon. NASA also will deploy its Deep Space Optical Communications payload (DSOC) aboard the Psyche mission, demonstrating the ability of lasers to facilitate very long-range communications.

The U.S. military views space-based laser communications as vital to its ability to operate a distributed, multi-domain force able to share information globally down to the tactical edge in near real-time. The U.S. Space Development Agency (SDA) is looking to build a large communications constellation called the Transport Layer. This constellation could consist of hundreds of satellites, provided that cheap and effective laser terminals are available. DARPA’s Blackjack program is an attempt to address the demand for a low-cost and readily reconfigurable optical communications system that will help various satellite constellations share copious amounts of data quickly and securely.

Private companies are also deploying their own satellite constellations, some intended for Earth observation, others to provide low-cost global communications. For example, SpaceX’s Starlink satellite constellation is intended to provide worldwide access to high-speed Internet. Starlink has begun to deploy purpose-built laser communications terminals on its satellites, starting with those in polar orbit, in order to reduce the requirements for ground stations. Future tranches of Starlink satellites may all have laser crosslinks.

Several U.S. companies are leading the way in the development of laser-based satellite communications systems. General Atomics is working with the SDA on the Laser Interconnect and Networking Communications System (LINCS), which will demonstrate secure optical communications in space. CACI International has been building a robust capability in laser communications, most recently with the acquisition of SA Photonics. DARPA recently launched two Mandrake satellites which employ SA Photonics/CACI laser communications terminals. CACI also provided the laser terminals for NASA’s initial LCRD experiments communicating with platforms in LEO as part of the Illuma program and for the DSOC program.

The race is on to equip future satellites with laser-based communications systems. As one space-oriented publication observed, this is the only choice for constellation building projects and deep space missions. The U.S. government and industry must continue to invest in the necessary optical technologies to create a robust and affordable domestic laser communications capability.

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Dr. Daniel Goure, a 1945 Contributing Editor, is Senior Vice President with the Lexington Institute, a nonprofit public-policy research organization headquartered in Arlington, Virginia. He is involved in a wide range of issues as part of the institute’s national security program. Dr. Goure has held senior positions in both the private sector and the U.S. Government. Most recently, he was a member of the 2001 Department of Defense Transition Team. Dr. Goure spent two years in the U.S. Government as the director of the Office of Strategic Competitiveness in the Office of the Secretary of Defense. He also served as a senior analyst on national security and defense issues with the Center for Naval Analyses, Science Applications International Corporation, SRS Technologies, R&D Associates, and System Planning Corporation.




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