A plurality of sensor portions detect a variety of physical characteristics of objects to be detected, which are being conveyed on a conveyance passage to asynchronously transmit electric signals indicating results of detection to a processing unit. The processing unit causes an A/D converter to A/D-convert the electric signals transmitted from the sensor portions. A mixer adds, to data, an identifier indicating the sensor portion from which data has been transmitted to sequentially output data for each of the sensor portions. A detection-result processing means receives data output from the mixer to identify the sensor portion from which data has been transmitted in accordance with the identifier contained in received data so as to perform a process for detecting the variety of the physical characteristics. The structure and circuit structure of the transmission passage in the detecting apparatus can be simplified.

A cytometer includes an illuminating unit having a laser and a light beam shaping module for shaping and converging the laser beam emitted from the laser. A sample generation unit includes a gas-liquid transmission controlling module and a flow chamber which are connected to each other, so the sample liquid containing the cells to be detected may flow through the flow chamber while being encircled by the sheath fluid. A signal processing unit receives, converts and processes the scattering light emitted from the flow chamber. The signal processing unit includes at least a photoelectric detection module, wherein the light beam shaping module has at least one aspheric collimating lens and a pair of mutually crossing cylindrical lenses, and the numerical aperture of the aspheric collimating lens is at least 0.3.

Light from an object such as a cell moving through an imaging system is collected and dispersed so that it can be imaged onto a detector. The light can be emitted from a luminous object or can be light from a light source that has been scattered or not absorbed by the object or can include a light emission by one or more probes within or on the object. Multiple objects passing through the imaging system can be imaged, producing both scatter images and dispersed images at different locations on one or more detectors. In one embodiment, the detector is divided into a plurality of zones so that each of a plurality of different images are spectrally dispersed onto a different zone of the detector.

Light from an object such as a cell moving through an imaging system is collected and dispersed so that it can be imaged onto a time delay and integration (TDI) detector. The light can be emitted from a luminous object or can be light from a light source that has been scattered by the object or can be a fluorescent emission by one or more FISH probes, frequently used to detect substances within cells. Further, light that is absorbed or reflected by the object can also be used to produce images for determining specific characteristics of the object. The movement of the object matches the rate at which a signal is read from the TDI detector. Multiple objects passing through the imaging system can be imaged, producing both scatter images and spectrally dispersed images at different locations on one or more TDI detectors.

Light from an object such as a cell moving through an imaging system is collected and dispersed so that it can be imaged onto a time delay and integration (TDI) detector. The light can be emitted from a luminous object or can be light from a light source that has been scattered or not absorbed by the object or can include a light emission by one or more probes within or on the object. Multiple objects passing through the imaging system can be imaged, producing both scatter images and dispersed images at different locations on one or more TDI detectors.