Abstract: A physiological sensing device for sensing physiological signal of an organism is provided. The physiological sensing device includes a sensing chip, a coupling sensing electrode and a coupling dielectric stacked layer. The coupling sensing electrode is electrically connected to the sensing chip. The coupling dielectric stacked layer covers the coupling sensing electrode. The coupling dielectric stacked layer is located between the coupling sensing electrode and the organism. The coupling dielectric stacked layer includes a first dielectric layer and a second dielectric layer. The dielectric constant of the second dielectric layer is greater than that of the first dielectric layer. The second dielectric layer is located between the first dielectric layer and the organism.

Abstract: A stacked wiring structure includes a first wiring substrate and a second wiring substrate. The first wiring substrate includes a first glass substrate, multiple first conductive through vias penetrating through the first glass substrate, and a first multi-layered redistribution wiring structure disposed on the first glass substrate. The second wiring substrate includes a second glass substrate, multiple second conductive through vias penetrating through the second glass substrate, and a second multi-layered redistribution wiring structure disposed on the second glass substrate. The first conductive through vias are electrically connected to the second conductive through vias. The first glass substrate is spaced apart from the second glass substrate. The first multi-layered redistribution wiring structure is spaced apart from the second multi-layered redistribution wiring structure by the first glass substrate and the second glass substrate.

Abstract: A beam splitter includes a substrate unit, and first and second prisms disposed on surfaces at two opposite sides of the substrate unit, respectively. The substrate unit includes a substrate member, and a beam splitter film disposed at the substrate member and capable of beam splitting. The beam splitter film includes a plurality of thin film layers arranged in a stack. Each of the thin film layers is made of an inorganic material.

Abstract: An optical device includes a first prism unit, a second prism unit spaced apart from the first prism unit, and a spacer unit disposed between the first and second prism units. Each of the first and second prism units includes a substrate, an anti-reflection coating, and a prism. The substrate has a first surface disposed to face the other one of the first and second prism units, and a second surface opposite to the first surface. The anti-reflection coating is disposed on the first surface of the substrate. The prism is disposed adjacent to the second surface of the substrate. The spacer unit is disposed between the anti-reflection coatings of the first and second prism units.

Abstract: An inkjet print head chip. The chip has a first column of firing chambers and a second column of firing chambers in which each firing chamber comprises a heater and an ink channel. A first ink slot is formed between the first column of firing chambers and the periphery of the chip, in which the first ink slot comprises a plurality of first ink sub-slots and each first ink sub-slot provides ink to part of heaters in the first column of firing chambers. A second ink slot is formed between the second column of firing chambers and the periphery of the chip to provide ink to the heaters in the second column of firing chambers. A dry film is patterned on the entire surface of the chip to separate the first ink sub-slots.

Abstract: An apparatus and a method for determining status of inkjet print head identification circuit are provided for an inkjet print head with a plurality of signal lines. The apparatus comprises: a status output terminal outputting one bit data of the status of the inkjet print head identification circuit; a first blowing terminal electrically coupled to the status output terminal via a first programmable switch; and a second blowing terminal electrically coupled to the status output terminal via a second programmable switch; wherein one of the first programmable switch and the second programmable switch being off to determine a voltage level of the status output terminal.

Abstract: The present invention provides an ink jet printhead identification circuit and method. The identification circuit is constructed of a fuse and other electronic components. A plurality of circuits are arranged and integrated on the printhead of the cartridge and encoded prior to leaving the factory subjecting the identification and detection circuits to achieve its identification purpose (of identifying general information of the cartridge, such as model number, serial number, color or gray-scale setting, and best printing quality). The circuits may alternatively be encoded subsequent to leaving the factory and usage to a certain state subjecting the identification circuits to achieve its detection purpose (of detecting the current status of the cartridge, such as whether its lifespan has elapsed).

Abstract: An ink cartridge for an inkjet printer includes a housing, an output channel, a porous material, and an adhesive layer. The housing has a vertical ink chamber for storing ink and an opening disposed on a top side of the ink chamber for interchanging air inside the ink chamber with air outside the ink chamber. The output channel is connected with a bottom side of the ink chamber for supplying ink from the ink chamber. The porous material is filled in the ink chamber for absorbing ink within the ink chamber. The adhesive layer is formed on a top end of the porous material for forming a sealed surface on the top end of the porous material.

Abstract: An inkjet print head chip. The chip has a first column of firing chambers and a second column of firing chambers in which each firing chamber comprises a heater and an ink channel. A first ink slot is formed between the first column of firing chambers and the periphery of the chip, in which the first ink slot comprises a plurality of first ink sub-slots and each first ink sub-slot provides ink to part of heaters in the first column of firing chambers. A second ink slot is formed between the second column of firing chambers and the periphery of the chip to provide ink to the heaters in the second column of firing chambers. A dry film is patterned on the entire surface of the chip to separate the first ink sub-slots.

Abstract: An ink print head has an ink container for storing fluid, a chip installed at a bottom of the ink container having a central slot for passing fluid, and a dry film formed on the chip having a plurality of ink chambers. The ink print head also has a nozzle plate formed below the dry film, a middle portion of the nozzle plate protruding above the nozzle plate so as to form a central refill chamber, a plurality of nozzles corresponding to the ink chambers of the dry film, and a plurality of heaters set on the chip for heating fluid inside the ink chambers so that the fluid can be ejected from the nozzles of the nozzle plate. The fluid inside the ink container will flow through the central slot into the central refill chamber and then into the ink chambers.

