Abstract: The package structure having packaged components within includes a circuit board, multiple packaged light detecting components mounted on the circuit board, a sealing cap being light transmittable, multiple light filtering films mounted on the sealing cap, and a supporting annular wall. The two opposite ends of the supporting annular wall are adhesively bonded to the surfaces of the circuit board and the sealing cap, such that the projection on the circuit board of the light filtering films corresponds the packaged light detecting components. Since the light filtering films have different filtering frequency bands, each packaged light detecting component detects light of different frequency bands in one incident light beam. The package method is simple and stable, effectively lowering the manufacture cost of the light detecting module.

Abstract: A sanitary device for the urine glucose test includes a urine container formed on an inner wall of a main body, and a measuring module with an inner space mounted at a bottom of the urine container. Within the inner space, a lens attaches to the bottom of the urine container, a rail faces a bottom surface of the lens, and a driving module moves a light unit shooting a detection beam to a measuring surface of the lens along the rail. The measuring surface contacts urine in the urine container, and reflects the detection beam out of the bottom surface into a sensor. The sensor is electrically connected to a processor. The processor determines a urine glucose level and generates a urine glucose level data instantly from an angle of incidence of the detection beam on the measuring surface and from a beam intensity signal from the sensor.

Abstract: The present invention relates to an optical system for triglyceride inspection partially integrated into a toilet seat and comprising a plurality of optical sensor modules and a controlling and processing module, wherein each said optical sensor module comprises a first light source, a second light source and an optical sensor. The optical sensor receives light signals generated by the first and second light sources respectively on the skin of the person (especially the skin of the thighs) to be tested and thereby generates a sensing signal of an adaptive calibration function. The sensing signal is then converted by the controlling and processing module into an inspection value of triglyceride, which is transmitted to a display unit. With the above optical system for triglyceride inspection, triglycerides can be inspected automatically without invasive blood sampling, making the system a convenient home health monitoring device.

Abstract: A urinal with built-in urine detection, comprises a urinal body, a detector, a processor and a display, the urinal body is disposed with a urine slot, and a urine drainage hole is disposed on a bottom of the urine slot; the detector is arranged in the urine slot and includes a casing, a detection channel for urine to pass through, a light source module and a sensing module. The light source module emits a detection beam into the detection channel, and the sensing module receives the detection beam passing through the urine, and generates a light intensity signal according to the detection beam; the processor electrically connects to the light source module and receives the light intensity signal, and calculates contents of various components in the urine according to the light intensity signal, to generate a test result and displays the test result in a display screen.

Abstract: The present invention includes a shell, a light emitter, a beam splitter, a convergent lens, an optical filter, a collimation unit, a discrete light detection unit, and a processing unit. The shell includes a sample well to contain a sample. The light emitter generates a detection beam towards the beam splitter, the detection beam is reflected by the beam splitter before being converged by the convergent lens onto the sample, and a Raman scattered beam is scattered from the sample. The Raman scattered beam respectively passes through the convergent lens, the beam splitter, the optical filter, and the collimation unit, allowing the collimation unit to collimate the Raman scattered beam into a collimated beam. The discrete light detection unit generates multiple light intensity signals according to the collimated beam received, and the processing unit generates a detection result according to the light intensity signals to help detect toxins.

Abstract: The invention discloses a glycosuria measurement device, comprising a prism body and a housing. The prism body comprises a first accommodating space, a junction surface, a first light penetrating surface, a second light penetrating surface, a third light penetrating surface and a light-emitting surface. The first accommodating space accommodates urine. The junction surface is formed at a bottom surface of the first accommodating space. The first light penetrating surface is formed at the first lateral surface of the first accommodating space. The second light penetrating surface is formed at the second lateral surface of the first accommodating space. The third light penetrating surface is disposed opposite to the junction surface. The light-emitting surface is disposed opposite to the junction surface. The housing comprises a second accommodating space, a first light-emitting port and a second light-emitting port. The second accommodating space accommodates the prism body.

