Embodiments include methods and systems to remotely and electronically enhance measurement accuracy and speed of electronic brassiere fitting data. A method according to an embodiment can include receiving a set of current user brassiere data from a remote user computing device, receiving a set of physiological images from the remote user computing device, and receiving brassiere fitting data from one or more data sources. The method can further include filtering the brassiere fitting data responsive to the set of current user brassiere data, and generating a first brassiere size responsive to filtering the brassiere fitting data. The method can further include modifying the first brassiere size responsive to the set of physiological images, and generating a recommended brassiere size responsive to modifying the first brassiere size.

A camera head unit including an image sensor configured to generate an image signal, a main unit configured to perform a signal process to the image signal, and first and second cables are included. Further, a determining section configured to determine whether a connection state is in a first connection state in which the camera head unit and the main unit are connected with each other via a first cable without a second cable or a second connection state in which the camera head unit and the main unit are connected with each other via the first cable and the second cable, and a transmission section configured to transmit the image signal between the camera head unit and the main unit at least via the first cable according to a determination result determined by the determining section are included.

Certain embodiments provide an imaging method for a non-line-of-sight object and an electronic device. In certain embodiments, the method includes: detecting a first input operation; and generating first image data in response to the first input operation. The first image data is imaging data of the non-line-of-sight object obtained by fusing second image data and third image data. The first image data includes position information between the non-line-of-sight object and a line-of-sight object. The second image data is imaging data of the line-of-sight object captured by the optical camera. The third image data is imaging data of the non-line-of-sight object captured by the electromagnetic sensor.

Some embodiments include a system, comprising: a plurality of pixels; a plurality of data lines coupled to the pixels; a plurality of switches coupling the pixels to the data lines; a plurality of readout circuits coupled to the data lines; control logic coupled to the readout circuits, the control logic configured to, for one of the pixels: acquire a first value for the pixel while the corresponding switch is in an off state; reset the corresponding readout circuit corresponding for the pixel; acquire a second value for the pixel after resetting the readout circuit; turn on the corresponding switch; acquire a third value for the pixel after turning on the corresponding switch; and combine the first value, the second value, and the third value into a combined value for the pixel.

Disclosed are an auto exposure control system and an image calibration method. The system comprises a main control unit and a plurality of auto exposure units, wherein the main control unit is connected to each of the auto exposure units; and the auto exposure units are in cascading connection. According to the system, detection of each X-ray source is realized by means of auto exposure units, such that an energy accumulation value and a KV level of X-rays are obtained; and when the energy accumulation value of X-rays reaches an energy threshold value, an auto exposure control signal is sent to a main control unit, such that the main control unit adjusts an exposure time sequence according to the auto exposure control signal, the aim of auto exposure control is achieved.

A radiation imaging apparatus includes a detection unit configured to detect radiation emitted from a radiation irradiation unit, the apparatus comprises a processing unit configured to obtain dose distribution information regarding the radiation with which the detection unit is irradiated from the radiation irradiation unit. The processing unit corrects, using the dose distribution information, an image signal output from the detection unit.

A method, medium and system for generating a high-rate video for displaying to a user on a display device. The method, medium and system may generate and display the high-rate video by: capturing images for a video at a first frame rate, capturing movement of a display device via a motion sensor, estimating a motion of the camera based on images of the video captured at the first frame rate and the movement of the display device captured via the motion sensor, generating the high-rate video at a second frame rate by up-sampling the video captured at the first frame rate, and displaying the high-rate video to the user.

Techniques for acquiring an electron energy loss spectrum in two dimensions are disclosed herein. The technique at least includes exposing an electron sensor to an electron spectrum projected in two dimensions, wherein one of the two dimensions corresponds to a dispersive axis, and the other of the two dimensions corresponds to a non-dispersive axis, receiving an electron sensor readout frame from the electron sensor, where the electron sensor readout frame comprises a plurality of values representative of the electron spectrum in each of the two dimensions, and reducing a resolution of the electron sensor readout frame in at least one of the two dimensions, where reducing the resolution includes reducing the number of values in the at least one of the two dimensions, where the electron sensor readout frame comprises a plurality of values in each of the two dimensions after the reduction in resolution.

A radiation imaging apparatus includes a radiation detector configured to detect radiation and convert the detected radiation into an electrical signal relating to a radiation image, a support base having a rectangular shape and supporting the radiation detector, and a housing accommodating the radiation detector and the support base, wherein the support base includes a plurality of protrusions extending from each side of an outer edge in the rectangular shape toward an inner wall of the housing, and wherein, at an end of a first protrusion located at a corner in the rectangular shape among the plurality of protrusions, a distance to the inner wall of the housing is shorter than at an end of a second protrusion located at a position other than the corner.

A radiation imaging apparatus includes a radiation detector configured to detect radiation and convert the detected radiation into an electrical signal relating to a radiation image, a support base having a rectangular shape and supporting the radiation detector, and a housing accommodating the radiation detector and the support base, wherein the support base includes a plurality of protrusions extending from each side of an outer edge in the rectangular shape toward an inner wall of the housing, and wherein, at an end of a first protrusion located at a corner in the rectangular shape among the plurality of protrusions, a distance to the inner wall of the housing is shorter than at an end of a second protrusion located at a position other than the corner.