TW201246087A - Fingerprint sensor and integratable electronic display - Google Patents

Abstract

A fingerprint sensor which includes a conductive layer which is incorporable within an electronic display is disclosed. The fingerprint sensor also includes a controller coupled to the conductive layer to capture a fingerprint image and can further be adapted to control the display.

Description

201246087 VI. Description of the Invention: [Technical Field] The present invention relates to a fingerprint sensor and an electronic display incorporating the fingerprint sensor. [Prior Art] 'Fingerprint sensing technology has made biological identification and certification procedures since its invention - a radical change. In most cases, a single fingerprint can identify individuals in a unique way that cannot be easily copied or imitated. The ability to capture and store fingerprint images in very small digital files has yielded significant benefits in areas such as law enforcement, forensics and information security. However, fingerprint sensing technology is widely used in various applications, but it faces many obstacles. One of the obstacles is the need for separate instruments for capturing fingerprint images. In addition, such components are often not suitable for use in systems designed for small size or weight. As handheld devices become more versatile and more widely used, engineers and designers of such devices are constantly looking for ways to maximize refinement and convenience while reducing size and cost. Typically, such devices include only input/output components that are considered critical to core functionality, such as screens and a limited set of buttons. ^ Therefore, fingerprint-based authentication technology has not replaced the user name and password in the most commonly used information security areas (eg, u-mail, online banking, and social networking). Paradoxically, Internet users are transmitting an increasing number of sensitive metrics to remote computer systems, which requires a more reliable authentication process than cryptographic-based technology. A display with built-in fingerprint sensing will result in a wider range of fingerprint identification methods. However, incorporating existing fingerprint sensing techniques into electronic devices presents a problem of hardware incompatibility. The large fingerprint _ device requires the fingerprint sensing on the tree f road 3 201246087 components. Mounting such a circuit in a display (whether a resistive circuit, a capacitive circuit, a thermal circuit, or an optical circuit) requires extensive and expensive modifications to the design and production of such displays. As we will see, this article exposes systems that provide for overcoming these obstacles. SUMMARY OF THE INVENTION The present invention discloses a fingerprint sensor and an electronic display incorporating the fingerprint sensor. The finger field disclosed in the present invention includes: a sensing n that can be placed on the electronic display to reduce the position within the upper layer of i mm; and a controller that takes a fingerprint image from the surface, and the controller can be placed in the layer τ of the electronic display. Below; where the sensor is placed between the transparent cover of the electronic display and the protective layer. In at least some configurations, the sensor can be placed in the topmost layer to the touch position; in other configurations the sensor can be placed in the uppermost layer of 600 microns, 550 microns, microns, _micron, 25 microns, 2 〇 〇 Micron and position within 150 microns. In addition, the sensor is adaptable and configurable as it should also include a touch sensor. It is also possible to control the touch sensor controller of the touch sensor. On the other hand, the controller connected to the ^ can also be connected to the touch. At least some of this =: Γ cover layer. The upper layer of the mask layer should be close to the protective layer. The second electrical layer shall be placed on the surface of the underlying layer of the mask and the protective layer: 可: The embossed sensing area is marked, for example, the aperture on the mask. "In this case, it can be secret - one or more controls (four)" can also be clearly added (frost film configuration. In addition, the sensor can be configured to include at least, with steel kick oxide, carbon nanotube 'metal _ wire Through 3 Ai 12 layers of fine metal transfer - Qingjing _. Material, 201246087 Material made at least in some configurations, can provide one or more of flat layer, overall ΐ = Γ plastic film and hard coating The protective layer is selected from the group consisting of ultra-thin glass and poly-p-dicarboxylic acid. In addition, in some configurations, 'a hard coating will be added to the layer. The fingerprint sense is configured to include a conductive layer, and the touch sensing 11 can also be configured to include two conductive layers. The conductive layer of the fingerprint sensor and the conductive layer of the touch sensor constitute an additional electronic device of the present (4) The display includes: an electronic display group for generating a visible display; a protective layer located above the electronic