Abstract: In a life detection method of the present invention, a signal transceiver is configured to transmit a transmission signal to an area and receive a reflected signal from the area as a detection signal, a demodulator coupled to the signal transceiver is configured to receive and demodulate the detection signal to output a demodulated signal, a compute element coupled to the demodulator is configured to receive the demodulated signal and compute a RMS value of the demodulated signal, and a determination element coupled to the compute element is configured to receive the RMS value of the demodulated signal and determine whether having a living body within the area according to the RMS value and a RMS threshold value.

Abstract: Provided herein are novel maytansinoid compounds of general formula I. Also provided herein are conjugates comprising the compounds linked to a binding protein via a linker, and conjugating reagents comprising the compounds attached via a linker to at least one functional group capable of reacting with a binding protein. Also provided herein are pharmaceutical compositions comprising the compounds and conjugates, therapeutic methods and uses involving the compounds and conjugates, for example in cancer therapy, and novel synthetic processes.

Abstract: A sensor unit utilized in an autonomous driving vehicle (ADV) includes a unit tray containing a sensor interface, a host interface, and one or more sensor processing modules. The sensor interface can be coupled to a variety of sensors used in the ADV, such as, for example, LIDAR, RADAR, cameras, etc., which may be mounted on different locations of the ADV. The host interface can be coupled a host system that is responsible for autonomously driving the vehicle. The host system is configured to perceive a driving environment surrounding the ADV base on sensor data obtained from the sensors and plan a path to autonomously drive the vehicle through the driving environment. The sensor processing modules are configured to process the sensor data obtained from the sensors.

Abstract: A sensor unit utilized in an autonomous driving vehicle (ADV) includes a unit tray containing a sensor interface, a host interface, and one or more sensor processing modules. The sensor interface can be coupled to a variety of sensors used in the ADV, such as, for example, LIDAR, RADAR, cameras, etc., which may be mounted on different locations of the ADV. The host interface can be coupled a host system that is responsible for autonomously driving the vehicle. The host system is configured to perceive a driving environment surrounding the ADV base on sensor data obtained from the sensors and plan a path to autonomously drive the vehicle through the driving environment. The sensor processing modules are configured to process the sensor data obtained from the sensors.

Abstract: A sensor unit includes a sensor interface and a host interface. The sensor interface can be coupled to a number of sensors mounted on various locations of the ADV. The host interface can be coupled to a host system that is configured to perceive a driving environment surrounding the ADV based on sensor data obtained from the sensors and to plan a path to autonomously drive the ADV. The sensor unit further includes a sensor processing module and a sensor control module coupled to the sensor interface, and a time module coupled to the sensor processing module and the sensor control module. The sensor processing module is configured to process sensor data received from the sensors via the sensor interface. The sensor control module is configured to control operations of the sensors. The time module is configured to generate time to synchronize timing of the operations of the sensors.

Abstract: A signal demodulation device includes an IQ mixer, a differential element and a signal processor. The IQ mixer is configured to output a first mixed signal and a second mixed signal. The differential element is electrically connected to the IQ mixer for receiving the first and second mixed signals and configured to differentiate the first and second mixed signals and output a first derivative signal and a second derivative signal. The signal processor is electrically connected to the differential element for receiving the first and second derivative signals and configured to demodulate the first and second derivative signals and output a first demodulated signal.

Abstract: A method includes receiving a first design for conductive bumps on a first surface of an interposer, the conductive bumps in the first design having a same cross-section area; grouping the conductive bumps in the first design into a first group of conductive bumps in a first region of the first surface and a second group of conductive bumps in a second region of the first surface, where a bump pattern density of the second region is lower than that of the first region; forming a second design by modifying the first design, where modifying the first design includes modifying a cross-section area of the second group of conductive bumps in the second region; and forming the conductive bumps on the first surface of the interposer in accordance with the second design, where after being formed, the first group of conductive bumps and the second group of conductive bumps have different cross-section areas.

Abstract: An active phase switchable array includes a plurality of antenna elements and a bias circuit. Each of the radar elements includes an antenna, a power coupling network and an injection-locked oscillator (ILO), and each of the antenna elements is coupled with each other through the power coupling networks for operating the ILO of each of the antenna elements in self- and mutual-injection-locked states. The antenna elements in self-injection-locked state are utilized to detect the vital signs of subjects, and the antenna elements in mutual-injection-locked state are utilized to produce phase difference between the radiating signals of the antenna elements for forming a beam. As a result, the active phase switchable array can simultaneously detect the vital signs of multiple subjects.

Abstract: The invention provides synthetic intermediates and synthetic processes that are useful for preparing the antibacterial agent TXA709:

Abstract: In a method for detection of vital sign signal, a variation detection module is configured to determine whether there is a living body in an image captured by an image capture module, next, a beam direction of a vital sign sensing system is directed toward the living body to detect vital sign signal of the living body, and a compute module is configured to compute eigenvalue and confidence of the vital sign signal so as to reconfirm whether the determined living body in the image is a living body having vital signs.

