Provided are an automatic analysis device and a maintenance support system which prevent a failure that occurs between regular inspection periods to thereby reduce the downtime of the automatic analysis device. A maintenance support system acquires, from each of a plurality of automatic analysis devices (100), pulse information transmitted from the automatic analysis device (100) provided with a mechanism which is driven by a pulse motor, and a transmission means which transmits pulse information including tow among a driving pulse value for driving the pulse motor, a consumed pulse amount that is a pulse amount consumed when the pulse motor has actually been driven, and a remaining pulse amount obtained by subtracting the consumed pulse amount from the driving pulse value, and stores at least the consumed pulse amount.

Methods, systems, computer program products, apparatus and circuits are configured to detect fallen containers upstream or proximate an intake zone suitable for automated evaluation apparatus using different sensors, including at least one lower sensor and at least one upper sensor which is positioned to project an optical signal at a height corresponding to a top portion of an upright container to thereby allow an increased reliability in detection of different orientations and positions of fallen containers. An optional second lower sensor may be used which is longitudinally spaced apart from the first lower sensor and the lower sensors can transmit optical signals across the container travel path that do not intersect.

A sample analyzing apparatus for performing an optical-based measurement on a sample includes a housing, a first light source, excitation optics, a first light detector, emission optics, and a monitoring system, all of which are disposed in the housing. The monitoring system is configured for monitoring a movable component disposed in the housing. The monitoring system includes one or more light sources for illuminating the movable component, and one or more light detectors for detecting light reflected from the movable component in response to being illuminated.

The present invention provides an automatic analyzer capable of reducing the time necessary for analysis processing by making various operations pertaining to the analysis processing more efficient. More specifically, the present invention is characterized in that, from among a plurality of ending operation items set as analysis ending operations to perform at the end of analysis operations for analyzing a sample under analysis, one or more ending operation items to be performed are selected, and on the basis of monitoring results of monitoring the status of an automatic analyzer during the period from the end of the analysis ending operations to the start of analysis preparation operations for preparing for the analysis operations, one or more preparation operation items to be performed are selected from among a plurality of preparation operation items set as analysis preparation operations.

In medical analysis devices and automatic specimen examination systems, the specimen conveyance mechanism is constituted by a plurality of belt lines. During installation or maintenance of the specimen conveyance mechanism, it is necessary to confirm the existence of steps at the joints of these belt lines and the parallelism of the conveyance line. According to the present invention, it is possible to lighten the burden of this work with a test tube type or conveyance holder type inspection device provided with a sensor and battery for operation. Also, even when an operator cannot visually confirm the conveyance line from outside, it is possible to confirm the state of the conveyance line.

A specimen transportation system is configured from linear modules, turn modules, and connection modules. The modules can freely combine with one another. Moreover, the modules form multiple paths through which specimen racks outputted from one specimen output device are transported to multiple analysis devices. When transporting a specimen rack from an upstream side to a downstream side, each module attaches a destination signal associated with the specimen rack to the specimen rack and transfers the destination signal to the downstream side. As a consequence of each module transporting the specimen rack from the upstream side to the downstream side that corresponds to the destination signal, the specimen rack becomes transported along a path that corresponds to the destination signal.

The present disclosure provides a computing device (100) for classification of an aspirating/dispensing operation in an automated analyzer (50). The computing device (100) comprises a memory (22) storing a neural network model (24). The neural network model 24 sequentially comprises a plurality of convolution blocks (202-1, 202-2 . . . 202-N). The computing device (100) further comprises a processor (20) communicably coupled to the memory (22) and at least one measurement sensor (106) associated with a pipetting probe (104) of a pipetting device (102). The processor (20) is capable of executing the neural network model (24). The processor (20) is further capable of executing instructions (26) to classify the aspirating/dispensing operation into at least one correct class or at least one incorrect class.

A position tracking system for tracking a relative position between connected modules. A target is arrangeable on and/or within a first connected module, the connected modules mechanically interacting for transporting objects between modules; a position sensor is arrangeable on and/or within a second connected module and is configured for generating a sensor signal according to a relative position between the position sensor and target, a processing unit configured for tracking a relative position between the connected modules from the sensor signal; and a second sensor is configured for generating a second sensor signal according to at least a second parameter, wherein the second sensor is a temperature sensor and/or a humidity sensor, the processing unit being configured for considering the second sensor signal when determining the relative position between the connected modules. Further disclosed are related monitoring systems and methods for tracking and monitoring at least two connected modules.

Methods, systems, computer program products, apparatus and circuits are configured to detect fallen containers upstream or proximate an intake zone suitable for automated evaluation apparatus using different sensors, including at least one lower sensor and at least one upper sensor which is positioned to project an optical signal at a height corresponding to a top portion of an upright container to thereby allow an increased reliability in detection of different orientations and positions of fallen containers. An optional second lower sensor may be used which is longitudinally spaced apart from the first lower sensor and the lower sensors can transmit optical signals across the container travel path that do not intersect.

Such a parts anomaly detection system is provided as being able to detect the anomaly of the parts of the liquid transport system of the automatic analyzer without delay.

The parts anomaly detection system to detect the anomaly of the parts of the liquid transport system (22) which absorbs and discharges liquid with respect to a sensor (21) for sample inspection of an automatic analyzer (1) comprises: storage devices (31, 41) to store data of electric signals outputted by the sensor and processing devices (32, 42) to process the data recorded in the storage devices, in which the processing devices detect the anomaly of the parts of the liquid transport system based on the electric signals.