Abstract: An in-vehicle network system deployed in a vehicle includes a plurality of first nodes configured to perform an operation relevant to a first function in the vehicle, a second node configured to perform an operation relevant to a second function different from the first function in the vehicle; and a relay device configured to relay communication between the first nodes and the second node. The relay device is configured to start relay of communication between the first nodes earlier than the relay of communication between the first node and the second node at a time of startup.

Abstract: Provided is an abnormality detection device for a rotary wing unit. The rotary wing unit includes a plurality of rotary wings that is coaxially disposed. The abnormality detection device includes a controller configured to acquire at least one of a correlation at the time of normal operation between operation parameters related to the rotary wings and a correlation at the time of abnormal operation between the operation parameters and detect abnormality of the rotary wing unit, based on a correlation at the time of actual operation between the operation parameters and at least one of the correlation at the time of normal operation and the correlation at the time of abnormal operation.

Abstract: Provided is an abnormality detection device for a rotary wing unit. The rotary wing unit includes a plurality of rotary wings that is coaxially disposed. The abnormality detection device includes a controller configured to acquire at least one of a correlation at the time of normal operation between operation parameters related to the rotary wings and a correlation at the time of abnormal operation between the operation parameters and detect abnormality of the rotary wing unit, based on a correlation at the time of actual operation between the operation parameters and at least one of the correlation at the time of normal operation and the correlation at the time of abnormal operation.

Abstract: A vapor-permeable waterproof sock includes a cylindrical main body including a cloth having vapor permeability and that is waterproof. The vapor-permeable waterproof sock covers a range from a foot tip portion to a crus portion. The cylindrical main body includes a plurality of cloth areas, each of which expands and contacts more easily in one direction as compared with other directions. The plurality of cloth areas are joined together, and include a crus cloth area expanding and contracting more easily in a circumferential direction of the crus portion as compared with in a longitudinal direction of the crus portion, the crus cloth area covering the crus portion; and a planta portion cloth area expanding and contacting more easily in a longitudinal direction of the planta portion as compared with a width direction of the planta portion.

Abstract: A photosensitive material includes: a polymer matrix, a radical polymerization monomer and photo-radical polymerization initiator, wherein the polymer matrix has stable nitroxy radical at side chain thereof, wherein a molar ratio of the stable nitroxy radical to the radical polymerization monomer is set within a range of 0.03 to 0.25.

Abstract: A recording signal beam and a recording reference beam are irradiated onto a first surface of a holographic recording medium to write an information as an interference pattern therein. Next, a reflective layer is provided on a second surface opposite to the first surface of the holographic recording medium such that the reflective layer is adhered with the second surface, and a reproducing reference beam is irradiated onto the first surface of the holographic recording medium so as to read a signal beam which is reflected at the reflective layer and reproduced from the holographic recording medium.

Abstract: The present invention pertains to a vector wave recording medium which: has an information recording layer comprising a photo-induced birefringence material; irradiates a recording signal light of a first polarization state, and a recording reference light of a second polarization state that differs to the first polarization state; and carries out vector wave multiplex recording by holography on the information recording layer. The vector wave recording medium is configured in such a manner that ?min/?max=0.1 is satisfied, where, assuming irradiation energy for the recording signal light and the recording reference light is constant, the maximum value of the diffraction efficiency of a playback signal light from diffraction gratings corresponding to information recorded in the information recording layer after the vector wave multiplex recording has been carried out by holography on the information recording layer, is regarded as ?max, and the minimum value is regarded as ?min.

Abstract: After performing a pretreatment step of coating an organic solvent mixed with a polymeric organic compound over a substrate having a tungsten film formed on the surface of the substrate, a chemically amplified resist is coated to form a resist pattern. Further, a ratio of a C1s peak intensity to a W4d peak intensity measured by XPS is 0.1 or mote at the surface of the tungsten film after the pretreatment step and before coating the chemically amplified resist.

Abstract: The external base electrode has a two-layered structure where a p-type polysilicon film doped with a medium concentration of boron is laminated on a p-type polysilicon film doped with a high concentration of boron. Therefore, since the p-type polysilicon film doped with a high concentration of boron is in contact with an intrinsic base layer at a junction portion between the external base electrode and the intrinsic base layer, the resistance of the junction portion can be reduced. In addition, since the resistance of the external base electrode becomes a parallel resistance of the two layers of the p-type polysilicon films, the resistance of the p-type polysilicon film whose boron concentration is relatively lower is dominant.

Abstract: A vapor-permeable waterproof sock includes a cylindrical main body including a cloth having vapor permeability and that is waterproof. The vapor-permeable waterproof sock covers a range from a foot tip portion to a crus portion. The cylindrical main body includes a plurality of cloth areas, each of which expands and contacts more easily in one direction as compared with other directions. The plurality of cloth areas are joined together, and include a crus cloth area expanding and contracting more easily in a circumferential direction of the crus portion as compared with in a longitudinal direction of the crus portion, the crus cloth area covering the crus portion; and a planta portion cloth area expanding and contacting more easily in a longitudinal direction of the planta portion as compared with a width direction of the planta portion.

