Abstract: A semiconductor device is formed in a self-light-emitting apparatus having a substrate and a plurality of self-light-emitting elements formed on the substrate. The semiconductor device is used to drive one of the self-light-emitting elements. The semiconductor device includes an active layer of semiconductor material, in which a source region and a drain region are formed. A source electrode has a multi-layered structure including an upper side layer of titanium nitride and a lower side layer of a high melting point metal having low resistance. The source electrode is electrically coupled to the source region. A drain electrode has a multi-layered structure including an upper side layer of titanium nitride and a lower side layer of a high melting point metal having low resistance. The drain electrode is electrically coupled to the drain region. An insulation layer is formed on the active layer. A gate electrode is formed on the insulation layer.

Abstract: An image display device having a plurality of pixcels with uniform light intensity comprises an organic EL element (3), a bias FET (2) for emit current control of said EL element, a capacitor (4) coupled with a gate electrode of said bias FET (2) for holding a signal, and a select FET (1) for selectively writing a signal to said capacitor (4), wherein the value S of said bias FET (2) is larger than that of said select FET (1).

Abstract: A light source image, i.e., a near field pattern of the light-emitting face of a laser diode which emits laser light having the electric field component in a predetermined direction is formed by an imaging lens at an image forming position of a smoke detecting area through which a flow of sucked air passes. A light receiving device is disposed on an optical axis which passes through the image forming position of a light source image in the smoke detecting area and which is set in a plane that is substantially parallel to the direction of the electric field component of the laser light, and receives scattered light due to a smoke particle passing through the imaging position of the light source image and the vicinity of the imaging position.

Abstract: A thin film transistor and a semiconductor device and a method for forming the same. A silicon thin film formed on an insulating substrate is heated at 550 to 800.degree. C. so that it has crystallinity, and a thin film transistor is formed using the crystalline silicon film thus obtained. Thermal contraction of the insulating substrate is set in a range of 30 to 500 ppm in the heating process, so that the thin film transistor has high mobility, low threshold voltage and high off-resistance. Thermal contraction of the insulating substrate may be also set 100 ppm or less in a heating process after a patterning treatment in a thin film transistor producing process.

Abstract: In an insulated gate field effect semiconductor device, the gate electrode formed on the gate insulating film includes the first and second semiconductor layers as a double layer. An impurity for providing one conductivity type is not contained in first semiconductor layer which is in contact with a gate insulating film and is contained at a high concentration in the second semiconductor layer which is not in contact with the gate insulating film. Accordingly, By existence of the first semiconductor layer is which the impurity is not doped, the impurity is prevented from penetrating through the gate insulating film from the gate electrode and diffusing into the channel forming region. Also, by existence of the second semiconductor layer in which high concentration impurity is doped, the gate electrode has low resistance.

Abstract: The pulse width of a light reception pulse signal a from a light receiving device is detected, and the smoke density is detected based on a total pulse width of pulse widths per unit time period. Alternatively, the smoke density may be detected based on an integrated value of the light reception pulse signal a from the light receiving device per unit time period. Even if the flow rate of the sucked air is varied, the total light reception pulse width value per unit time period is not varied, so that the smoke density can be accurately detected.

Abstract: An organic EL display device has a substrate, a plurality of organic EL elements formed on the substrate and a plurality of thin film transistors formed on the substrate. The transistors are connected to the respective EL elements for controlling current applied to the respective elements.

Abstract: A hybrid (composite) integrated circuit element comprises a substrate, a thin film type integrated circuit formed on a substrate through a thin film process, and a lamination type passive circuit element such as a capacitor, inductor, resitance and a combination thereof formed on the integrated circuit. During the firing of passive circuit element in a hydrogen atmosphere, the semiconductor layer which constitutes the integrated circuit is also heat annealed. Various substrates can be used as the substrate, for example, quartz, ceramic and a cheap semiconductor substrate which has not been treated with a mirror-grinding by the use of a glass layer.

Abstract: A thin film transistor which includes an insulation base, first and second gate electrodes, first and second insulation layers, an active layer of semiconductor material, a source electrode and a drain electrode, in which a lateral length of the first gate electrode is narrower than a lateral length of the second gate electrode. Also, the first gate is electrically insulated from the active layer of semiconductor material by the first insulation layer so that the drain current saturates in a high drain voltage region.

Abstract: A hybrid (composite) integrated circuit element comprises a substrate, a thin film type integrated circuit formed on a substrate through a thin film process, and a lamination type passive circuit element such as a capacitor, inductor, resitance and a combination thereof formed on the integrated circuit. During the firing of passive circuit element in a hydrogen atmosphere, the semiconductor layer which constitutes the integrated circuit is also heat annealed. Various substrates can be used as the substrate, for example, quartz, ceramic and a cheap semiconductor substrate which has not been treated with a mirror-grinding by the use of a glass layer.

Abstract: An organic EL display device has a substrate, a plurality of organic EL elements formed on the substrate and a plurality of thin film transistors formed on the substrate. The transistors are connected to the respective EL elements for controlling current applied to the respective elements.

Abstract: In an insulated gate field effect semiconductor device, the gate electrode formed on the gate insulating film includes the first and second semiconductor layers as a double layer. An impurity for providing one conductivity type is not contained in first semiconductor layer which is in contact with a gate insulating film and is contained at a high concentration in the second semiconductor layer which is not in contact with the gate insulating film. Accordingly, By existence of the first semiconductor layer is which the impurity is not doped, the impurity is prevented from penetrating through the gate insulating film from the gate electrode and diffusing into the channel forming region. Also, by existence of the second semiconductor layer in which high concentration impurity is doped, the gate electrode has low resistance.

