Abstract: A barristor-based photodetector is disclosed. The photodetector according to an embodiment comprises: a substrate; a gate electrode which is laminated on the substrate; a first electrode and a second electrode which are laminated on the substrate and spaced apart from the gate electrode; a graphene layer which is formed between the substrate and the second electrode and extends toward the first electrode; and a gate insulating layer which is formed between the gate electrode and the graphene layer.

Abstract: A barristor-based photodetector is disclosed. The photodetector according to an embodiment comprises: a substrate; a gate electrode which is laminated on the substrate; a first electrode and a second electrode which are laminated on the substrate and spaced apart from the gate electrode; a graphene layer which is formed between the substrate and the second electrode and extends toward the first electrode; and a gate insulating layer which is formed between the gate electrode and the graphene layer.

Abstract: Disclosed are a two-dimensional semiconductor in which an energy band gap changes with thickness, a manufacturing method therefor, and a semiconductor device comprising the same. A two-dimensional semiconductor according to an embodiment comprises: a first layer having a first thickness; and a second layer having a second thickness, wherein the first thickness and the second thickness are different from each other, the first layer forms a first junction with a first electrode, and the second layer forms a second junction with a second electrode.

Abstract: A vehicle radar detection angle adjustment system and angularly adjustable radar thereof are provided. The system comprises a transmission unit, a processing unit, and a receiving unit. The transmission unit generates a radar beam according to an operation frequency. The processing unit, by the adjustment of the operation frequency, changes a dip angle of the transmission of the radar beam from the transmission unit, and generates a feedback signal after receiving the radar beam through the receiving unit. The processing unit is electrically connected with the receiving unit for receiving the feedback signal, so as to compare the beam frequency of the received feedback signal, and select an operation frequency corresponding to the radar beam having the predetermined energy. Therefore, the radar beam is launched at an optimal angle.

Abstract: A radar system with angle error determination function and method thereof are provided. The system includes a camera device, a radar device, a calculation module, and an angle calibration module. The camera device captures a surveillance image of a surveillance area. The radar device sends a radar signal toward the surveillance area. The calculation module, according to the surveillance image, acquires an image angle of an object with respect to the vehicle in the surveillance area. Also, the calculation module acquires a radar angle of the object with respect to the vehicle which is produced according to a reflection signal generated when the radar signal meets the object. The angle calibration module, by referring to the image angle, correspondingly calibrates the radar angle. Therefore, the radar angle is immediately calibrated.

Abstract: A vehicle speed radar system and detection method are provided. The radar system is disposed on a vehicle for determining the speed status of a target vehicle. The radar system includes a transmitting unit, a receiving unit, a self speed detection unit, a signal processing unit, and a rational speed determination unit. The transmitting unit sends out a wave source which is reflected by the target vehicle and received by the receiving unit, and a frequency value is acquired. The self speed detection unit acquired a first absolute speed. The signal processing unit acquires a relative speed, and acquires possible second absolute speeds of the target vehicle according to the first absolute speed and the relative speed. The rational speed determination unit determines the rational second absolute speed, so as to resolve the irrational determination of the speed status of the vehicle.

Abstract: A symmetric leaky wave antenna includes a dielectric substrate, an electric wall, and two reflection bore arrays. The dielectric substrate has a first and a second metal layers disposed on two opposite faces thereof. The first metal layer has a feed end and two travelling wave sides. The electric wall is disposed between two travelling wave sides, with the two travelling wave sides symmetrically disposed with respect to the electric wall. The two reflection bore arrays are symmetrically disposed along the two travelling wave sides, respectively, with the electric wall arranged at a central line between the two reflection bore arrays. The two reflection bore arrays pass through the first metal layer, the second metal layer, and the dielectric substrate. The reflection bore array and the electric wall reduce the leakage rate of the electromagnetic wave, thus increasing the gain value of the antenna.

Abstract: An in-vehicle radar detection system includes a first radar module and a second radar module separately mounted on a lateral of a vehicle. The first radar module gives a first radar signal that defines a first detection range. The second radar module gives a second radar signal that defines a second detection range. The first radar module and the second radar module give a first radar signal and a second radar signal toward each other, respectively, so that the first detection range and the second detection range fully cover the lateral of the vehicle, thereby providing full detection without any dead spaces.

Abstract: A dual-notch antenna includes a radiation member and two microstrip lines. The radiation member is formed in a rectangular shape, with two first lateral sides disposed in opposite, and two second lateral sides disposed on two ends of the two first sides, respectively. The middle section of each first lateral side is concavely provided with a notch. Each notch has a feeding side and two cove sides, wherein the feeding side is disposed in parallel to the first lateral sides. The two cove sides are connected with two ends of the feeding side. Each microstrip line has one end thereof electrically connected with the feeding side of the corresponding notch, respectively.

Abstract: A symmetric leaky wave antenna includes a dielectric substrate, an electric wall, and two reflection bore arrays. The dielectric substrate has a first and a second metal layers disposed on two opposite faces thereof. The first metal layer has a feed end and two travelling wave sides. The electric wall is disposed between two travelling wave sides, with the two travelling wave sides symmetrically disposed with respect to the electric wall. The two reflection bore arrays are symmetrically disposed along the two travelling wave sides, respectively, with the electric wall arranged at a central line between the two reflection bore arrays. The two reflection bore arrays pass through the first metal layer, the second metal layer, and the dielectric substrate. The reflection bore array and the electric wall reduce the leakage rate of the electromagnetic wave, thus increasing the gain value of the antenna.

