Abstract: A reflecting microscope module cooperating with an image capturing module includes a housing, a lens and a sample adhesive substance. The housing has a sample inspecting surface located on one side of the housing opposite to the image capturing module. The lens is disposed in the housing and the sample adhesive substance is detachably disposed on a bottom of the housing. The sample adhesive substance adjacently connected to the sample inspecting surface includes a substrate and a glue layer. The glue layer is integrally combined with the substrate to form one piece. A reflecting microscope device is also disclosed.

Abstract: A microscope module, which is cooperated with an image capturing module, includes a housing, a convex lens and an illumination assembly. The housing has a sample inspecting surface located on one side of the housing, which is opposite to the image capturing module. The convex lens is disposed in the housing, and the shortest distance between the sample inspecting surface and the convex lens ranges from 0.1 mm to 3.0 mm. The illumination assembly has a light source and is located between the image capturing module and the convex lens. The light emitted from the light source enters the convex lens through an input surface of the convex lens, leaves the convex lens through an output surface of the convex lens, and then reaches the sample inspecting surface. A microscope device containing the microscope module is also disclosed.

Abstract: Examples herein relate to server systems with hinge mechanisms. In one example, a server system includes a first enclosure and a second enclosure, the first and second enclosure each include a front end and a back end disposed opposite to each other, the front end having an opening. The server system further includes a hinge mechanism, the hinge mechanism connecting an upper edge of the back end of the first enclosure to an upper edge of the front end of the second enclosure. The first enclosure is adapted to rotate around the hinge mechanism.

Abstract: A microscope module includes a light source assembly, a sampling assembly and a diffusing element. The light source assembly includes a light source and a light guide element. The light source is disposed close to the light incidence end of the light guide element. The sampling assembly includes a cover and a base. The cover and the base are combined to define a sample accommodating space, which is located at the light exit end of the light guide element. The diffusing element is disposed between the light source and the sample accommodating space. The light emitted from the light source passes through the diffusing element and then enters the sample accommodating space. A microscope device containing the microscope module is also disclosed.

Abstract: An electronic device and a play and interactive method for an electronic advertising are provided. The electronic device includes a touch module, a display, a static information presentation structure and a data processing device. The touch module has a touch area for providing position of a measured object in the touch area. The display has a display area set in the touch area. The touch area is composed of the display area and a non-display area. The static information presentation structure is disposed on the non-display area. The data processing device determines whether the measured object performs a operation in the display area or the non-display area according to the position of the measured object provided by the touch module. When the operation is located in the non-display area, the data processing device displays a corresponding data in the display area according to position of the operation.

Abstract: A portable microscope apparatus operated with an image capture device includes a sample carrying module, a lens module, a first polarizer and a second polarizer. The sample carrying module includes a transparent carrier and a sample adhesive element including a substrate and a glue layer. The substrate has a concave portion and an extending portion. The concave portion is adjacently connected to the extending portion to form a first surface. The glue layer is at least partially disposed on the first surface and in an integrated form with the substrate. The lens module is detachably connected to the image capture device, and disposed between the sample carrying module and the image capture device. The first polarizer is disposed on an optical path on one side of the sample carrying module. The second polarizer is disposed on the optical path on the other side of the sample carrying module.

Abstract: An optical viewing device includes a first assembly and a second assembly. The first assembly includes a first body and a light source. The second assembly includes a second body, a convex lens and an image capturing module. The first body has a first connecting portion and a light output hole, and the first connecting portion is disposed on at least one side of the light output hole. The light source is disposed within the first body. The second body has a second connecting portion, which is disposed corresponding to the first connecting portion. The convex lens and the image capturing module are disposed within the second body, and the light outputted from the light output hole passes through the convex lens and then enters the image capturing module. The first connecting portion and the second connecting portion are connected with each other to form a chamber.

Abstract: A reflecting microscope module cooperating with an image capturing module includes a housing, a lens and a sample adhesive substance. The housing has a sample inspecting surface located on one side of the housing opposite to the image capturing module. The lens is disposed in the housing and the sample adhesive substance is detachably disposed on a bottom of the housing. The sample adhesive substance adjacently connected to the sample inspecting surface includes a substrate and a glue layer. The glue layer is integrally combined with the substrate to form one piece. A reflecting microscope device is also disclosed.

Abstract: A sample detecting device is used in cooperation with an image capturing device. The sample detecting device includes a first assembly and a second assembly. The first assembly includes a light emitting unit and a light-permeable unit. The light-permeable unit is disposed at one side of the light emitting unit. The first assembly and the second assembly match and connect with each other to form a sample containing space. The second assembly includes a body and a convex lens. The body has a first cavity portion and a second cavity portion. The light-permeable unit is disposed in the first cavity portion, and the convex lens is disposed in the second cavity portion. The light emitted from the light emitting unit sequentially passes through the light-permeable unit and the convex lens and leaves the body.

Abstract: A microscope apparatus includes a sample carrying module, a light source module and a lens module. The sample carrying module includes an adhesive element and a body having a light-transmission region and a sample viewing surface. The adhesive element is detachably adhered to the body, and at least partially covers the light-transmission region, such that the adhesive element is disposed adjacent to the sample viewing surface. The light source module is detachably disposed at a side of the body, and includes a base and a light source. The base has an aperture, and the sample carrying module is detachably disposed at a side of the aperture. The light source is disposed in the base. The lens module includes at least one lens, which is detachably disposed at one side of the sample carrying module and substantially focuses at the sample viewing surface, and corresponds to the light source module.

