A new type of photodetector called "photosensitive floating field emitter, (PFFE)" has been proposed. The PFFE device combines an n-type cone-shaped triode field emitter with a-Si p-i-n photodiode film. However, a PFFE cannot detect two-dimensional distributions of light intensity. In this paper, we propose a novel structure to overcome the above this problem of the PFFE. The device was fabricated on a silicon-on-sapphire substrate to permit irradiation from the backside. p-n photodiodes were constructed within a field emitters, the n+ region being separated by p+ regions to permit detection of two- dimensional light distributions. The emission current of the PFFE/SOS was found to be proportional to the illumination intensity, but the quantum efficiency was only about 2%. This quantum efficiency is lower than that expected. Under irradiation, the emission current increased, but the gate-leakage current increased. This gate-leakage current was several orders of magnitude larger than the emission current. Almost photo-generated electrons lost in the gate electrode.

To visualize the biochemical distribution two-dimensionally, we invented a solid-state-type ion image sensor that indicates the chemical activity of solutions and cells. The device, which consists of a CCD array covered with a functionalized membrane to detect charge accumulation, is highly sensitive to changes in the concentration and two-dimensional distribution of ions and biomaterials.

In this paper, a novel method of clock feedthrough reduction in CMOS autozeroed operational amplifiers with three-phase clock operation is presented. The operational amplifiers in the method are configured by two autozeroed-gain stages. The differential input stage and the second output gain stage are autozeroed individually by a three-phase clock for autozeroing. The three-phase clock is provided so as to finish the compensation period of the input stage earlier than the end of the second stage compensation period. This operation makes it possible to absorb affection of clock feedthrough in the input stage with the second stage. As a result, residual error of offset compensation is much reduced by the voltage gain of the first stage. The effect of the two-stage autozeroing has been confirmed with SPICE simulation and fabricated CMOS circuit. The results of SPICE simulation showed that the two-stage autozeroed operational amplifier has significant advantage as compared to conventional configuration. Affection of clock feedthrough is reduced to about 1/50 in the two-stage configuration. Fabricated CMOS circuit also showed high potential of the two-stage autozeroed operational amplifier for feedthrough reduction. It has been proven experimentally that the two-stage autozeroing is an effective design approach to reduce clock feedthrough error in CMOS autozeroed operational amplifiers.

Because redox sensors can detect multi-ions and the concentration within a single sensing area using current and potential signals, they have been studied for chemical analysis applications. A small sensing area and a low concentration measurement typically reduce the output current of a redox sensor. Therefore, we previously fabricated the Amplified Redox Sensor, which has a working electrode combined with a bipolar transistor to amplify a small current signal. However, the current gain of the bipolar transistor had been changed by the redox current because the redox current flows in the base terminal of the bipolar transistor. In this study, we propose a new measurement method in which an offset current is inserted along with the redox current in the base terminal. The proposed measurement method can detect potassium ferricyanide (K3[Fe (CN)6]) concentrations as low as 1μM using the Square Wave Voltammetry method.