display module, wherein the protective layer contacts the surface of the user's finger for a long time; a fingerprint sensor; and a f texture Sensor connected to the controller for sensing The user's fingerprint captures the crepe image. A transport detector can be provided to detect the movement of the finger on the fingerprint sensor. In addition, a display controller can be provided, and the display controller and the electronic display module are provided. Connected to the visible display of the use of the metamorphosis. Display controller: connected to the finger field test 11 to control the touch sensor by the display H. (In some configurations, a controller can be provided to control the electronic display A sinuous surface sensor may further include a conductive layer disposed under the mask layer, and the mask layer is located on the bottom layer of the protective layer. The mask layer may be configured to include a texture sensing area Indicating, for example, pores on the mask. In addition, in some configurations, the controller can be coated with a thin film. The sensor includes at least one conductive layer. The conductive layer can be used from indium tin oxide, carbon nanotubes, Made of metal nanowires, transparent conductive polymers, and materials selected from the following, or selected from the 'metals'. At least in some configurations, conductive 1疋 flexible materials. In addition, flat layers, optical coatings are available. Layer, optical transmission One or more of the visible adhesive, the permeable shaft and the hard coat. Suitable materials for the protective layer 5 201246087 are selected from the category of materials including ultra-thin glass and polyterephthalic acid. At least in some cases, A hard coating is added to the protective layer. Further, the display may further include a touch sensor. In at least some aspects, the fingerprint sensor may further include a conductive layer touch sensor and may further include a conductive layer The conductive layer of the fingerprint sensor and the guide surface of the touch sense = the body. The mesh and the grain form an integral part so that the integral component includes all the components required for operation. This can be achieved by a whole running component. - Purpose, this design is professional for the method disclosed in the present invention relating to the electronic display, the step of grouping = including · providing - a printed circuit board (also referred to as a substrate); mounting on a printed circuit board - Display controller; install an electronic display group on top of the printed circuit board; place the fingerprint on the top surface of the electronic display; the missing sensor is placed within the uppermost layer of the electronic display, and the electronic display number is the most upper layer Reset - a protective layer, a protective layer is located above the circuit-fingerprint sense of. In some configurations, the sensor can be placed in the uppermost layer within the micron position. ^ In other configurations, the sense can be placed in the top layer _ micron, 55G micron, m, 400 micron, 25G micron, micron and 15 () Micron position. In at least some aspects, the method can further include the following - one or more steps - placing a mask layer between the protective device and the electronic display; and providing a protective layer over the mask layer. The display controller can be configured to control one or more faces of the electronic display, including the area measurement H and the fingerprint. In at least some aspects, the method can include the steps of connecting the display controller to the motion sensor and the fingerprint sensor and/or installing a fingerprint sensor controller on the printed f-board. Additionally, the step of installing the benefit controller can further include connecting the display controller to the motion sensor circuit 201246087 and connecting the fingerprint sensor controller to the fingerprint sensor circuit. Another aspect of exposing information is the method of identifying biometric information. According to the disclosure information, the method includes: identifying a sensor that can be placed within a distance of 1 mm from the uppermost layer of the electronic display, connecting to the sensor to capture a fingerprint image, and placing the controller on the lower layer of the electronic display Below, in addition, the sensor is integrated in the electronic display, placed between the cover and the protective layer; sensing biometric information related to the user; comparing the sensed biometric information with the biometric template associated with the user If the biometric information matches the biometric template, accept the credentials associated with the user based on the biometric information and pass the credentials to the requesting program. At least in some configurations, the sensor can be placed within 80 () micrometers of the uppermost layer; in other configurations, the sensor can be placed at the topmost layer of 6 μm, 550 μm, 500 μm, 400 μm, Locations within 250 microns, 200 microns, and 150 microns. In addition, other aspects of the disclosure include: identifying a sensor that can be placed within 1 mm