Tag: LPF

LISA Pathfinder was an international effort under European leadership. Scientific institutes, ESA and industry  worked closely together:

• Science Working Team: The LISA Pathfinder Science Team provided ESA with advice on all aspects of Science and Technology related to the mission. The team was chaired by the LPF Project Scientist, and composed of seven members from ESA member states, and representatives for the LISA project, both in Europe and the US.
• ESA commissioned the European aerospace company Astrium Ltd (an EADS company) at Stevenage, Great Britain to be the Prime Contractor for the mission and to build the LISA Pathfinder spacecraft, i.e., the payload carrier.
• The LISA Technology Package (LTP) was built by a consortium of European space companies from France, Germany, Great Britain, Italy, Netherlands, Spain and Switzerland led by the industrial partner EADS Gmbh (an EADS company), Friedrichshafen, Germany.
• The second payload package, the Disturbance Reduction System (DRS), was developed in the United States by JPL (Jet Propulsion Laboratory) under the leadership of NASA. It provided a system of Micro-Newton thrusters complementary to the on-board LTP technology with a dedicated control system.

Preparing for LPF operations meant developing the analysis, building the tools and training the team.

Given the relatively short duration planned for mission operations (90 days), the data analysis team had to be extremely well prepared. This meant that not only did the in-orbit experiments have to be defined well in advance, but the analysis routines and the associated tools also had to be prepared and tested.

Using the LTPDA Toolbox framework, analysis pipelines had been being developed to analyse the extensive menu of possible experiments which formed the mission time-line during operations. These pipelines, and the component tools, were then tested on simulated data sets which were generated using a variety of LPF simulators. From linear state-space models to non-linear simulators running the flight software, the data analysis team leveraged all available simulators to test the tools and procedures on as wide a range of data sets as possible.

In addition to the development and testing of the experiment procedures and associated analysis pipelines, the data analysis team had to prepare itself for the intense period of operations, during which the data needed to be analysed essentially in real-time so that the subsequent investigations could be first properly selected, and second appropriately configured. The output of each investigation also yielded information with which the operations team configured the spacecraft and the LTP to best achieve the mission goals.

Part of this preparation involved exposing the team to mission-like scenarios in which simulated data sets were delivered to the team as if they had just been downloaded from the spacecraft. The teams on duty then analysed the data, drew conclusions, fully documented the activity, and worked with the operations engineers to ensure the correct configuration of the mission timeline at all times. These operations training simulations typically lasted for about 1 week, with the team being split into sub-teams to take shifts at ESA’s Astronomy Center (ESAC) near Madrid. An additional set of teams was deployed to the Complementary Data Center located at the APC in Paris.

LISA Pathfinder paved the way for the LISA mission by testing in space the very concept of gravitational wave detection.

The quietest place in the solar system

LPF launched successfully on 3rd December 2015 at 4:04 GMT. After a picture perfect start, a journey to its destination some 1.5 million kilometers from Earth towards the Sun, and a successful release of the test masses, LISA Pathfinder began its job as a space laboratory on 1 March.

https://youtu.be/1j0YGl8oXbw?si=YT5WWy836CluhKAw
The Path to LISA in 90 seconds
The LISA Pathfinder Mission Teaser: Follow LISA Pathfinder’s story from the assembly of its heart, the optical bench through testing to the assembly of the spacecraft and getting it ready for launch. Meet some of the key people who are involved and learn how the mission operates.
© Max Planck Institute for Gravitational Physics / Milde Marketing Science Communication

LISA Pathfinder (LPF) placed two test masses in a nearly perfect gravitational free-fall, and controls and measures their relative motion with unprecedented accuracy. This was achieved through innovative technologies comprising inertial sensors, an optical metrology system, a drag-free control system and micro-Newton thruster system. The test-masses and their environment were at that time the quietest place in the solar system.

With LISA Pathfinder, scientists have created the quietest place known to humankind. Its performance exceeded all  expectations by far. Observing the most perfect free fall ever created was only made possible by reducing and eliminating all other sources of disturbance.

The first results, presented in June 2016, show that the two test masses at the heart of the spacecraft are falling freely through space under the influence of gravity alone. They are unperturbed by other external forces, to a precision more than five times better than originally required. The results show that the test masses are almost motionless with respect to each other, with a relative acceleration lower than 1 part in ten millionths of a billionth of Earth’s gravitational acceleration. This corresponds to the weight of a virus on Earth.

All these technologies are not only essential for LISA, they also lie at the heart of any future space-based test of Einstein’s General Relativity. The successful demonstration of the mission’s key technologies thus opens the door to the development of a large space observatory capable of detecting gravitational waves emanating from a wide range of exotic objects in the Universe.