Abstract: An ink cartridge for an inkjet printer includes a housing, an output channel, a porous material and an adhesive layer. The housing has a vertical ink chamber for storing ink and an opening disposed on a top side of the ink chamber for interchanging air inside the ink chamber with air outside the ink chamber. The output channel is connected with a bottom side of the ink chamber for receiving ink from the ink chamber. The porous material is filled in the ink chamber for absorbing ink within the ink chamber. The adhesive layer is formed on a top end of the porous material for forming a sealed surface on the top end of the porous material.

Abstract: A recognition circuit for an ink jet printer has a plurality of heating cells. Each of the heating cells has a heating element coupled with a power line and a switch coupled with an address line. When voltages are applied to the power line and the address line, the switch is turned on and a current flows via the power line through the heating element. The recognition circuit further has a plurality of identifying cells each coupled with a corresponding power line. The recognition circuit can read the identification code from each the identifying cells by applying voltage to corresponding power lines.

Abstract: The ink cartridge is provided with a pressure controller to regulate the inner pressure therein by atmospheric pressure while the ink stored in the ink cartridge is gradually drained off. The ink is stored in a container with negative pressure therein, and at least one through hole formed on the container is used to connect to the atmosphere, and at least one recess is formed on the inner wall of the through hole. The pressure controller has a plug movably disposed on the through hole and the recesses. The recesses are used as a channel to allow the entrance of the atmospheric air, and the plug can be automatically moved so as to enlarge the clearance between the plug and the through hole while the ink stored in the ink cartridge is gradually drained off. The inputted air can effectively reduce the negative pressure in the container, and therefore the printing process of the ink cartridge can be proceeding steadily.

Abstract: A recognition circuit for an ink jet printer has a plurality of heating cells. Each of the heating cells has a heating element coupled with a power line and a switch coupled with an address line. When voltages are applied to the power line and the address line, the switch is turned on and a current flows via the power line through the heating element. The recognition circuit further has a plurality of identifying cells each coupled with a corresponding power line. The recognition circuit can read the identification code from each the identifying cells by applying voltage to corresponding power lines.

Abstract: An ink container includes an ink chamber for storing ink, a print head installed below the ink chamber for receiving ink from the ink chamber, an ink channel installed between the ink chamber and the print head for passing ink from the ink chamber to the print head, a nozzle installed below the print head for injecting ink, and a heater installed beside the nozzle for heating ink so as to inject ink through the nozzle. The resistive layer of the heater has essentially refractory material, oxygen and nitrogen.

Abstract: An ink print head has an ink container for storing fluid, a chip installed at a bottom of the ink container having a central slot for passing fluid, and a dry film formed on the chip having a plurality of ink chambers. The ink print head also has a nozzle plate formed below the dry film, a middle portion of the nozzle plate protruding above the nozzle plate so as to form a central refill chamber, a plurality of nozzles corresponding to the ink chambers of the dry film, and a plurality of heaters set on the chip for heating fluid inside the ink chambers so that the fluid can be ejected from the nozzles of the nozzle plate. The fluid inside the ink container will flow through the central slot into the central refill chamber and then into the ink chambers.

Abstract: The present invention is an ink pressure adjustment device of inkjet pen; the device is utilized to adjust negative pressure in an ink cartridge mainly through an expandable and shrinkable gasbag installed in the ink cartridge, and a tension valve attached on the surface of the gasbag. The tension valve can open or close automatically an air hole that communicates atmosphere and the inner part of ink cartridge via the gasbag according to the expansion and shrinkage of the gasbag, causing a part of atmosphere to enter the ink cartridge so as to adjust the negative pressure of the ink cartridge and not only can prevent ink from leaking but also prevent the negative pressure from being too large to fail the inkjet printing.

Abstract: The present invention is an ink pressure adjustment device of inkjet pen; the device is utilized to adjust negative pressure in an ink cartridge mainly through an expandable and shrinkable gasbag installed in the ink cartridge, and a tension valve attached on the surface of the gasbag. The tension valve can open or close automatically an air hole that communicates atmosphere and the inner part of ink cartridge via the gasbag according to the expansion and shrinkage of the gasbag, causing a part of atmosphere to enter the ink cartridge so as to adjust the negative pressure of the ink cartridge and not only can prevent ink from leaking but also prevent the negative pressure from being too large to fail the inkjet printing.

Abstract: The ink cartridge of the present invention uses a directional fibrous collection enclosed within a bushing to temporally retain the ink therein, wherein at least one controlled capillary portion is provided. The controlled capillary portion can be formed by the bushing or by a predetermined shape located in the cartridge. The capillary forces of the controlled capillary portion are stronger than the one of other portion of the directional fibrous collection. The flow rate of the ink can be precisely controlled by the directional fibrous collection, and the controlled capillary portion can efficiently drain out the ink to the printhead and there is no bubble left therein.

Abstract: The present invention pertains to a packaging method and the structure of an inkjet cartridge print head chip. The main technique disclosed herein is to package a chip substrate that can resist the corrosion of the ink at the ink cartridge outlet. A preferred embodiment is to package the chip substrate at the ink outlet at the same time when the inkjet cartridge is formed through plastic molding. Another preferred embodiment is to package the chip substrate at the ink cartridge outlet using ultrasonic or heat welding and then glue the print head on the chip substrate. These means can solve the problem of ink leakage in conventional ink cartridge because of the corrosion of ink to the glue between the print head chip and the ink cartridge.