Abstract: The present invention includes a needle connected to a urine container; a side of the needle is connected to the urine container, and the other side is a blunt end; a holder is mounted on a base, and the urine container is detachably mounted on the holder; a camera unit is mounted on the base, aiming at the blunt end; a light source is mounted on the base, emitting a detection beam; a processor unit is electrically connected to the camera unit; wherein when a sample urine in the urine container drips through the needle and forms a drop of urine, the detection beam passes through the drop of urine and travels into the camera unit; the processor unit receives an image of the drop of urine through the camera unit, and the processor unit instantly calculates a protein concentration of the drop of urine from the image.

Abstract: An optical testing device has a beam splitting element, a glowing unit, a first sensor, and a second sensor. The beam splitting element has a first side and a second side. The glowing unit and the second sensor are disposed at the second side. The first sensor is disposed at the first side. The beam splitting element is capable of splitting the beam emitted from the glowing unit into a testing beam and a reflection beam. The testing beam penetrates the beam splitting element and is received by the first sensor. The reflection beam is reflected by the beam splitting element and is received by the second sensor. Therefore, the change of light intensity of the light source can be monitored, and thus the processing unit is allowed to correct the calculations on the basis of the change of light intensity of the light source.

Abstract: A pesticide detection device with a washing function comprises a detection assembly and a vibration assembly. The detection assembly includes a waterproof casing with an inner space and a detection end, a display disposed on the waterproof casing, a detection channel formed at the detection end of the waterproof casing, a light source module disposed in the inner space of the waterproof casing, a sensor disposed in the inner space of the waterproof casing, and a processor disposed in the inner space and electrically connected to the light source module, the sensor, and the display. The vibration assembly includes a casing having an inner space with a motor, and a vibration element connected to the casing and generating vibration by the motor.

Abstract: The invention discloses a glycosuria measurement device, comprising a prism body and a housing. The prism body comprises a first accommodating space, a junction surface, a first light penetrating surface, a second light penetrating surface, a third light penetrating surface and a light-emitting surface. The first accommodating space accommodates urine. The junction surface is formed at a bottom surface of the first accommodating space. The first light penetrating surface is formed at the first lateral surface of the first accommodating space. The second light penetrating surface is formed at the second lateral surface of the first accommodating space. The third light penetrating surface is disposed opposite to the junction surface. The light-emitting surface is disposed opposite to the junction surface. The housing comprises a second accommodating space, a first light-emitting port and a second light-emitting port. The second accommodating space accommodates the prism body.

Abstract: The package structure having packaged components within includes a circuit board, multiple packaged light detecting components mounted on the circuit board, a sealing cap being light transmittable, multiple light filtering films mounted on the sealing cap, and a supporting annular wall. The two opposite ends of the supporting annular wall are adhesively bonded to the surfaces of the circuit board and the sealing cap, such that the projection on the circuit board of the light filtering films corresponds the packaged light detecting components. Since the light filtering films have different filtering frequency bands, each packaged light detecting component detects light of different frequency bands in one incident light beam. The package method is simple and stable, effectively lowering the manufacture cost of the light detecting module.

Abstract: A prism for measuring liquid concentration includes: an accommodating space for accommodating a liquid; an interface formed on a bottom surface of the accommodating space; a first light transmission surface and a second light transmission surface respectively formed on two side surfaces of the accommodating space; a third light transmission surface and a light emitting surface respectively formed relative to the interface. When a first incident light beam enters the prism, the first incident light beam is reflected to the light emitting surface by the interface, and exits the prism from the light emitting surface. When a second incident light beam enters the prism to the first light transmission surface, the second incident light beam exits the prism to the accommodating space from the second incident light beam, passes through the liquid and the second light to the prism, and exits the prism from the third light transmission surface.

Abstract: The present invention includes a needle connected to a urine container; a side of the needle is connected to the urine container, and the other side is a blunt end; a holder is mounted on a base, and the urine container is detachably mounted on the holder; a camera unit is mounted on the base, aiming at the blunt end; a light source is mounted on the base, emitting a detection beam; a processor unit is electrically connected to the camera unit; wherein when a sample urine in the urine container drips through the needle and forms a drop of urine, the detection beam passes through the drop of urine and travels into the camera unit; the processor unit receives an image of the drop of urine through the camera unit, and the processor unit instantly calculates a protein concentration of the drop of urine from the image.

