About Michael Paluszek

Michael Paluszek is President of Princeton Satellite Systems. He graduated from MIT with a degree in electrical engineering in 1976 and followed that with an Engineer's degree in Aeronautics and Astronautics from MIT in 1979. He worked at MIT for a year as a research engineer then worked at Draper Laboratory for 6 years on GN&C for human space missions. He worked at GE Astro Space from 1986 to 1992 on a variety of satellite projects including GPS IIR, Inmarsat 3 and Mars Observer. In 1992 he founded Princeton Satellite Systems.

ARPA-E Award for Compact Nuclear Fusion Power

Princeton Fusion Systems, a fully owned subsidiary of Princeton Satellite Systems, has been awarded $1.25 Million from ARPA-E for Low-Radioactivity Compact Fusion Devices

Today ARPA-E announced announced that PFS has received a competitive $1.25 million award from the U.S. Department of Energy’s Advanced Research Projects Agency-Energy (ARPA-E), as part of the Energy cohort of OPEN 2018.

Princeton Fusion Systems seeks to develop technologies to enable future commercial fusion power. Our team’s concept is a small, clean, and portable design based on a field-reversed-configuration plasma. The concept uses an innovative method called odd-parity rotating magnetic field (RMF) to drive electrical current and heat the plasma to fusion temperatures. Under this award, the team will pursue improved electron and ion temperatures through RMF, as well as identify the modeling needed to elucidate the key heating and loss mechanisms for the fusion reactor concept. The team’s ultimate power plant design seeks a very small footprint for a compact, potentially transportable, distributed energy resource that is fully dispatchable and emissions-free.
PFS received this competitive award from ARPA-E’s OPEN 2018 program, in which teams develop innovative technologies to transform the nation’s energy system. OPEN solicitations are an open call to scientists and engineers for technologies across the entire scope of ARPA-E’s energy mission.

This work complements three NASA grants for the development of this technology for nuclear fusion rockets for human and robotic space exploration. This includes the NASA Phase II NIAC Grant, “Fusion-Enabled Pluto Orbiter and Lander,” and a NASA Phase II STTR, “Superconducting Coils for Small Nuclear Fusion Rocket Engines“, and a Phase I STTR, “High Efficiency RF Heating for Small Nuclear Fusion Rocket Engines.”. These contracts build on over 20 years of collaborative work between Princeton Fusion Systems and the Princeton University Princeton Plasma Physics Laboratory. This unique nuclear fusion concept was invented by Dr. Samuel Cohen of the Princeton Plasma Physics Laboratory.

Princeton Satellite Systems was founded by Mr. Michael Paluszek in 1992 to develop advanced space and terrestrial technology. It has developed a wide range of space and terrestrial technology including advanced spacecraft control and navigation systems, formation flying systems and terrestrial energy systems including solar, wind and nuclear fusion.

Princeton University Science and Technology Job Fair 2018

Princeton Satellite Systems had a table at the Princeton University Science and Technology Job Fair on Friday, October 12. Many companies attended including the IBM Thomas J. Watson Laboratory, Facebook and Siemens.

We had on display hardware and software that involved the work of interns at PSS. The exhibits were of great interest to the many students who came by our table.

From left to right is an iPhone App for talking with a reconnaissance satellite, a lunar landing simulation on the LCD monitor, parts of an optical navigation system, a Class E RF amplifier, a reaction wheel and a frame for a small satellite. Many students who came by were very knowledgeable about our work.

Here I am talking with one of the students.

It was great event! We look forward to talking with the students when we interview for summer and full time jobs in January.

Young Women’s Conference in STEM

Princeton Satellite Systems attended the Young Women’s Conference in STEM in at the Frick Laboratory on the Princeton University campus again this year. We had an exhibit with spacecraft hardware and software. This include 3D printed models of our fusion reactor core and a 2 stage to orbit launch vehicle, star and navigation cameras, a circuit board for driving a fusion reactor and a 3U CubeSat frame . We were also running a simulation of a Lunar Landing simulation.

We met many enthusiastic students this year! It seemed that there were more high school students than in past years. A budding plasma physicist asked how we fuel the Direct Fusion Drive engine. Another student, looking at our Lunar Lander simulation display, asked what is a quaternion! The disassembled reaction wheel was very popular.  Some students wanted a detailed explanation about how the motor worked. One student wanted to know the electrical details of our RF board. Several were interested in our Army iPhone app. One wanted to know if she could get it from the App Store.

Other attendees included Lockheed Martin, the FBI and the Princeton Plasma Physics Laboratory. Click on this image to see a video about the event.

It was a fun event, albeit exhausting given the four hours of continuous conversations. We do hope that we inspired some of the attendees to pursue careers in science, math and engineering!

