Abstract: A manufacturing method of an integrated driving module with energy conversion function includes providing a carrier board and forming an integrated electromagnetic induction component layer having a first dielectric layer, a plurality of conductive coil layers and a plurality of conductive connecting components on a surface of the carrier board. A patterned conductive circuit layer is formed on the integrated electromagnetic induction component layer, and electrically connecting to each other through the conductive connecting components. An embedded electrical component is patterned on the patterned conductive circuit layer. A conductive component is disposed on the patterned conductive circuit layer. Thereafter, the method forms a second dielectric layer to cover the embedded electrical component and the conductive component and removes the carrier board to form a plurality of integrated driving modules.

Abstract: An integrated driving module with energy conversion function includes a patterned conductive circuit layer, an integrated electromagnetic induction component layer, a second dielectric layer, an embedded electrical component and a conductive component. The integrated electromagnetic induction component layer, which has a plurality of conductive coil layer, a plurality of conductive connecting component and a first dielectric layer, is disposed on the patterned conductive circuit layer. The conductive coil layers are stacked. Each conductive connecting component is electrically connected between the two conductive coil layers and between the corresponding conductive coil layer and the patterned conductive circuit layer. The first dielectric layer covers the conductive coil layers and the conductive connecting components. The second dielectric layer covers the patterned conductive circuit layer.

Abstract: An integrated driving module with energy conversion function includes a patterned conductive circuit layer, an integrated electromagnetic induction component layer, a second dielectric layer, an embedded electrical component and a conductive component. The integrated electromagnetic induction component layer, which has a plurality of conductive coil layer, a plurality of conductive connecting component and a first dielectric layer, is disposed on the patterned conductive circuit layer. The conductive coil layers are stacked. Each conductive connecting component is electrically connected between the two conductive coil layers and between the corresponding conductive coil layer and the patterned conductive circuit layer. The first dielectric layer covers the conductive coil layers and the conductive connecting components. The second dielectric layer covers the patterned conductive circuit layer.

Abstract: An integrated driving module with energy conversion function includes a patterned conductive circuit layer, an integrated electromagnetic induction component layer, a second dielectric layer, an embedded electrical component and a conductive component. The integrated electromagnetic induction component layer, which has a plurality of conductive coil layer, a plurality of conductive connecting component and a first dielectric layer, is disposed on the patterned conductive circuit layer. The conductive coil layers are stacked. Each conductive connecting component is electrically connected between the two conductive coil layers and between the corresponding conductive coil layer and the patterned conductive circuit layer. The first dielectric layer covers the conductive coil layers and the conductive connecting components. The second dielectric layer covers the patterned conductive circuit layer.

Abstract: An identifying method for detecting a specific region of a translucent medium provided includes steps as follows. A light sensing module is adjusted to allow an operation point of the light sensing module to be in an active region. Light is emitted to a driven translucent medium by a light-emitting module. The light been passed through the translucent medium is sensed by the light sensing module to generate a first light-intensity signal based on the light sensed at one time instant, and the voltages of the first light-intensity signal are regulated to derive a second light-intensity signal. A voltage level of the first light-intensity signal is compared with that of the second light-intensity signal to generate a comparison result. A determination of whether a specific region of the translucent medium is positioned between light sensing module and light-emitting module is made based on the comparison result.

Abstract: An identifying method for detecting a specific region of a translucent medium provided includes steps as follows. A light sensing module is adjusted to allow an operation point of the light sensing module to be in an active region. Light is emitted to a driven translucent medium by a light-emitting module. The light been passed through the translucent medium is sensed by the light sensing module to generate a first light-intensity signal based on the light sensed at one time instant, and the voltages of the first light-intensity signal are regulated to derive a second light-intensity signal. A voltage level of the first light-intensity signal is compared with that of the second light-intensity signal to generate a comparison result. A determination of whether a specific region of the translucent medium is positioned between light sensing module and light-emitting module is made based on the comparison result.

Abstract: A thermal print system includes a case, a thermal print device, an information storage device, an information transmission device and a control device. The thermal print device is detachably installed inside the case and is for performing thermal printing. The information storage device is installed inside the case and is for storing parameter information of the thermal print device. The information transmission device is installed inside the case and is for fetching the parameter information stored in the information storage device. The control device is installed inside the case and is electrically connected to the information transmission device. The control device controls the thermal print device to perform the corresponding thermal printing according to the parameter information transmitted from the information transmission device.