Abstract: A particle detection device includes a detection tube, a light emitter, a light receiver, and a processing unit. The detection tube is for a detection solution to pass through. The light emitter generates a detection light and emits the detection light to the detection solution. The light receiver receives the detection light scattered from the detection solution. The processing unit generates a received light intensity value according to the detection signal generated by the light receiver, and determines whether the received light intensity value is greater than a first threshold value: if greater, generating a detection result of particles; otherwise, generating a detection result of no particles. Then it provides a basis for semiconductor manufacturing companies to evaluate whether the detection solution can be used in a high-precision manufacturing processes, thereby optimizing the manufacturing process and improving the yield rate of the high-precision manufacturing process.

Abstract: A particle detection device includes a detection tube, a light emitter, a light receiver, and a processing unit. The detection tube is for a detection solution to pass through. The light emitter generates a detection light and emits the detection light to the detection solution. The light receiver receives the detection light scattered from the detection solution. The processing unit generates a received light intensity value according to the detection signal generated by the light receiver, and determines whether the received light intensity value is greater than a first threshold value: if greater, generating a detection result of particles; otherwise, generating a detection result of no particles. Then it provides a basis for semiconductor manufacturing companies to evaluate whether the detection solution can be used in a high-precision manufacturing processes, thereby optimizing the manufacturing process and improving the yield rate of the high-precision manufacturing process.

Abstract: The present invention allows a sample urine to enter an entry hole formed on a shell and to flow through a flow pathway. A part of the sample urine remains in a groove of the flow pathway as collected urine. A measuring module in the shell includes a first side and a second side. The first side includes a light emitting unit and a light sensing unit. The second side includes a lens. The lens is mounted in the groove. The light emitting unit generates a detection beam. The detection beam passes the lens, the collected urine, a reflective mirror, the lens again, and into the light sensing unit. The light sensing unit receives the detection beam and generates a sensing signal. The processing unit generates a detection result signal according to the sensing signal, and a display unit immediately displays a test result of the sample urine.

Abstract: Disclosed is a bioinstrumentation apparatus including a main unit, a detection portion, a light source, and an optics sensor. The bioinstrumentation apparatus is a kind of home health care device for testing Triglycerides automatically without requiring any chemical reagent or blood specimen.

Abstract: A biological detection device for a toilet water solution includes a mounting portion, a main system, an adjustable support portion and a detection portion. The main system is connected to the mounting portion. The adjustable support portion can be adjusted for its movement in both horizontal and vertical directions and is connected to the mounting portion. The detection portion is connected and linked to the adjustable support portion and includes a light emitting source and an optical sensor. The biological detection device for a toilet water solution is a home healthcare device capable of automatically detecting whether there is blood in stool or urine without adding any chemical reagent or collecting any stool or urine specimen.

Abstract: A hemoglobin detecting method is executed by a mobile device having a hemoglobin detecting function. The mobile device includes a processor unit, a first light source that generates a first light beam, and a light detecting module that receives a second light beam that is generated when the first light beam travels through an analyte solution and is reflected. The light detecting module generates first to fourth intensity signals according to the second light beam, and the processor unit determines whether the absorption spectrum of the analyte solution matches a target spectrum. If the absorption spectrum of the analyte solution matches the target spectrum, the processor unit generates positive result information; otherwise, the processor unit generates negative result information. The mobile device provides a fast and accurate way to detect blood in a stool solution, which does not require collecting samples of stool or applying any chemical.

Abstract: A hemoglobin detecting device includes a shell component connected with a fixing part that engages with an outer side of a smart device. A processor unit, a light source, a light detection module and a transmission unit are mounted inside the shell component. The light source generates a first light beam, and the light detection module receives a second light beam that is generated when the first light beam travels through an analyte solution and is reflected. The processor unit determines whether the absorption spectrum of the analyte solution matches a target spectrum, and generates a result information according to the detection. The transmission unit transmits the result information to the smart device and displays an indication of the result. The hemoglobin detecting device provides a fast and accurate way to detect blood in a stool solution, and can be applied to and cooperate with all kinds of smart devices.