Inter Ivy Space Coalition Meeting

Marilyn and I attended the first Inter Ivy Space Coalition Inter Ivy Space Coalition meeting at Yale University on April 6 and 7.

The meeting was attended by students with an interest in space from the Ivy League schools. Saturday consisted of talks by speakers from a wide range of organizations followed by an exhibition and a banquet. Jonathan Li of Yale was the driving force behind this excellent conference.

The Dean of Engineering of Yale opened the meeting talking about the Yale Undergraduate Aerospace Association. They have done a wide variety of space work including some very large rockets. One student later showed me the nozzle for their latest rocket.

Dr. Fuk Li of JPL, Director Mars Exploration Directorate, talked about Mars 2020. The mission with its very sophisticated rover, will look for indigenous life, study climate and geology and prepare for Exploration. One ambitious goal is to eventually return Mars samples. The challenge of the sample return is to not contaminate the Earth as in the movie The Andromeda Strain.

Prof. Alessandro Gomez of Yale gave a nice talk on electrospray thrusters. The thrusters will be very valuable for small satellite missions.

Suresh Kannan talked about Trustable Autonomous Aerospace Systems. He had great videos from Nvidia on autonomous car control systems and videos from Boston Dynamics showing their amazing robots.

Ellen Chang, co-founder of  Lightspeed Innovations is a former U.S. Navy Intelligence Officer and a graduate of the Naval Postgraduate School. She talked about the state of investment in space. She mentioned a couple of investments organizations, including IQT, which was started by the CIA! She said a key issue for space companies is that investors can’t wait 20 years for their return on investment.

I gave the next lecture presenting the latest results on our work on Direct Fusion Drive.

Artist rendering of DFD rocket engine

We’ve been able to reduce the mass of our RF and superconducting coil subsystems dramatically. We have completed the radiation heat transfer analysis of the reactor which shows that it isn’t a big problem. Conduction will provide the major heat loads.

Here is a recent shot in our experimental facility.

I included a  teaser slide on our two stage to orbit vehicle that we are proposing to NASA and DARPA. It would be inexpensive enough for companies and universities to own their own launch vehicle. It is fully reusable and could be launched at any convenient airport. It can also shuttle around the world at subsonic speeds. It is about the size of a private jet.

Alden Richards, founder of Space Machine Advisors, gave a fun talk on the space business. He insured the PanAmSat launch on which I worked. He said that the key for space profitability is dual use,

Jason Aspiotis of Finsophy talked about sources of funding for space. These include global sovereign funds that countries like Kuwait and Norway maintain. He  is a founder of  SpaceVault online banking and SpaceXchange.

Dr. Jonathan Arenberg of  Northrop-Grumman talked about the Chandra X-Ray telescope. He also talked about future missions for imaging exo-planets. Dr. Arenberg is second from the left on the linked page.

Ulisses Ortiz of  Space for Humanity talked about his plan to make sub-orbital flights available to anyone. People selected would make a commitment to using the publicity for a good cause.

Kari Love of  Soft Robotics gave a great talk on how to win contracts. She said you need to get to know people by going to conferences and responding to RFIs. She said you can make contacts by going to non-space events, like science fiction conventions. She recommended using professional illustrators for key graphics. Kari has a interesting background. She designed the Spiderman costume for the Broadway musical!

Dr. Lin Chambers Atmospheric Scientist at NASA/LaRC, gave the final talk of the day. Unfortunately, we were setting up our table for the networking fair so we missed her talk!

Princeton Satellite Systems had a table at the networking fair. The TV is showing a lunar landing simulation. We had a disassembled reaction wheel, a sun sensor, a navigation camera and a 3D printed model of our two stage to launch vehicle, Space Rapid Transit Mini.

We talked with many students. All of our discussions were interesting. I talked at length with an English major interested in space!

Scott Willoughby of Northrop-Grumman and Program Manager of the James Webb Space Telescope  gave an overview of the program in the after dinner talk.

Here are the speakers and student organizers.

We look forward to next year’s meeting! 

Lunar Landing Control System

The first soft moon landings were accomplished in the 1960’s by the Soviet Luna 9 and the U.S. Surveyor Spacecraft. These were followed by the U.S. Lunar Module landings during the Apollo program. The Soviets had their own LK Lander lunar lander for landing humans on the moon but it never flew. China’s Chang’e-3 landed on the moon on December 13, 2013. India plans to land the Chandrayaan-2 on the moon in 2018.  South Korea intends to land a spacecraft on the moon in 2020.

