Abstract: A method includes attaching a package component to a package substrate, the package component includes: an interposer disposed over the package substrate; a first die disposed along the interposer; and a second die disposed along the interposer, the second die being laterally adjacent the first die; attaching a first thermal interface material to the first die, the first thermal interface material being composed of a first material; attaching a second thermal interface material to the second die, the second thermal interface material being composed of a second material different from the first material; and attaching a lid assembly to the package substrate, the lid assembly being further attached to the first thermal interface material and the second thermal interface material.

Abstract: The present invention provides a transmitter including a mixer, a harmonic impedance adjustment circuit and an amplifier. The mixer is configured to mix a first baseband signal with a first oscillation signal to generate a first mixed signal to a first node, and to mix a second baseband signal with a second oscillation signal to generate a second mixed signal to a second node. The harmonic impedance adjustment circuit is coupled between the first node and the second node, and is configured to reduce harmonic components of the first mixed signal and the second mixed signal to generate an adjusted first mixed signal and an adjusted second mixed signal. The amplifier is coupled to the harmonic impedance adjustment circuit, and is configured to generate an amplified signal according to the adjusted first mixed signal and the adjusted second mixed signal.

Abstract: A data processing system digitally processes data feeds of inhaler device operation. The data feed represents operation of an inhaler device. The system indexes the live data feed with a key value representing the inhaler device for which the live data feed is obtained. For a particular key value indexed in the in-memory data storage, the system queries, a data feed representing physical operation of an inhaler device, segments the live data feed for that particular key value into a plurality of data samples, process at least a portion of the data samples to classify each of the processed data samples; outputs a prompt specifying whether operation of the inhaler device is within a threshold range of operation. Audio data, temperature data, image data, and ranging data can be processed to classify operation of the inhaler device and the order of operations of the inhaler device.

Abstract: A data processing system digitally processes data feeds of inhaler device operation. The data feed represents operation of an inhaler device. The system indexes the live data feed with a key value representing the inhaler device for which the live data feed is obtained. For a particular key value indexed in the in-memory data storage, the system queries, a data feed representing physical operation of an inhaler device, segments the live data feed for that particular key value into a plurality of data samples, process at least a portion of the data samples to classify each of the processed data samples; outputs a prompt specifying whether operation of the inhaler device is within a threshold range of operation. Audio data, temperature data, image data, and ranging data can be processed to classify operation of the inhaler device and the order of operations of the inhaler device.

Abstract: A method of measuring an azimuth of a target by a scanning radar includes (a) establishing a radar scanning model, including (a1) selecting an antenna pattern, (a2) setting a set of radar parameters, (a3) creating reflected signals simulation curve, (a4) sampling the reflected signals simulation curve to create a plurality of sets of simulation data, each set is consisted of successive samples, and (a5) normalizing each sample of each set of simulation data to create a plurality sets of records of normalized simulation data; (b) obtaining normalized scanning data; (c) comparing records of normalized simulation data with the normalized scanning data; and (d) obtaining an azimuth of the target.

Abstract: The disclosure relates to a fluorescence detection instrument, including a base, a heating module, a detecting module, an illumination module, and an actuation module. The heating module, the detecting module, and the actuation module are disposed on the base. The heating module includes plural heating holders, wherein each of the plural heating holders is adapted to accommodate a light-transmissive reaction container adapted to contain a fluorescent reaction mixture with at least one targeted fluorescent probe respectively. The detecting module is configured with the heating module to form plural detection channels, wherein the plural heating holders are located at the plural detection channels respectively. The actuation module is connected with the illumination module and adapted to drive the illumination module to move to at least one predetermined position to selectively match at least one combination of the heating holder on the corresponding detection channel.

Abstract: A method of measuring an azimuth of a target by a scanning radar includes (a) establishing a radar scanning model, including (a1) selecting an antenna pattern, (a2) setting a set of radar parameters, (a3) creating reflected signals simulation curve, (a4) sampling the reflected signals simulation curve to create a plurality of sets of simulation data, each set is consisted of successive samples, and (a5) normalizing each sample of each set of simulation data to create a plurality sets of records of normalized simulation data; (b) obtaining normalized scanning data; (c) comparing records of normalized simulation data with the normalized scanning data; and (d) obtaining an azimuth of the target.

