In an endoscope system, an image processing section on a processor side detects a movement amount or a distance in an image. An endoscopic-procedure-scene classifying section classify, from a feature value, to which of endoscopic procedure scene a scene of an image corresponds and further determines whether reliability of the classified endoscopic procedure scene is low. When the reliability is low, the endoscopic-procedure-scene classifying section decides a target compression ratio from an endoscopic procedure scene classified in the past, and transmits a compression parameter corresponding to the target compression ratio to a wireless endoscope. The wireless endoscope performs wireless transmission of an image compressed with the compression parameter.

A capsule endoscope system includes a capsule endoscope and a wireless communication device. The capsule endoscope includes a first movement sensor, a determiner, an imager, and a first wireless receiver. The wireless communication device includes a second analyzer and a first wireless transmitter. The first analyzer analyzes first data and generates a first analysis result. The second analyzer analyzes second data and generates a second analysis result. The determiner determines an imaging timing at a period that is equal to or shorter than a reception period on the basis of any one of the first analysis result and the second analysis result.

A light source device includes a laser diode configured to emit a laser light used as an illumination light, a determination unit configured to determine one of a plurality of modes as an operation mode of the laser diode based on usage state of the light source device; and a driver configured to drive the laser diode in a condition that a bias current to the laser diode is applied depending on the operation mode determined by the determination unit.

An endoscope apparatus, includes: a memory configured to hold setting information about operations respectively of a first endoscope and a second endoscope; and a processor. The processor is configured to: when detecting switching of the endoscope to be used between the first endoscope and the second endoscope, read the setting information for the endoscope after the switching, and use the setting information for setting for operation of the endoscope after the switching; and when the setting for operation of the endoscope in use is changed, update the setting information for the endoscope in use, and based on the updated setting information for the endoscope in use, update the setting information for the endoscope not in use, and record, in the memory, the updated setting information.

An endoscope includes an insertion portion having a light source portion configured to emit illuminating light therefrom when inserted into a body cavity. An imaging portion is configured to capture an image in the body cavity. A transmission portion configured to transmit the image captured by the imaging portion. A battery is configured to supply electric power needed for endoscopic observation. A power control portion is configured to selectively control a supply of electric power to all of the light source portion, the imaging portion, and the transmission portion in a standby mode in which power consumption is reduced compared with a normal operation mode in which a supply of electric power is performed from the battery to all of the light source portion, the imaging portion, and the transmission portion.

An image display device includes: a plurality of circuits configured to process image signals received from an endoscope, and display an endoscope image on a display; a battery configured to supply electric power to the plurality of circuits; and a processor. The processor switches a control mode in which the electric power is supplied to the plurality of circuits, from a normal mode to any one of a plurality of standby modes in which power consumption is set to be lower than in the normal mode; and the processor switches the control mode, in a case where date and time are out of a preset scheduled use period, to a second standby mode in which the power consumption is set to be lower than in a first standby mode of a case where the date and time are within the scheduled use period.

Provided is a capsule endoscope. The capsule endoscope includes: an imaging device configured to perform imaging on a digestive tract in vivo to generate an image; an artificial neural network configured to determine whether there is a lesion area in the image; and a transmitter configured to transmit the image based on a determination result of the artificial neural network.

An imaging apparatus includes a processor, an imaging device, and a light source. The processor is configured to determine whether or not the imaging device has gone out of space of which at least part is surrounded by an object when the imaging device is performing imaging after the imaging device is inserted into the space. The processor is configured to execute power-saving control when the processor determines that the imaging device has gone out of the space. In the power-saving control, the processor is configured to make power consumption of a control target less than power consumption of the control target before the power-saving control is executed. The control target is at least one of the imaging device and the light source.

An imaging apparatus includes a processor, an imaging device, and a light source. The processor is configured to determine whether or not the imaging device has gone out of space of which at least part is surrounded by an object when the imaging device is performing imaging after the imaging device is inserted into the space. The processor is configured to execute power-saving control when the processor determines that the imaging device has gone out of the space. In the power-saving control, the processor is configured to make power consumption of a control target less than power consumption of the control target before the power-saving control is executed. The control target is at least one of the imaging device and the light source.

A wireless endoscopic camera system includes a surgical endoscope for viewing tissue within a patient, an imager for converting an optical image viewed by the endoscope into digital image data, a processor for processing the digital image data, a transmitter for establishing at least one wireless link to a remote receiver and conveying the processed digital image data over the at least one wireless link, and a plurality of antennas of a camera head that are in communication with the transmitter for receiving the digital image data from the transmitter and wirelessly relaying the digital image data to the remote receiver.