Abstract: A microscope unit and a microscope device are disclosed. The microscope unit is used with an external image capture module or an image capture module of the microscope device. The microscope unit comprises a body, an optical assembly and a heating element. The body has a tunnel going through the body, and a specimen observation plane located in the tunnel. The optical assembly having a convex lens is disposed at one end of the tunnel. A minimum distance from the specimen observation plane to the convex lens ranges from 0.1 mm to 3.0 mm. The heating element is disposed corresponding to the specimen observation plane.

Abstract: A detecting device for detecting a sample in a fluid includes an image capturing unit, at least one lens, a detecting area and a light source. The image capturing unit has at least one camera. The lens is disposed at one side of the image capturing unit corresponding to the camera. The lens and the image capturing unit together form a DOF area, and the lens has a first optical axis. The detecting area is located in the DOF area, and the fluid flows through the detecting area. The light source emits a light beam to the DOF area along a second optical axis for illuminating at least a part of the detecting area. The image capturing unit captures at least a part of the light beam reflected, refracted or excited by the sample flowing through the detecting area for generating at least one sample image.

Abstract: A microscope module, which is cooperated with an image capturing module, includes a housing, a convex lens and an illumination assembly. The housing has a sample inspecting surface located on one side of the housing, which is opposite to the image capturing module. The convex lens is disposed in the housing, and the shortest distance between the sample inspecting surface and the convex lens ranges from 0.1 mm to 3.0 mm. The illumination assembly has a light source and is located between the image capturing module and the convex lens. The light emitted from the light source enters the convex lens through an input surface of the convex lens, leaves the convex lens through an output surface of the convex lens, and then reaches the sample inspecting surface. A microscope device containing the microscope module is also disclosed.

Abstract: A microscope module includes a housing, a convex lens and a light guide element. The housing has a sample inspecting surface located on one side of the housing opposite to an image capturing module. The convex lens is disposed in the housing, and the shortest distance between the sample inspecting surface and the convex lens ranges from 0.1 mm to 3.0 mm. The light guide element is disposed on an external portion of the housing and has a light input portion and a light output portion. The light output portion is located between the image capturing module and the convex lens. The light input portion receives a light, and the light is outputted through the light output portion to the convex lens. The light passes through the convex lens and then reaches the sample inspecting surface. A microscope device including the microscope module is also disclosed.

Abstract: A microscope module includes a light source assembly, a sampling assembly and a diffusing element. The light source assembly includes a light source and a light guide element. The light source is disposed close to the light incidence end of the light guide element. The sampling assembly includes a cover and a base. The cover and the base are combined to define a sample accommodating space, which is located at the light exit end of the light guide element. The diffusing element is disposed between the light source and the sample accommodating space. The light emitted from the light source passes through the diffusing element and then enters the sample accommodating space. A microscope device containing the microscope module is also disclosed.

Abstract: The present invention discloses a portable microscope device which can be installed on the smartphone capable of capturing image. By combing these devices, users can observe the detection sample and capture the image of the sample instantly without environment limitation. Moreover, during operation, the user can observe the whole image of the sample by substituting the microscope lens of different magnification ratio or by shifting the position of the sample.

Abstract: A microscope apparatus is disclosed. The microscope apparatus comprises a microscope module and an image capture device. The microscope module comprises a housing, a lens element, a sampling assembly, and a light guide element. The lens element is mounted on the housing. The sampling assembly is accommodated in the housing. The light guide element is mounted in the sampling assembly. The sampling assembly is configured to sample a specimen and comprises a cover body and a base body received in the cover body. The cover body has a first top plate and a first anchoring structure connected to the top plate. The base body has a second opt plate and a second anchoring structure connected to the second top plate. The second top plate faces the first top plate to define a holding space for the specimen.

Abstract: A method and an apparatus for evaluating weighting of elements of a DAC and a SAR ADC using the same are provided. An equivalent weighting of each composed element is obtained by adding a reference element with a reference weighting, an auxiliary DAC, and a search circuit into the SAR ADC, and the equivalent weighting is represented by the reference weighting. The SAR ADC can calculate and then obtain a correct digital output by using the calibrated equivalent weighting and the successive approximation result of each input signal. The present disclosure prevents the necessity of matching each composed element of the DAC in the SAR ADC.

Abstract: A method and an apparatus for evaluating weighting of elements of a DAC and a SAR ADC using the same are provided. An equivalent weighting of each composed element is obtained by adding a reference element with a reference weighting, an auxiliary DAC, and a search circuit into the SAR ADC, and the equivalent weighting is represented by the reference weighting. The SAR ADC can calculate and then obtain a correct digital output by using the calibrated equivalent weighting and the successive approximation result of each input signal. The present disclosure prevents the necessity of matching each composed element of the DAC in the SAR ADC.

Abstract: Disclosed is a micro-hole structure and a method for forming the micro-hole. A working energy source is projected onto a predetermined drilling site on a first surface of a substrate for a given period of time so as to melt a portion of the substrate to form a working energy entering section until the working energy source penetrates through a second surface of the substrate to form a micro-hole. A melt formed by melting a portion of the substrate in the micro-hole next to the second surface is allowed to reflow in a direction opposite to the projection of the working energy source to thereby form a reflow section in the substrate. Further, a two or more stages emission of laser pulses is used to form the micro-hole to control the bore diameter of the micro-hole.