The test free-electron laser (test-FEL) at MAX-lab in Lund demonstrated for the first time circularly

polarized coherent femtosecond pulses at 66 nm wavelength. A 375 MeV electron bunch

was seeded by a femtosecond laser at 263 nm and coherent harmonics were extracted in an

APPLE-II type elliptical undulator. A thermionic gun with a barium oxide cathode was adapted

for photocathode operation, and the performance of the gun was tested. Measurements

showed the production of 200 pC of electrons with a normalized emittance of 5.5 mmmrad

and a quantum efficiency of 1.1 10-4. To ensure the electron bunch overlap with the 500 fs

seed laser pulse and to measure the bunch length, an electro-optical spectral decoding setup

was built. The bunch length of about 1 ps was measured and it was determined that the longterm

drifts in timing were accelerator-related. Electro-optical spectral decoding was used for

the first time for online feedback to stabilize the overlap between the laser pulse and the electron

bunch. This stabilization ensured lasing of the FEL on every shot and contributed to the

detection of higher linearly polarized harmonics (44 nm). This thesis presents an introduction

to the processes that occur in the undulators: modulation, bunching and radiation. It describes

the test-FEL setup and the emittance of an electron beam. Electro-optical spectral decoding is

explained and its advantages and limitations are discussed. The feedback based on a simple

controller is presented.