Abstract: A charged particle transport system and its installation method, both of which can readily and quickly adjust alignment, are provided. The charged particle transport system 10a includes: a frame 16 fixed to a base 15; a first plate 21 joined to an upper portion of the frame 16 with a height-adjustable first screw 11; a second plate 22 movably accommodated in a horizontal surface of the first plate; a second screw 12 screwed into a screw hole formed in a fixing member 25 around the first plate 21 such that its tip abuts on an outer peripheral surface of the second plate 22; a third screw 13 that fixes the second plate 21 to the first plate 21; and first engagement pins 31 inserted into respective engagement holes 17a, 17b formed in the second plate 22 and a supporting member 27 for engaging both.

Abstract: A laser projection display apparatus includes: a laser light source that generates laser lights of a plurality of colors; a laser light source driving unit that drives the laser light source; a light intensity detector that detects an intensity of the laser light; an overshoot current determining unit that determines a reference overshoot current for improving a rising response of the laser light source; and an overshoot current applying unit that applies an overshoot current to an image signal based on the reference overshoot current. The overshoot current determining unit supplies the overshoot current to the laser light source driving unit while changing the overshoot current, so as to cause the laser light source to emit light, and determines the reference overshoot current such that a light intensity detected when the laser light source emits light becomes a target value.

Abstract: A vibration detection element includes substrates, support members, and an oscillator, and may be used as a biosensor and/or for liquid inspection by analysis of oscillator resonant frequency change. The substrates have a space portion, and the support members protrude from the surfaces of the respective substrates into the space portion. The oscillator is disposed between the support members and is capable of vibrating in the space portion. The support members may each include multiple supports which prevent the oscillator from contacting the substrate surfaces. During manufacturing the oscillator may be transferred from the support member of a glass flow path substrate to a silicon flow path substrate by placement of the silicon substrate support member against the oscillator and subsequent removal of the adhesive from the glass substrate support member.

Abstract: A charged particle transport system and its installation method, both of which can readily and quickly adjust alignment, are provided. The charged particle transport system 10a includes: a frame 16 fixed to a base 15; a first plate 21 joined to an upper portion of the frame 16 with a height-adjustable first screw 11; a second plate 22 movably accommodated in a horizontal surface of the first plate; a second screw 12 screwed into a screw hole formed in a fixing member 25 around the first plate 21 such that its tip abuts on an outer peripheral surface of the second plate 22; a third screw 13 that fixes the second plate 21 to the first plate 21; and first engagement pins 31 inserted into respective engagement holes 17a, 17b formed in the second plate 22 and a supporting member 27 for engaging both.

Abstract: A vibration detection element (10) includes substrates (1 to 3), a support member (22), a support member (32), and an oscillator (4). The substrates (1 to 3) have a space portion (SP) having a bottom surface (21A) and a bottom surface (31A) opposed to the bottom surface (21A). The support member (22) protrudes from the bottom surface (21A) toward the bottom surface (31A) of the space portion (SP). The support member (32) protrudes from the bottom surface (31A) toward the bottom surface (21A) of the space portion. The oscillator (4) is disposed in contact with the support member (22) or the support member (32) and capable of vibrating in the space portion (SP) and has a thickness less than 10 ?m. The support members (22, 32) each include multiple supports which prevent the oscillator (4) from contacting the bottom surface (21A) or the bottom surface (31A).

Abstract: A rotary irradiation apparatus of an embodiment comprises: a rotating gantry; a superconducting electromagnet being installed in the rotating gantry and forming at least one of a deflecting magnetic field that deflects a trajectory of a charged particle beam and a convergent magnetic field that converges the charged particle beam to guide the charged particle beam to an object to be irradiated; a rotating gantry drive unit that drives/rotates the rotating gantry; and a control device that controls the rotating gantry drive unit to rotate and stop the rotating gantry, while the superconducting electromagnet is being excited and the charged particle beam is not irradiated.

Abstract: A rotary irradiation apparatus of an embodiment comprises: a rotating gantry; a superconducting electromagnet being installed in the rotating gantry and forming at least one of a deflecting magnetic field that deflects a trajectory of a charged particle beam and a convergent magnetic field that converges the charged particle beam to guide the charged particle beam to an object to be irradiated; a rotating gantry drive unit that drives/rotates the rotating gantry; and a control device that controls the rotating gantry drive unit to rotate and stop the rotating gantry, while the superconducting electromagnet is being excited and the charged particle beam is not irradiated.

Abstract: A wafer processing device is a device for handling a framed wafer including a frame, a film stretched inside the frame, and a wafer attached on the film, to perform a plasma processing on the wafer. The device includes: a wafer stage on which the wafer is to be placed via the film; a plurality of vertically movable frame-lifting pins arranged around the wafer stage, for supporting the frame; and a frame-lifting-pin drive controller for lowering the individual frame-lifting pins with different timings. With this device, the film with the attached wafer can be neatly placed on the wafer stage (i.e. with no wrinkle in the film as well as no bubble between the film and the wafer stage).

Abstract: The laser projection display device includes: a photo-sensor for detecting the quantity of laser light generated by the laser light source; and an image processing unit for processing a drive signal on the basis of the quantity of light of the detected laser light and supplying the processed drive signal to a driving unit for the laser light source. Right after the dimming, the image processing unit supplies the drive signal to the driving unit for the laser light source on the basis of the quantity of light of the detected laser light within a second execution cycle shorter than a first execution cycle which is the execution cycle used during the normal operation.