Abstract: The disclosure relates to a fluorescence detection instrument, including a base, a heating module, a detecting module, an illumination module, and an actuation module. The heating module, the detecting module, and the actuation module are disposed on the base. The heating module includes plural heating holders, wherein each of the plural heating holders is adapted to accommodate a light-transmissive reaction container adapted to contain a fluorescent reaction mixture with at least one targeted fluorescent probe respectively. The detecting module is configured with the heating module to form plural detection channels, wherein the plural heating holders are located at the plural detection channels respectively. The actuation module is connected with the illumination module and adapted to drive the illumination module to move to at least one predetermined position to selectively match at least one combination of the heating holder on the corresponding detection channel.

Abstract: An ampoule opener has an opening unit and a cover unit. The opening unit is a rigid frame and has two panels, two head-clamping holes and two pairs of wave-shaped flanges. The panels are respectively an upper panel and a lower panel. The head-clamping holes are elongated in length and tapered in width and are respectively formed through the panels. The pairs of wave-shaped flanges are formed between the panels and the head-clamping holes. The cover unit is flexible, is detachably mounted around the opening unit and has two covering boards, a mounting recess, two body-clamping holes and two pairs of wave-shaped edges. The body-clamping holes are elongated in length and tapered in width and are respectively formed through the mounting boards and communicate with the mounting recess. The pairs of wave-shaped edges are formed between the mounting boards and the body-clamping holes.

Abstract: A semiconductor package structure includes a package substrate, at least a chip, solder balls, a light emitting/receiving device, a optical intermediary device and an optical transmission device. The package substrate has a first surface, a second surface, a circuit and solder ball pads, wherein each solder ball pad is electrically connected to the circuit. The chip is disposed on the first surface and electrically connected to the circuit. The solder balls are respectively disposed on the solder ball pads. The light emitting/receiving device is disposed on the package substrate and electrically connected to the circuit. The optical intermediary device is disposed above the light emitting/receiving device. The optical transmission device is inserted in the optical intermediary device, wherein a light emitting by the light emitting/receiving device is emitted to the optical transmission device via the optical intermediary device so that an optical signal is transmitted through the optical transmission device.

Abstract: A high speed input/output (HSIO) system and a power saving control method for the HSIO system are provided. The HSIO system has a plurality of transmission speed modes. When an external device is connected to the HSIO system and an auto-configuration link is completed, the power saving control method forcibly sets an interface controller to any desired transmission speed specification in accordance with an actual transmission speed of to-be-transmitted data. Therefore, transmission speed mode of a single physical layer can be changed to achieve a low power transmission.

Abstract: A semiconductor package structure includes a package substrate, at least a chip, solder balls, a light emitting/receiving device, a optical intermediary device and an optical transmission device. The package substrate has a first surface, a second surface, a circuit and solder ball pads, wherein each solder ball pad is electrically connected to the circuit. The chip is disposed on the first surface and electrically connected to the circuit. The solder balls are respectively disposed on the solder ball pads. The light emitting/receiving device is disposed on the package substrate and electrically connected to the circuit. The optical intermediary device is disposed above the light emitting/receiving device. The optical transmission device is inserted in the optical intermediary device, wherein a light emitting by the light emitting/receiving device is emitted to the optical transmission device via the optical intermediary device so that an optical signal is transmitted through the optical transmission device.

Abstract: A high speed input/output (HSIO) system and a power saving control method for the HSIO system are provided. The HSIO system has a plurality of transmission speed modes. When an external device is connected to the HSIO system and an auto-configuration link is completed, the power saving control method forcibly sets an interface controller to any desired transmission speed specification in accordance with an actual transmission speed of to-be-transmitted data. Therefore, transmission speed mode of a single physical layer can be changed to achieve a low power transmission.