The Cray-3 was a vector supercomputer, Seymour Cray's designated successor to the Cray-2. The system was one of the first major applications of gallium arsenide (GaAs) semiconductors in computing, using hundreds of custom built ICs packed into a 1 cubic foot (0.028 m³) CPU. The design goal was performance around 16 GFLOPS, about 12 times that of the Cray-2.

Work started on the Cray-3 in 1988 at Cray Research's (CRI) development labs in Chippewa Falls, Wisconsin. Other teams at the lab were working on designs with similar performance. To focus the teams, the Cray-3 effort was moved to a new lab in Colorado Springs, Colorado later that year. Shortly thereafter, the corporate headquarters in Minneapolis decided to end work on the Cray-3 in favor of another design, the Cray C90. In 1989 the Cray-3 effort was spun off to a newly formed company, Cray Computer Corporation (CCC).

The launch customer, Lawrence Livermore National Laboratory, cancelled their order in 1991 and a number of company executives left shortly thereafter. The first machine was finally ready in 1993, but with no launch customer, it was instead loaned as a demonstration unit to the nearby National Center for Atmospheric Research in Boulder. The company went bankrupt in May 1995, and the machine was officially decommissioned.

With the delivery of the first Cray-3, Seymour Cray immediately moved on to the similar-but-improved Cray-4 design, but the company went bankrupt before it was completely tested. The Cray-3 was Cray's last completed design; with CCC's bankruptcy, he formed SRC Computers to concentrate on parallel designs, but died in a car accident in 1996 before this work was delivered.

Seymour Cray began the design of the Cray-3 in 1985, as soon as the Cray-2 reached production. Cray generally set himself the goal of producing new machines with ten times the performance of the previous models. Although the machines did not always meet this goal, this was a useful technique in defining the project and clarifying what sort of process improvements would be needed to meet it. For the Cray-3, he decided to set an even higher performance improvement goal, an increase of 12x over the Cray-2.

Cray had always attacked the problem of increased speed with three simultaneous advances; more execution units to give the system higher parallelism, tighter packaging to decrease signal delays, and faster components to allow for a higher clock speed. Of the three, Cray was normally least aggressive on the last; his designs tended to use components that were already in widespread use, as opposed to leading-edge designs.

For the Cray-2, he introduced a novel 3D-packaging system for its integrated circuits to allow higher densities, and it appeared that there was some room for improvement in this process. For the new design, he stated that all wires would be limited to a maximum length of 1 foot (0.30 m). This would demand the processor be able to fit into a 1 cubic foot (0.028 m³) block, about 1⁄3 that of the Cray-2 CPU. This would not only increase performance but make the system 27 times smaller.

For a 12x performance increase, the packaging alone would not be enough, the circuits on the chips themselves would also have to speed up. The Cray-2 appeared to be pushing the limits of the speed of silicon-based transistors at 4.1 ns (244 MHz), and it did not appear that anything more than another 2x would be possible. If the goal of 12x was to be met, more radical changes would be needed, and a "high tech" approach would have to be used.