Abstract: A substrate (1) has a surface covered with an insulation layer (2), on which an active layer (3') made of non-single crystal silicon through thin film technique is provided. A gate electrode layer (5') is partially provided on said active layer through a gate insulation layer (4). Said active layer (3') is subject to injection of P-type or N-type impurities to provide an image sensor of MOS structure. Bias potential is applied to a gate electrode so that a circuit between a source and a drain is in an On state, so that input light through said substrate or said gate electrode is applied to said active layer, and electrical output depending upon said input light is obtained from said source electrode or said drain electrode. Other MOS transistors for switching element and/or shift registers for operating said image sensor are provided on said substrate (1).

Abstract: An image sensor (10) has a substrate (1), an active layer (3') having a source region and a drain region placed on said substrate (1), a gate insulation layer (4') placed on said active layer, and a gate electrode layer (5') on said gate insulation layer (4'). The active layer (3') is produced by the steps of producing amorphous silicon layer by using disilane gas (Si.sub.2 H.sub.6) through Low Pressure CVD process, and annealing said layer at 500.degree.-650.degree. C. for 4-50 hours in nitrogen gas atmosphere. The gate insulation layer (4') is produced through oxidation of the surface of the active layer at high temperature around 900.degree.-1100.degree. C. The oxidation process at high temperature improves the anneal process and improves the active layer. Thus, an image sensor with uniform characteristics is obtained with improved producing yield rate.

Abstract: A substrate (1) has a surface covered with an insulation layer (2), on which an active layer (3') made of non-single crystal silicon through thin film technique is provided. A gate electrode layer (5') is partially provided on said active layer through a gate insulation layer (4'). Said active layer (3') is subject to injection of P-type or N-type impurities to provide an image sensor of MOS structure. Bias potential is applied to a gate electrode so that a circuit between a source and a drain is in an On state, so that input light through said substrate or said gate electrode is applied to said active layer, and electrical output depending upon said input light is obtained from said source electrode or said drain electrode. Other MOS transistors for switching element and/or shift registers for operating said image sensor are provided on said substrate (1).

Abstract: A light emitting device for projecting a light beam onto a monitor area, and a light receiving device, arranged so that a light beam is not directly received by the device, for receiving diffused light caused as a result of fine particles, such as dust, or smoke caused by a fire, entering the monitor area, are provided. Also, an amplifying device for amplifying an output from the light receiving device, and a counting device for counting the output from the amplifying device in units of time are provided. In addition, a computing device for computing an average value or an integrated value of the output from the amplifying device in units of time, and a determining device for determining the level of contamination of the monitor area on the basis of the count value of the counting device and for determining the level of the fire on the basis of the average value or the integrated value computed by the computing device, are provided.

Abstract: A MOS-FET transistor is produced on a substrate made of glass which has a non single crystal semiconductor film (2'). The average diameter of a crystal grain in said film is in the range between 0.5 times and 4 times of thickness of said film, and said average diameter is 250 .ANG.-8000 .ANG., and said film thickness is 500 .ANG.-2000 .ANG.. The density of oxygen in the semiconductor film (2') is less than 2.times.10.sup.19 /cm.sup.3. A photo sensor having PIN structure is also produced on the substrate, to provide an image sensor for a facsimile transmitter together with the transistors. Said film (2') is produced by placing amorphous silicon film on the glass substrate through CVD process using disilane gas, and effecting solid phase growth to said amorphous silicon film by heating the substrate together with said film in nitrogen gas atmosphere. The film (2') thus produced is subject to implantation of dopant for providing a transistor.

Abstract: A MOS-FET transistor is produced on a substrate made of glass which has a non single crystal semiconductor film (2'). The average diameter of a crystal grain in said film is in the range between 0.5 times and 4 times of thickness of said film, and said average diameter is 250 .ANG.-8000 .ANG. , and said film thickness is 500 .ANG.-2000 .ANG.. The density of oxygen in the semiconductor film (2') is less than 2.times.10.sup.19 /cm.sup.3. A photo sensor having PIN structure is also produced on the substrate, to provide an image sensor for a facsimile transmitter together with the transistors. Said film (2') is produced by placing amorphous silicon film on the glass substrate through CVD process using disilane gas, and effecting solid phase growth to said amorphous silicon film by heating the substrate together with said film in nitrogen gas atmosphere. The film (2') thus produced is subject to implantation of dopant for providing a transistor.

Abstract: First sensors measure physical quantities correlated with the heat release value of a fire source, and second sensors measure physical quantities correlated with the amount of the product of burning. At least a pair of one first sensor and one second sensor are arranged in a zone to be monitored. A first threshold of high sensitivity and a second threshold of low sensitivity are set at the first sensors. A third threshold is set at the second sensors. A pre-alarm is given only when the level of signals from the second sensors exceeds the third threshold. A fire alarm is given when the level of the signals from the second sensors exceeds the third threshold and when the level of signals from the first sensors exceeds the first threshold. The outputs from a plurality of such sensors detecting different objects, such as heat and smoke, are processed in the manner in which these outputs are combined together to reliably detect fires and to give a fire alarm.

Abstract: A fire discriminating apparatus for determining whether there is the outbreak of fire in an area under surveillance in accordance with the temperature difference between a temperature detection value of the area and a reference temperature.