Commercial Lunar Payload Services
Commercial Lunar Payload Services is a NASA program to contract transportation services able to send small robotic landers and rovers to the Moon's south polar region mostly with the goals of scouting for lunar resources, testing in situ resource utilization concepts, and performing lunar science to support the Artemis lunar program. CLPS is intended to buy end-to-end payload services between Earth and the lunar surface using fixed priced contracts.
The CLPS program is being operated by NASA Headquarter's Science Mission Directorate, in-conjunction with the Human Exploration and Operations and Science Technology Mission Directorates. NASA expects the contractors to provide all activities necessary to safely integrate, accommodate, transport, and operate NASA payloads, including launch vehicles, lunar lander spacecraft, lunar surface systems, Earth re-entry vehicles and associated resources. Flight opportunities are scheduled to start in mid 2020.
History
NASA has been planning the exploration and use of natural lunar resources for many years. A variety of exploration, science, and technology objectives that could be addressed by regularly sending instruments, experiments and other small payloads to the Moon have been identified by NASA.When the concept study on the Resource Prospector rover was cancelled in April 2018, NASA officials explained that lunar surface exploration will continue in the future, but using commercial lander services under a new CLPS program. Later that April, NASA launched the Commercial Lunar Payload Services program as the first step in the solicitation for flights to the Moon. In April 2018, CLPS issued a Draft Request for Proposal, and in September 2018 the actual CLPS Request for Proposal was issued. The text of the formal solicitation and selected contractors are here:
On 29 November 2018, NASA announced the first nine companies that will be allowed to bid on contracts, which are indefinite delivery, indefinite quantity contracts with a combined maximum contract value of $2.6 billion during the next 10 years. The first formal solicitation is expected sometime in 2019.
In February 2018 NASA issued a solicitation for Lunar Surface Instrument and Technology Payloads that may become CLPS customers. Proposals were due by November 2018 and January 17, 2019. NASA plans to make yearly calls for proposals.
On May 31, 2019, NASA announced a list of awards, featuring Astrobotic, of Pittsburgh, Pa., $79.5 million; Intuitive Machines, of Houston, Texas, $77 million; and OrbitBeyond, $97 million; to launch their Moon landers. However, Orbit Beyond dropped out of this contract in July 2019, but remains a contractor able to bid on future missions.
On 18 November 2019, NASA added five new contractors to the group of companies who are eligible to bid to send large payloads to the surface of the moon with to the CLPS program: Blue Origin, Ceres Robotics, Sierra Nevada Corporation, SpaceX, and Tyvak Nano-Satellite Systems.
On 8 April 2020, it was announced that NASA had awarded the fourth CLPS contract for Masten Space Systems. The contract, worth US$ 75.9 million, is for Masten's XL-1 lunar lander to deliver payloads from NASA and other customers to the south pole of the Moon in late 2022.
Overview
The competitive nature of the CLPS program is expected to reduce the cost of lunar exploration, accelerate a robotic return to the Moon, sample return, resource prospecting in the south polar region, and promote innovation and growth of related commercial industries. The payload development program is called Development and Advancement of Lunar Instrumentation, and the payload goals are exploration, in situ resource utilization, and lunar science. The first instruments are expected to be selected by Summer 2019, and the flight opportunities start in 2021.Multiple contracts will be issued, and the early payloads will likely be small because of the limited capacity of the initial commercial landers. The first landers and rovers will be technology demonstrators on hardware such as precision landing/hazard avoidance, power generation, in situ resource utilization, cryogenic fluid management, autonomous operations and sensing, and advanced avionics, mobility, mechanisms, and materials. This program requires that only US launch vehicles can launch the spacecraft. The mass of the landers and rovers can range from miniature to, with a lander targeted to launch in 2022.
The Draft Request for Proposal's covering letter states that the contracts will last up to 10 years. As NASA's need to send payloads to the lunar surface arises it will issue Firm-Fixed Price 'task orders' that the approved prime contractors can bid for. A Scope Of Work will be issued with each task order. The CLPS proposals are being evaluated against five Technical Accessibility Standards.
NASA is assuming a cost of one million dollars per kilogram delivered to the lunar surface.
Contractors
The companies selected are considered "main contractors" that can sub-contract projects to other companies of their choice. The first companies granted the right to bid on CLPS contracts were chosen in 2018.On May 31, 2019, three of those were awarded lander contracts: Astrobotic Technology, Intuitive Machines, OrbitBeyond.
On July 29, 2019, NASA announced that it had granted OrbitBeyond's request to be released from this specific contract, citing "internal corporate challenges".
In April 2020, NASA selects Masten Space Systems to deliver cargo to the Moon in 2022.
List of contractors
The contractors selected for CLPS are:| Selection date | Company | Headquarters | Proposed services | Awarded contract |
| 29 November 2018 | Astrobotic Technology | Pittsburgh, Pennsylvania | Peregrine lander | |
| 29 November 2018 | Deep Space Systems | Littleton, Colorado | Rover; design and development services | |
| 29 November 2018 | Draper Laboratory | Cambridge, Massachusetts | Artemis-7 lander | |
| 29 November 2018 | Firefly Aerospace | Cedar Park, Texas | Firefly Genesis lander based on Israel's Beresheet; Firefly Alpha and Beta launch vehicles. | |
| 29 November 2018 | Intuitive Machines | Houston, Texas | Nova-C lander | |
| 29 November 2018 | Lockheed Martin Space | Littleton, Colorado | McCandless Lunar Lander | |
| 29 November 2018 | Masten Space Systems | Mojave, California | XL-1 lander | |
| 29 November 2018 | Moon Express | Cape Canaveral, Florida | MX-1, MX-2, MX-5, MX-9 landers; sample return. | |
| 29 November 2018 | OrbitBeyond | Edison, New Jersey | Z-01 and Z-02 landers | |
| 18 November 2019 | Blue Origin | Kent, Washington | Blue Moon lander | |
| 18 November 2019 | Ceres Robotics | Palo Alto, California | ||
| 18 November 2019 | Sierra Nevada Corporation | Louisville, Colorado | ||
| 18 November 2019 | SpaceX | Hawthorne, California | Starship | |
| 18 November 2019 | Tyvak Nano-Satellite Systems | Irvine, California |
- The companies awarded lander contracts displayed in bold.
