A radar-type microwave imaging system utilizing a Doppler sensor which contains a Gunn oscillator is described. In the system, the synchronous detector is modified to dual diode detection in order to obtain complex hologram. Experimental results are also described.

Spectral properties of an unlocked semiconductor laser under an external light injection are numerically analyzed and experimentally observed. It is found that the unlocked spectrum consists of a shifted carrier and a number of harmonics and that their distributions are varied by the detuning.

The influence of 1/f noise in FM noise on the spectral linewidth of semiconductor lasers in a normal operation has been investigated. The linewidth calculated from the FM noise spectrum considering the 1/f noise agrees with that obtained from the delayed self-heterodyne method.

A novel and simple measuring method for locking bandwidths of injection-locked semiconductor lasers is proposed. The measuring system based on this method can visualize the overall locking bandwidth and quickly measure the boundaries. Some experimental results are also presented.

An all-fibre sensing system having both a high handling capability and an enhanced stability has been developed by introducing a tapered fibre to laser coupling, fibre polarizers, and a threefold switching of laser injection current. Possible factors responsible for erroneous measurement are also inspected and the resultant error is estimated less than 0.01 K.

A novel measuring system on the amplitude and phase of the RF magnetic field is proposed. It is composed of a laser diode (LD) linked with a small loop antenna, an optical fiber transmission line, and phase-sensitive detection instruments. The LD output light is directly intensity-modulated by the RF current induced in the loop antenna by the RF magnetic field under test. The instantaneous amplitude and phase of the RF magnetic field are preserved in the modulated light because of the quick response of LD and are detected by the remote detection system. The characteristics of the calibration, the sensitivity, the minimum detectable field, and the frequency response are analyzed in detail. The system is highly sensitive, nonperturbing, and noninteractive. In addition to these advantages, the excellent property for measuring the phase of the RF magnetic field is experimentally confirmed by many field measurements. Resultantly, the minimum detectable RF magnetic field is obtained as 10 µA/cm (38 nW/cm2 in power density) remarkably lower than others.

The coherence characteristics of semiconductor laser driven by high-frequency current injection are measured under various operation conditions. The measured results are in agreement with analytical results derived from a simple model, in which all the modes are individually frequency-modulated.