Abstract: Disclosed are a two-dimensional semiconductor in which an energy band gap changes with thickness, a manufacturing method therefor, and a semiconductor device comprising the same. A two-dimensional semiconductor according to an embodiment comprises: a first layer having a first thickness; and a second layer having a second thickness, wherein the first thickness and the second thickness are different from each other, the first layer forms a first junction with a first electrode, and the second layer forms a second junction with a second electrode.

Abstract: A school bus radar system includes a main unit mounted in the school bus, and two radars protrudingly arranged on the bus body of the school bus in a tilted manner and respectively electrically connected to the main unit. When the main unit is switched to a monitoring mode, the main unit generates a radar activation signal to activate the radars in generating a signal, making the signals generated by the monitoring sources of the radars form an intersection network. The monitoring source of each radar defines a normal line. Accordingly, the intersection type three-dimensional spatial monitoring network of the radar system of the present invention is proposed for individual warnings to facilitate the driver making good judgments or stopping the running school bus in an emergency.

Abstract: A dual slot SIW antenna unit includes a first substrate, a conductive layer, plural unit radiation members, a second substrate, a ground conductive layer, and two first conductor pillars. The plural unit radiation members are disposed in parallel on the conductive layer, and each unit radiation member includes at least a pair of slots that are disposed in parallel. The two first conductive pillars are disposed between two neighboring unit radiation members and electrically connect the feed routing layer and the conductive layer. A dual slot SIW antenna array module is also disclosed. By use of the dual slot structure, more radiation members are allowed to be included in a limited square measure for improving the antenna gain.

Abstract: Targeting-enhanced anticancer nanoparticles and preparation methods for the nanoparticles are provided. In particular, this invention provides targeting-enhanced anticancer nanoparticles comprising non-covalently bound anticancer drugs, serum albumins as the nanoparticle base material, and porphyrin compounds as tumor-targeting moieties. The targeting-enhanced anticancer nanoparticles described in the present invention are characterized by non-covalently bound constituents: anticancer drugs, serum albumin as the nanoparticle base material, and porphyrin compounds as tumor-targeting moieties, thus preventing common toxic side effects, enhancing the structural stability of nanoparticles, and enhancing tumor targeting by treatment with electromagnetic waves due to the activity of porphyrin, without structural and functional changes.

Abstract: A dual-notch antenna includes a radiation member and two microstrip lines. The radiation member is formed in a rectangular shape, with two first lateral sides disposed in opposite, and two second lateral sides disposed on two ends of the two first sides, respectively. The middle section of each first lateral side is concavely provided with a notch. Each notch has a feeding side and two cove sides, wherein the feeding side is disposed in parallel to the first lateral sides. The two cove sides are connected with two ends of the feeding side. Each microstrip line has one end thereof electrically connected with the feeding side of the corresponding notch, respectively.

Abstract: A method for measuring a permittivity (?) of a material (30) includes following steps. A sensing rod (14) of a material level sensor (10) inserts into a tank (20). The material level sensor (10) proceeds with a material level measurement of the material (30) to obtain a first feature value. The material level sensor (10) is vertically moved with a vertical distance (Hair). The material level sensor (10) proceeds with the material level measurement to obtain a second feature value, and subtracts the first feature value by the second feature value to obtain a feature value variation, and calculates the feature value variation to obtain the permittivity (?) of the material (30).

Abstract: An integrated millimeter-wave chip package structure including an interposer structure, a millimeter-wave chip and a substrate is provided. The interposer structure includes at least an antenna pattern and at least a plated through-hole structure penetrating through the interposer structure and connected to the at least one antenna pattern. The millimeter-wave chip is electrically connected to the at least antenna pattern located either above or below the millimeter-wave chip through the at least plated through-hole structure.

Abstract: A series fed microstrip antenna structure includes a substrate, a patterned conductive layer disposed on the upper surface of the substrate, and a grounding layer disposed on the lower surface of the substrate. The patterned conductive layer includes a conductive wire and a plurality of radiator units, wherein each radiator unit is connected with the conductive wire by a feed line. A matched radiator unit disposed on the substrate and electrically connected with the conductive wire. With such configuration, the structure is simple and facilitates the massive production. Also, the antenna bandwidth is increased, and the antenna gain is improved.

Abstract: An inset type feed antenna structure is disclosed includes a substrate, a patterned conductive layer disposed on an upper surface of the substrate, and a grounding layer disposed on a lower surface of the substrate. The patterned conductive layer includes a conductive line and a plurality of radiation units, wherein each radiation units includes a conductive patch provided with a notch on one side thereof, and a feeding line electrically connecting the conductive line and the notch, wherein the feeding line is a quarter-wave feeding line. The present invention not only decreases the distance between the radiation units and the conductive line to control the vertical side lobes, but also increases the impedance of each radiation unit, so that more radiation units can be fed in.

Abstract: A radar device for vehicles includes a waveform generator, generating an FMCW; a transmit antenna, transmitting the FMCW; a first receive antenna, receiving a first reflected wave of the FMCW; a first mixer, receiving the FMCW and the first reflected wave to produce a first mixed signal; a second receive antenna, receiving a second reflected wave of the FMCW; a second mixer, receiving the FMCW and the second reflected wave to produce a second mixed signal; and a digital signal processor, receiving and processing the first mixed signal and the second mixed signal to produce a diversity receive signal. By use of a multipath reflection compensation, the instability issue of the signal from a remote target object is resolved.