Twenty years of student satellites.  The original student CanSat satelllite project.   Nineteen years with 819 flights and 99.3% launch success. Not bad, eh?


What is ARLISS?


The ARLISS Project is a collaborative effort between students and faculty at universities (and some high schools) around the world, and high power rocketry enthusiasts in Northern California, to build, launch, test and recover prototype satellites, miniaturized to fit inside a soft drink can (hence "CanSats") in preparation for an Earth orbit or Mars orbit space launch.

ARLISS and the CanSat project challenge innovative students to get hands-on experience in the life-cycle (one year or less) of a space project. Each CanSat team will design and build one or more satellites, and travel to the launch site in Black Rock, Nevada to supervise preparation, launch, telemetry download and safe recovery of their experiments and data.

The ARLISS rocketry group provides launch vehicles and services, each capable of lofting and safely deploying one or more CanSats at an altitude of 12,000' AGL, affording each CanSat a "hang time" in the air of about 15 minutes for experiments, simulating a horizon-to-horizon low orbit pass.

Marking our twentieth year, ARLISS has grown to embrace more satellite missions, more launch profiles, more launch sites and more students.

ARLISS missions not only include flight data collection and telemetry, but integrate autonomous robots to direct satellites back to designated locations at the launch site.   And not only returning autonomously, but flying sophisticated science missions.

The ARLISS scope of launch profiles provide launch vehicles to carry a .3 Kg CanSat to 5k' AGL with sensors and telemetry, a 1 Kg Open Classic satellite to deploy into a airplane to autonomously return to its launch site from 12kk' AGL, or a PocketQube or CanSat to 120k' AGL with ARLISS Extreme.

The core ARLISS experience is at Black Rock Nevada with ARLISS Cansat missions being flown wherever there are students and ARLISS fliers.

ARLISS began as a cooperative program between Professor Bob Twiggs of Stanford, his colleagues at other universities worldwide and members of AeroPac led by Pius Morizumi and Tom Rouse. The first ARLISS event was held in 1999.

Goals. The goals of the program are to provide a learning experience - both for advanced high school and college level students and for AeroPac members (fliers) as well.

For the students - they learn the complete collaborative design process to design a complex electronic and computer payload (a satellite) that will have to operate in a standard, but harsh environment. For the fliers, they learn to hone their skills of designing highly reliable and repeatable flight operations.

Key to the ARLISS program are reliable flight and support operations provided by ARLISS and AeroPac members.

The ARLISS team and AeroPac provide the infrastructure for the event. Airframes built to deliver standard payloads to consistent altitudes. Motors are provided for each launch.  Provide motors for each launch. Provide a launch site and launch operations including FAA, BLM and other regulatory agency management. Provide basic sanitary facilities.  Provide a one stop, non-profit financial support for launch fees, flight operations costs, and regulatory fees.

And most importantly - reliable delivery of standard payloads (CanSat and Open) to a reasonably consistent altitude (~11k' AGL at Black Rock). The ARLISS team takes extraordinary pride in a 99.3% launch success of student payloads.

The program has evolved over the years. While initially focused on rather unintelligent (by today's standards) student satellites the size of soft drink can (and launched three at a time - rather like Bob Twigg's CubeSats), the program quickly moved to where the dominant payload is the Open Class of a single coffee can sized payload containing a complex satellite capable of autonomous operation with heavy use of real-time bidirectional radio communications, GPS and autonomous robotic design. The ComeBack competition of the last few years has seen some dramatic technology of remote rovers, fliers and sophisticated communications both in flight and on the ground. A second airframe using K motors has been developed to allow lower cost, more convenient flights of Classic CanSat payloads alongside of M motored Open Class flights.   ARLISS Extreme has been developed to take PocketQube and CanSat payloads to the edge of space at over 100k' AGL.