- OrbitBeyond was awarded contract but later released.
Payload selection
First batch
The first twelve NASA payloads and experiments were announced on February 21, 2019, and will fly on separate missions. NASA hoped to assign the first mission in May 2019 before selecting specific payloads for that flight. This was realized May 31, 2019, when NASA released the list of the first companies to participate in the program.- Linear Energy Transfer Spectrometer, to monitor the lunar surface radiation.
- Magnetometer, to measure the surface magnetic field.
- Low-frequency Radio Observations from the Near Side Lunar Surface, a radio experiment to measure photoelectron sheath density near the surface.
- A set of three instruments to collect data during entry, descent and landing on the lunar surface to help develop future crewed landers.
- Stereo Cameras for Lunar Plume-Surface Studies is a set of cameras for monitoring the interaction between the lander engine plume and the lunar surface.
- Surface and Exosphere Alterations by Landers, another landing monitor to study the effects of spacecraft on the lunar exosphere.
- Navigation Doppler Lidar for Precise Velocity and Range Sensing is a velocity and ranging lidar instrument designed to make lunar landings more precise.
- Near-Infrared Volatile Spectrometer System, is an imaging spectrometer to analyze the composition of the lunar surface.
- Neutron Spectrometer System and Advanced Neutron Measurements at the Lunar Surface, are a pair of neutron detectors to quantify the hydrogen -and therefore water near the surface.
- Ion-Trap Mass Spectrometer for Lunar Surface Volatiles, is a mass spectrometer for measuring volatiles on the surface and in the exosphere.
- Solar Cell Demonstration Platform for Enabling Long-Term Lunar Surface Power, a next-generation solar array for long-term missions.
- Lunar Node 1 Navigation Demonstrator, a navigation beacon for providing geolocation for orbiters and landing craft.
Second batch
- MoonRanger, a small, fast-moving rover that has the capability to drive beyond communications range with a lander and then return to it. Astrobotic Technology, Inc.
- Heimdall, a flexible camera system for conducting lunar science on commercial vehicles. Planetary Science Institute.
- Lunar Demonstration of a Reconfigurable, Radiation Tolerant Computer System, which will demonstrate a radiation-tolerant computing technology. Montana State University.
- Regolith Adherence Characterization Payload, which will determine how lunar regolith sticks to a range of materials exposed to the Moon's environment. Alpha Space Test and Research Alliance, LLC.
- The Lunar Magnetotelluric Sounder, which will characterize the structure and composition of the Moon's mantle by studying electric and magnetic fields. Southwest Research Institute.
- The Lunar Surface Electromagnetics Experiment, which will make comprehensive measurements of electromagnetic phenomena on the surface of the Moon. University of California, Berkeley.
- The Lunar Environment heliospheric X-ray Imager, which will capture images of the interaction of Earth's magnetosphere with solar wind. Boston University.
- Next Generation Lunar Retroreflectors, which will serve as a target for lasers on Earth to precisely measure the Earth-Moon distance. University of Maryland.
- Lunar Compact InfraRed Imaging System, an infrared radiometer to explore the Moon's surface composition and temperature distribution. University of Colorado.
- The Lunar Instrumentation for Subsurface Thermal Exploration with Rapidity, an instrument designed to measure heat flow from the interior of the Moon. Texas Tech University.
- PlanetVac, a technology for acquiring and transferring lunar regolith from the surface to other instruments or place it in a container for its potential return to Earth. Honeybee Robotics, Ltd.
- SAMPLR: Sample Acquisition, Morphology Filtering, and Probing of Lunar Regolith, a sample acquisition technology that will make use of a robotic arm. Maxar Technologies.
List of missions contracted under CLPS
| Name | Launch | Contractor | Lander | Launch Vehicle | Notes | Outcome |
| Peregrine Mission One | June 2021 | Astrobotic Technology | Peregrine | Vulcan | Awarded in May 2019. Will carry 28 payloads, including 14 NASA payloads contracted under CLPS to Lacus Mortis on the Moon, landing is scheduled for June 2021. | |
| Intuitive Machines Mission 1 | October 2021 | Intuitive Machines | Nova-C | Falcon 9 | Awarded in May 2019. Will carry up to five NASA contracted payloads as well as payloads from other customers to Schroter's Valley on the Moon, the spacecraft will operate for up to 14 days after landing. | |
| Masten Mission One | December 2022 | Masten Space | XL-1 | TBA | Awarded in April 2020. Intended to deliver several hundred kg of payloads to the Lunar south pole, more information is expected once the mission draws closer. | |
| VIPER | NET 2023 | Astrobotic Technology | Griffin | TBA | First flight of Astrobotic's larger Griffin lander, Will deliver NASA's VIPER resource prospecting lunar rover to the Lunar south pole. Griffin is 450 kg, the award is for $199.5 M. |
Orbit Beyond returned their task order two months after award.