Abstract: A scanner device is provided which enables high-frequency scanning and can increase the speed of a scanning probe microscope. A scanner device (1) used for a scanning probe microscope includes a Z actuator (7) which scans an object to be scanned in a scanning direction, and a Z actuator holder (11) which holds the Z actuator (7). The Z actuator holder (11) holds the Z actuator (7) at a plurality of holding line parts which extend in the scanning direction and are separated from each other. For example, the Z actuator (7) has a rectangular cross-section, and the four edges of the Z actuator (7) are held by the Z actuator holder (11). The Z actuator (7) is pressed into a holding hole (29) of the Z actuator holder (11).

Abstract: Provided is an atomic force microscope capable of increasing the phase detection speed of a cantilever vibration. The cantilever (5) is excited and the cantilever (5) and a sample are relatively scanned. Displacement of the cantilever (5) is detected by a sensor. An oscillator (27) generates an excitation signal of the cantilever (5) and generates a reference wave signal having a frequency based on the excitation signal and a fixed phase. According to vibration of the cantilever (5), a trigger pulse generation circuit (41) generates a trigger pulse signal having a pulse position changing in accordance with the vibration of the cantilever (5). According to the reference wave signal and the trigger pulse signal, a phase signal generation circuit (43) generates a signal corresponding to the level of the reference wave signal at the pulse position as a phase signal of vibration of the cantilever (5). As the reference wave signal, a saw tooth wave is used.

Abstract: There is provided an atomic force microscope (AFM) with increase the speed and sensitivity of detection of the resonant frequency shift in a cantilever. An AFM (1) extracts a reference signal and a phase shift signal from a detection signal from a displacement sensor of the cantilever. The reference signal is restrained from a phase change in accordance with the resonant frequency shift. The phase shift signal has a phase shifted in accordance with the resonant frequency shift. The AFM (1) determines the phase difference of the phase shift signal from the reference signal, as the resonant frequency shift. The AFM (1) may detect the phase difference between a plus-minus inversion point on the reference signal and a corresponding plus-minus inversion point on the phase shift signal. The AFM (1) may adjust phase before phase detection. The phase adjustment may move the detection point for the resonant frequency shift defined on the oscillation waveforms to the plus-minus inversion point.

Abstract: There is provided a scanning probe microscope that allows active damping to be advantageously carried out. A Z scan control section functions as a driving control section to control a Z scanner that is a controlled object. Driving control is performed by supplying the controlled object with a driving signal processed by an adjustment function. The adjustment function adjusts the driving signal by using a simulated transfer function that simulates an actual transfer function indicative of an actual frequency characteristic of the controlled object so that executing processing of the simulated transfer function on the adjusted driving signal results in decrease of vibration of an output signal from the simulated transfer function.

Abstract: A recording signal beam and a recording reference beam are irradiated onto a first surface of a holographic recording medium to write an information as an interference pattern therein. Next, a reflective layer is provided on a second surface opposite to the first surface of the holographic recording medium such that the reflective layer is adhered with the second surface, and a reproducing reference beam is irradiated onto the first surface of the holographic recording medium so as to read a signal beam which is reflected at the reflective layer and reproduced from the holographic recording medium.

Abstract: A driving laser unit (11) irradiates a laser beam on a cantilever (5) to cause thermal expansion deformation. A driving-laser control unit (13) performs feedback control for the cantilever (5) by controlling intensity of the laser beam on the basis of displacement of the cantilever (5) detected by a sensor (9). A thermal-response compensating circuit (35) has a constitution equivalent to an inverse transfer function of a heat transfer function of the cantilever (5) and compensates for a delay in a thermal response of the cantilever (5) to the light irradiation. Moreover, the cantilever (5) may be excited by controlling the intensity of the laser beam. By controlling light intensity, a Q value of a lever resonance system is also controlled. It is possible to increase scanning speed of an atomic force microscope.

Abstract: A scanning probe microscope is provided, which can be stably used for a long time even if excitation efficiency varies during scan. A cantilever (5) is excited, and the cantilever (5) and a sample are subjected to relative scanning. A second-harmonic component detection circuit (31) detects second-harmonic component amplitude of oscillation of the cantilever (5) as integral-multiple component amplitude. The second-harmonic component amplitude is amplitude of a second-harmonic component having a frequency twice as high as excitation frequency. An excitation intensity adjustment circuit (33) controls excitation intensity based on the detected second-harmonic component amplitude such that the second-harmonic component amplitude is kept constant.