Abstract: A method performed by a user equipment for a beam operation is provided. The method includes: receiving an RRC configuration for configuring a set of joint TCI states; receiving, from the BS, a MAC CE for activating a subset of joint TCI states in the set of joint TCI states, the MAC CE is used to map the subset of joint TCI states to codepoints of a TCI field in DCI; receiving the DCI indicating a joint TCI state included in the subset of joint TCI states activated by the MAC CE; determining whether the DCI includes a DL assignment; transmitting, in response to reception of the DCI, first HARQ-ACK information in a case that the DCI does not include the DL assignment; and transmitting, in response to the reception of the DCI and reception of a PDSCH, second HARQ-ACK information in a case that the DCI includes the DL assignment.

Abstract: A probe pin alignment apparatus includes a beam-splitting element, an image-sensing device and a light-reflecting element. The beam-splitting element has a first illuminating surface facing a probe element, a second illuminating surface facing an object, and a light incident surface. The beam-splitting element has a semi-reflective surface for reflecting a light beam from the light incident surface to the probe element. The image-sensing device is disposed externally to the light incident surface of the beam-splitting element. The light-reflecting element, disposed oppositely to the light incident surface, allows a light beam to pass through the semi-reflective surface to be reflected back to the semi-reflective surface to be further projected onto the object. The beam-splitting element outputs a probe image and an object image from the first and second illuminating surfaces through the light incident surface.

Abstract: A probe pin alignment apparatus includes a beam-splitting element, an image-sensing device and a light-reflecting element. The beam-splitting element has a first illuminating surface facing a probe element, a second illuminating surface facing an object, and a light incident surface. The beam-splitting element has a semi-reflective surface for reflecting a light beam from the light incident surface to the probe element. The image-sensing device is disposed externally to the light incident surface of the beam-splitting element. The light-reflecting element, disposed oppositely to the light incident surface, allows a light beam to pass through the semi-reflective surface to be reflected back to the semi-reflective surface to be further projected onto the object. The beam-splitting element outputs a probe image and an object image from the first and second illuminating surfaces through the light incident surface.

Abstract: An acoustic camera comprises a first sound pick-up device, a second sound pick-up device, and a switch. The switch is respectively connected to the first sound pick-up device and the second pick-up device and used to select the first sound pick-up device or the second sound pick-up device to reconstruct the sound field of the sound source of a detected object. The first sound pick-up device has a first microphone array, and the first microphone array is a near-field uniform microphone array. The second sound pick-up device has a second microphone array, and the second microphone array is a far-field non-uniform microphone array.

Abstract: An acoustic camera comprises a first sound pick-up device, a second sound pick-up device, and a switch. The switch is respectively connected to the first sound pick-up device and the second pick-up device and used to select the first sound pick-up device or the second sound pick-up device to reconstruct the sound field of the sound source of a detected object. The first sound pick-up device has a first microphone array, and the first microphone array is a near-field uniform microphone array. The second sound pick-up device has a second microphone array, and the second microphone array is a far-field non-uniform microphone array.

Abstract: The present invention relates to a fuel cell system and a method for operating the same. The method of the present invention includes: igniting a fuel by an ignition element to generate flames to allow the fuel to carry out an exothermic combustion reaction in a burner, and introducing a reforming reaction material into an evaporator to vaporize the reforming reaction material; transmitting heat generated from the exothermic combustion reaction to a reactor, and introducing the vaporized reforming reaction material into the reactor to perform a reforming reaction and generate hydrogen gas; and introducing the hydrogen gas into a fuel cell stack member to generate electricity. Accordingly, the fuel cell system and the method for operating the same provided by the present invention can reduce start-up time and avoid the additional consumption of electricity.

Abstract: This present invention provides the preparation of a manganese oxide-ferric oxide-supported nano-gold catalyst and a process for subjecting carbon monoxide and oxygen to interaction resulting in the formation of carbon dioxide in a hydrogen-rich environment by a manganese oxide-ferric oxide-supported nano-gold catalyst to remove carbon monoxide in hydrogen stream. The size of the nano-gold particle is less than 5 nm and supported on mixed oxides MnO2/Fe2O3 in various molar ratios. Preferential oxidation of CO in the presence of CO, O2 and H2 by the manganese oxide-ferric oxide-supported nano-gold catalyst is carried out in a fixed-bed reactor in the process of the present invention. The O2/CO molar ratio is in the range of 0.5 to 4. The manganese oxide-ferric oxide-supported nano-gold catalyst of the present invention is applied to reduce CO concentration in hydrogen steam to less than 100 ppm to prevent CO from contaminating the electrodes of a fuel cell.

Abstract: This present invention provides the preparation of a manganese oxide-cerium oxide-supported nano-gold catalyst and a process for subjecting carbon monoxide and oxygen to interaction resulting in the formation of carbon dioxide in a hydrogen-rich environment by a manganese oxide-cerium oxide-supported nano-gold catalyst to remove carbon monoxide in hydrogen stream. The size of the nano-gold particle is less than 5 nm and supported on mixed oxides MnO2/CeO2 in various molar ratios. Preferential oxidation of CO in the presence of CO, O2 and H2 by the manganese oxide-cerium oxide-supported nano-gold catalyst is carried out in a fixed-bed reactor in the process of the present invention. The CO/O2 molar ratio is in the range of 0.5 to 3. The manganese oxide-cerium oxide-supported nano-gold catalyst of the present invention is applied to reduce CO concentration in hydrogen steam to less than 100 ppm to prevent CO from contaminating the electrodes of a fuel cell.

Abstract: The present invention discloses a system for visualizing sound source energy distribution and a method thereof, wherein a propagation matrix and a window matrix are obtained firstly; next, an inverse operation of the propagation matrix is performed; next, a multiplication operation of the result of the inverse operation and the window matrix is performed; next, the result of the multiplication operation is transformed from the time domain to the frequency domain; thus, a sound source energy distribution reconstructor is established; then, an array of microphones is used to receive the sound source signals; next, a multi-channel capture device transforms the received sound source signals into digital sound source signals; lastly, a convolution operation is performed on the digital sound source signals and the sound source energy distribution reconstructor to obtain a visualized sound source energy distribution.