The U.S. Lunar Module was flown by a crew but had a digital computer that performed guidance, navigation and control. A great new book by Don Eyles, Sunburst and Luminary an Apollo Memoir explains how that was accomplished with a computer less powerful than those in toaster ovens today. Don played a key role in saving the Apollo 14 mission when an abort light appeared on the crew’s console prior to descent. Read the book for for the whole story.

NASA intended follow-ons to the Lunar Module that would have been fully automated for delivering materials to the moon in preparation for a permanent human presence. Unfortunately, those plans never materialized.

As we are always looking for new missions for testing our Precision Attitude Control System, we added guidance, navigation and control for lunar landings. We use a really simple guidance algorithm called 2nd order guidance. It is nothing more than a Proportional Derivative (PD) controller with the landing spot as a target. You can adjust the damping ratio and undamped natural frequency of the controller to mimic more sophisticated, “optimal” guidance algorithms. The 2nd order guidance works until the lander gets near the surface and then it switches to landing algorithm that hovers, nulling any remaining translational velocities and then descends to the surface. Lidar would be used as guidance. Once it is hovering it would need to search for a flat spot for landing. NASA has developed Hazard Detection Software for Lunar Landing that uses lidar. It is available for licensing from Caltech.

Here is one simulation in our Simulation Framework. Once the descent is initiated, the spacecraft reorients so that the main engine thrust vector is in the desired direction. The display on the left shows the attitude errors (the two boxes) and the throttle setting (which is zero during the attitude maneuver.)

A close up of the attitude display. Pitch and yaw are offsets of the green rectangle. Roll is rotation of the rectangle. This is quite primitive but it is easy to add your own displays if you know a little OpenGL!

Descent starts and the throttle is about 50% at this point. The two plots are of altitude and velocity. The maneuver starts at 15 km and the target is 600 km along track. The lander has solar panels on a two-axis gimbal and a high gain antenna, also on a two-axis gimbal.

The propulsion page shows two attitude thrusters firing and the main engine.

The spacecraft has landed! You can see the terminal descent phase on the altitude and velocity plots. The lunar surface is featureless because we have not added close up maps of the landing zone to the planet display.

The descent page shows the throttle settings. You can monitor the guidance force demand and simulated force.

This is the propulsion page. The attitude thrusters get very busy during the terminal descent phase. Note that we have a lot of fuel left! We could have hovered for quite some time.

The graphics are from our VisualCommander product that runs on Mac OS X.

This GN&C system is capable of autonomous flight from LEO all the way to the moon. It uses our Optical Navigation System, developed under a NASA Phase II SBIR for trajectory determination on the flight to the moon and lunar orbit entry.

For more information contact us directly!

Fusion Power Associates Meeting

I attended the 2017 Fusion Power Associates meeting in Washington, D.C. on December 6 and 7. Fusion Power Associates is a non-profit, tax-exempt research and educational foundation, providing timely information on the status of fusion development and other applications of plasma science and fusion research.

The annual meeting brought together experts in all areas of nuclear fusion research including scientists and engineers from ITER, the Princeton Plasma Physics LaboratoryTAE TechnologiesGeneral Atomic and many others! The meeting gave a great overview of the state of nuclear fusion power generation. We learned that ITER is 50% complete and on its way to first plasma in 2025. Planning has begun on Demo, the follow-on to ITER.

The Joint European Torus plans a D-T campaign in 2019 and hopes to set new fusion benchmarks. We learned about Korea Superconducting Tokamak Advanced Research  (KStar). It has achieved longer than 70 second pulses in H-mode and has suppressed ELM for more than 34 seconds. KStar has in-vessel control coils.

There were several speakers from the University of Rochester along with colleagues from the national laboratories talking about advances in laser compression of fuel pellets. This work is for nuclear weapons research but could be applied to inertial confinement fusion.

I gave the last talk of the meeting on Princeton Satellite Systems and PPPL’s work on DFD, nuclear fusion propulsion for spacecraft.

Rendezvous with 1I/’Oumuamua

An interstellar asteroid, 1I/’Oumuamua, was discovered on a highly hyperbolic orbit by Robert Weryk on October 19, 2017 moving with a speed of  26.32 km/s. It appears to come from the direction of the star Vega in the constellation Lyra. It would be really great to send a mission to rendezvous and fly in formation with 1I/’Oumuamua to study the asteroid. The high velocity makes it hard to do with current technology.

Direct Fusion Drive (DFD) might provide a answer. We designed a spacecraft with a 1 MW DFD power plant and assumed a launch on March 16, 2030. The following plots show the trajectory and the force, mass and power of the spacecraft during the 23 year mission. As you can see we don’t have to use the full 1 MW for propulsion so we have plenty of power for data transmission and the science payload.


The code for this analysis will be available in Release 2018.1 of the Princeton Satellite Systems  Spacecraft Control Toolbox for MATLAB.