Abstract: The present invention discloses a printing device. The printing device of the present invention may include a communication element capable of communicating with an external host utilizing a plurality of telecommunication network technologies to receive a file sent from the external host to the device, a printing element electrically coupled to the communication element to output an image file, and an audio outputting element electrically coupled to the communication element to output an audio file, wherein the communication element identifies a file type of the file received from the external host and selectively sends the file to the printing element or the audio outputting element.

Abstract: A detecting device includes an actuating unit for driving a transparent material, a light source for emitting light to the transparent material driven by the actuating unit, a light sensor for sensing the light emitted from the light source as an edge of the transparent material is moved to different positions relative to the light source so as to generate a corresponding optical intensity signal, a transforming circuit coupled to the light sensor for transforming the optical intensity signal into a transforming signal, and a processing unit coupled to the transforming circuit for determining whether the edge of the transparent material is moved to a position between the light source and the light sensor according to the transforming signal transmitted from the transforming circuit. And methods and systems for same.

Abstract: A thermal print system includes a case, a thermal print device, an information storage device, an information transmission device and a control device. The thermal print device is detachably installed inside the case and is for performing thermal printing. The information storage device is installed inside the case and is for storing parameter information of the thermal print device. The information transmission device is installed inside the case and is for fetching the parameter information stored in the information storage device. The control device is installed inside the case and is electrically connected to the information transmission device. The control device controls the thermal print device to perform the corresponding thermal printing according to the parameter information transmitted from the information transmission device.

Abstract: A detecting device includes an actuating unit for driving a transparent grating structure, a light source for emitting light to the transparent grating structure driven by the actuating unit, a light sensor for sensing the light emitted from the light source as the transparent grating structure is moved to different positions relative to the light source so as to generate a corresponding optical intensity signal, a transforming circuit coupled to the light sensor for transforming the optical intensity signal into a transforming signal, and a processing unit coupled to the transforming circuit for determining a position of the transparent grating structure according to the transforming signal transmitted from the transforming circuit.

Abstract: A detecting device includes an actuating unit for driving a transparent material, a light source for emitting light to the transparent material driven by the actuating unit, a light sensor for sensing the light emitted from the light source as an edge of the transparent material is moved to different positions relative to the light source so as to generate a corresponding optical intensity signal, a transforming circuit coupled to the light sensor for transforming the optical intensity signal into a transforming signal, and a processing unit coupled to the transforming circuit for determining whether the edge of the transparent material is moved to a position between the light source and the light sensor according to the transforming signal transmitted from the transforming circuit.

Abstract: An object moving apparatus for controlling the movement of an object such as a print medium includes a first motor, a second motor, a moving module, a first power transmission module, a second power transmission module and a controlling module. The moving module is for moving the object. The first power transmission module is coupled between the first motor and the moving module, and is for delivering power from the first motor to the moving module to drive the moving module to move the object. The second power transmission module is coupled between the second motor and the moving module, and is for delivering power from the second motor to the moving module to drive the moving module to move the object. The controlling module is coupled to the first and second motors, and is for selectively turning on the first motor or the second motor.

Abstract: A print medium detecting module includes a first conductive unit, a second conductive unit and a detector. The first conductive unit is coupled to a first reference voltage level. The detector has a detecting port, which is coupled to the second conductive unit and a second reference voltage level, for referring to an electrical characteristic of the detecting port to detect whether there is a non-conductive print media between the first and second conductive units that causes the first conductive unit to not be electrically connected to the second conductive unit. The first and second conductive units in an initial state are electrically connected to each other. The first reference voltage level is different from the second reference voltage level.

Abstract: A print media moving apparatus is disposed in a printer for controlling movement of a print media. The print media moving apparatus includes a motor, a first media moving module, a second media moving module, a controlling module, a first power transmission module and a second power transmission module. The first and second media moving module are both coupled to the motor. The controlling module is coupled to the first and second media moving modules, and is for turning on the first media moving module when the printer operates under a first mode, and turning on the second media moving module when the printer operates under a second mode. The first and second power transmission modules are respectively coupled between the motor and the first and second media moving modules, and are respectively for delivering power from the motor to the first and second media moving modules.

Abstract: An object moving apparatus for controlling the movement of an object such as a print medium includes a first motor, a second motor, a moving module, a first power transmission module, a second power transmission module and a controlling module. The moving module is for moving the object. The first power transmission module is coupled between the first motor and the moving module, and is for delivering power from the first motor to the moving module to drive the moving module to move the object. The second power transmission module is coupled between the second motor and the moving module, and is for delivering power from the second motor to the moving module to drive the moving module to move the object. The controlling module is coupled to the first and second motors, and is for selectively turning on the first motor or the second motor.