Abstract: The laser projection display device includes: a photo-sensor for detecting the quantity of laser light generated by the laser light source; and an image processing unit for processing a drive signal on the basis of the quantity of light of the detected laser light and supplying the processed drive signal to a driving unit for the laser light source. Right after the dimming, the image processing unit supplies the drive signal to the driving unit for the laser light source on the basis of the quantity of light of the detected laser light within a second execution cycle shorter than a first execution cycle which is the execution cycle used during the normal operation.

Abstract: A laser projection display device includes: a laser light source drive unit; an attribute amount detection unit for detecting the attribute amount of a picture signal; a light sensor for measuring the light amounts of the laser light sources; and a temperature sensor for measuring the temperatures of the laser light sources. The laser projection display device is configured so that the current vs. light amount output characteristics of the laser light sources with a threshold current and current gain as a parameter are corrected in accordance with the load amount of the picture signal per frame if the change of the attribute amount exceeds a predefined amount; the light sources are driven at a predefined timing of the vertical blanking interval; controls the threshold currents and current gains in accordance with the light amounts; and the threshold currents and current gains are corrected on the basis of the measured temperatures.

Abstract: A laser projection display device includes: a laser light source drive unit; an attribute amount detection unit for detecting the attribute amount of a picture signal; a light sensor for measuring the light amounts of the laser light sources; and a temperature sensor for measuring the temperatures of the laser light sources. The laser projection display device is configured so that the current vs. light amount output characteristics of the laser light sources with a threshold current and current gain as a parameter are corrected in accordance with the load amount of the picture signal per frame if the change of the attribute amount exceeds a predefined amount; the light sources are driven at a predefined timing of the vertical blanking interval; controls the threshold currents and current gains in accordance with the light amounts; and the threshold currents and current gains are corrected on the basis of the measured temperatures.

Abstract: An image transmission device compresses and transmits image data to be sent and cannot correct errors occurring on the transmission path when image data to be transmitted is larger than a currently prescribed image size. In an image receiving device which receives compressed image data, data to be inputted is inputted by switching between first periods, during which the amount of data transmitted per prescribed time interval is a first data transmission amount, and second periods, during which the amount of data transmitted per prescribed time interval is less than the first data transmission amount. Compressed image data is inputted during the first periods, and error correction codes are inputted during the second periods, and a control unit expands the output of an error detection unit by means of an expansion unit and outputs the same.

Abstract: A recording/reproducing apparatus, for enabling recording/reproducing of a three-dimensional (3D) video stream, by taking a display environment into the consideration thereof, comprises: a stream distinguishing means for distinguishing the three-dimensional (3D) video stream; a 3D/2D stream converting for converting the three-dimensional (3D) video stream distinguished by the stream distinguishing means into a two-dimensional (2D) video stream; and a conversion indicating means for indicating to execute the 3D/2D conversion, wherein the three-dimensional (3D) video stream is converted into the two-dimensional (2D) video stream by the 3D/2D stream means, when the 3D/2D conversion is indicted in the conversion indicating means.

Abstract: A method is disclosed wherein a first piece of digital information and copy control information of the first piece of digital information is received. The copy control information is for controlling the recording of the first piece of digital information on a recording medium. When the received copy control information is Copy One Generation indicating that only one generation copy of digital information is allowed, then a plurality of the first pieces of digital information are recorded on a first recording medium as the first piece of digital information and a second piece of digital information, wherein the first piece of digital information is different in format or in bit rate from the second piece of digital information.

Abstract: A method is disclosed wherein a first piece of digital information and copy control information of the first piece of digital information is received. The copy control information is for controlling the recording of the first piece of digital information on a recording medium. When the received copy control information is Copy One Generation indicating that only one generation copy of digital information is allowed, then a plurality of the first pieces of digital information are recorded on a first recording medium as the first piece of digital information and a second piece of digital information, wherein the first piece of digital information is different in format or in bit rate from the second piece of digital information.

Abstract: An image processing apparatus is configured to have units for compressing and expanding image data and an arbitrating unit for arbitrating control units for executing image processing so that the compressing and expanding units are located between the arbitrating unit and the control units respectively. The apparatus further includes the circuits for compressing and expanding the image data in a reversible manner and a nonreversible manner so that the compressing and expanding manner may be switched according to the image processing condition. When treating a large amount of image data, this configuration makes it possible to reduce the number of accesses to memory and make effective use of a bandwidth, thereby being able to reduce the power consumption. Since the bandwidth is reduced and the random access to memory is made possible, more image processing capabilities may be provided so that the operability of this apparatus is enhanced.

Abstract: An information recording/reproducing apparatus capable of simplifying settings of a scene breakpoint includes a voice recognition unit and a control unit. At a timing when the voice recognition unit extracts a feature during recording, the control units sets a scene breakpoint and generates a thumbnail at the same time. During reproduction, the thumbnail and voices when the feature was extracted are output at the same time.

Abstract: A recording and reproducing apparatus capable of recording and reproducing the signals of both a digital broadcast system and an analog broadcast system is disclosed. By utilizing the existing configuration efficiently, the cost increase due to the system change is minimized. Both the digital broadcast system and the analog broadcast system are connected to a connector to receive both digital and analog broadcast signals. The analog broadcast signal input through the connector is recorded in a digital broadcast signal recording unit of the digital broadcast system under the control of the control unit included in the digital broadcast system.

Abstract: In increasing multi-channel broadcast situations, user friendliness is insufficient in that digest information can not be generated to satisfy users' demands to record two contents which are broadcast at the same time. In a reproduction apparatus which simultaneously records a plurality of digital video signals and creates a digest of each of the signals to shorten the reproduction time, particular frames of input digital video signals are recorded on a recording medium as reproduction position information. A first decoder decodes the digital video signals as a whole, and a second decoder decodes only digital video signals associated with the reproduction position information. The output of the second decoder is used as a digest generation signal of a digest generation module.