Abstract: A method for evaluating a leadframe surface includes positioning a leadframe on a measurement apparatus at a first predetermined distance relative to an end portion of a light source of an optical sensor; irradiating a predetermined area on a surface of the leadframe with light having a single predetermined wavelength from the light source; receiving, with a light receiver of the optical sensor, reflected light from the predetermined area on the surface of the leadframe, and converting the reflected light into an electric signal; determining a reflection intensity value of the predetermined area on the surface of the leadframe based on the electric signal; and calculating a reflection ratio of the predetermined area on the surface of the leadframe based on the reflection intensity value and a predetermined reference reflection intensity value associated with the light source.

Abstract: A vital sign detection system includes a radar device, a nonreciprocal network, a first antenna and a second antenna. An output signal from the radar device is delivered to the first antenna via the nonreciprocal network and then transmitted to a first side of a biological subject via the first antenna. A first reflection signal from the first side of the biological subject is received by the first antenna and then delivered to the second antenna via the nonreciprocal network and then transmitted to a second side of the biological subject via the second antenna. A second reflection signal from the second side of the biological subject is received by the second antenna and then delivered to the radar device via the nonreciprocal network for vital sign detection with random body movement cancellation.

Abstract: In a vital sign sensor of the present invention, an antenna assembly radiates an oscillation signal generated by a SIL oscillator to an object in a form of a wireless signal and receives a reflected signal from the object, and the reflected signal can have the SIL oscillator injection-locked. The wireless signal radiated from the antenna assembly is transmitted to a demodulator for demodulation such that the vital signs of the object can be obtained. Additionally, an isolator of the antenna assembly is provided to prevent the SIL oscillator from receiving a clutter reflected from the demodulator and an environment where the demodulator is placed. As a result, the clutter can't influence the vital sign detection of the object.

Abstract: In non-contact pulse transit time measurement system of the present invention, two continuous-wave radars are provided to detect movements at two positions on a subject for use in measuring pulse transit time. The measurement of the pulse transit time can be continuous and last for a long time because there is no contact to skin necessary.

Abstract: According to some embodiments, before an M.2 compatible module or device is mounted onto a data processing system that operates an autonomous driving vehicle (ADV), the M.2 module is placed onto a tray device to increase the stiffness of the M.2 module. The tray device containing the M.2 module is then mounted on a board or motherboard of the data processing system. Since the M.2 module is placed on the tray device, the overall stiffness has been significantly increased, which can sustain the physical impact on the M.2 module due to the physical movement and oscillation during the autonomous driving of the ADV. In addition, the tray device also provides suspension effect on the M.2 module during the movement of the ADV. As a result, the M.2 module would not easily damaged during the autonomous driving.

Abstract: An integrated circuit package having a shunt resistor with at least one self-aligning member that protrudes from a first surface, and a lead frame with at least one self-aligning feature that is a cavity within which the at least one self-aligning member is located, and an integrated circuit located on the lead frame.

Abstract: A method for evaluating a leadframe surface includes positioning a leadframe on a measurement apparatus at a first predetermined distance relative to an end portion of a light source of an optical sensor; irradiating a predetermined area on a surface of the leadframe with light having a single predetermined wavelength from the light source; receiving, with a light receiver of the optical sensor, reflected light from the predetermined area on the surface of the leadframe, and converting the reflected light into an electric signal; determining a reflection intensity value of the predetermined area on the surface of the leadframe based on the electric signal; and calculating a reflection ratio of the predetermined area on the surface of the leadframe based on the reflection intensity value and a predetermined reference reflection intensity value associated with the light source.

Abstract: A method and apparatus for bonding semiconductor devices are disclosed. In an embodiment, the method may include attaching a first die to a flip head of a flip module, flipping the first die with the flip module, removing the first die from the flip module after flipping the first die, inspecting the flip head of the flip module for contamination after removing the first die, cleaning the flip head with an in situ cleaning module after inspecting the flip head, and attaching a second die to the flip head after cleaning the flip head.

Abstract: Provided herein are novel maytansinoid compounds of general formula I. Also provided herein are conjugates comprising the compounds linked to a binding protein via a linker, and conjugating reagents comprising the compounds attached via a linker to at least one functional group capable of reacting with a binding protein. Also provided herein are pharmaceutical compositions comprising the compounds and conjugates, therapeutic methods and uses involving the compounds and conjugates, for example in cancer therapy, and novel synthetic processes.

Abstract: Aspects of the disclosure relate generally to semiconductor packaging, and specifically to semiconductor device having a lead frame having a semiconductor supporting die pad that is capable of engaging with a wire bonding clamp.