of the uppermost layer of the electronic display, a controller coupled to the sensor for capturing the fingerprint image, and the controller being placed under the electronic display Below, in addition, the sensor is integrated in the electronic display, placed between the cover and the protective layer; identifies the biometric device installed in the client device equipped with the web application; identifies the biometric information associated with the user Create biometric templates related to biometric information; receive credentials related to the user; and combine the user's credentials with the biometric template. [Embodiment] Various electronic displays are used in conjunction with electronic devices. The display can be operated using emission (pixel-generated light), transmission (transmitting light through pixels), and reflective (reflecting background light). The type of display may include a liquid crystal display (LCD) that uses a liquid crystal that changes the transmission or reflection in the applied electric field, and an organic light-emitting diode (LED) that uses a light-emitting diode (LED) (in the pure two poles, The luminescence produced by the organic compound _ luminescence due to the reaction of the current, and the difference in the movement of the pigment particles due to the reaction of the electric field _ (four) swimming display Gyri_, E_ink, etc.) Gyricon 疋 xerox pARC" is an electronic paper, is a thin layer Transparent plastic, with hundreds of beads distributed along with the financial formula. These beads are: Like carbon granules, each bead is mounted in an oil-filled cavity and can be rotated freely in these cavities. k Beads are two-color beads composed of two contrasting hemispheres that can be released. Electric dipole. After the voltage is applied to the surface of the electronic paper, the beads will rotate to show the viewer the color of the two color towels. Therefore, E-ink, which can pass through voltage and thief text and pictures, is another electronic paper made by E Ink. The company "EInk" has been purchased by Prime View International. LCD panels typically include two sheets of glass separated by a closed liquid crystal material. Both glass plates have a thin layer of conductive material transparent coating that is visually visible - the sides are in different hearts and the wires extend to the edge of the display II. The voltage between the front coating and the back coating disrupts the normal distribution of the molecules and darkens the liquid, creating a visually visible pattern. Furthermore, electronic displays are designed to detect whether they are touched and where they are touched (e.g., by a finger touch) or passive objects (e.g., a stylus or a digital pen). Such displays are commonly referred to as screens. The screen has been well-wired and the components of the electronic device are very illuminating. Touch can be included or included in a computer, network, mobile phone, video game, personal digital assistant (pDA), tablet or any digital device. A variety of technologies are currently used to produce devices with touch capabilities. Lai Wei's technology includes: resistive touch panel, surface acoustics 8 201246087 wave technology, capacitive sensing board (for example, using surface capacitance technology or projection capacitive touch technology, the latter using mutual capacitance sensor or self-capacitance sensing ), infrared, optical imaging, dispersive signal technology, and acoustic pulse recognition technology. The touch function can be combined with the electronic display in the device in a variety of configurations. The touch sensing circuit can be directly embedded in the display or mounted on multiple layers of the display (for example, using "in-line" or "on-ceii" methods), the circuits of these sensors are mounted on different substrates. Then, the substrate is bonded to the electronic display (for example, using an "out-cell" method), or bonded to a cover for protecting the electronic display, or the sensor's circuitry is directly embedded in the transparent cover. The back of the board ("Touch-on-Lens") The electronic device can be configured to include a variety of components and functions. This design is not difficult for professionals to understand, including: display, touch Screen, anti-friction cover (eg, transparent cover), storage device, wafer system, cpu core, GTpu core, memory, Wi-Fi connection device (for example, 902. 11 b. g), Bluetooth, connected devices (for example, USB connectors), camcorders, recorders, batteries (for example, built-in, rechargeable polymer 41 ion batteries), power connectors, computers, etc., software, etc. ‘In the description (4), an integrated sensor based on the disclosure information suitable for detecting fingerprints and a touch display currently used for devices such as smart phones are described. Such touch screens typically include a 9 cm (35 inch) small liquid crystal display (LCD) with an anti-friction glass layer. The capacitive touch screen of the LCD is usually optimized, and has the ability to sense the roots or the fingers of the town. However, the Rondo multi-face display, a variety of touch configurations, and touch devices do not deviate from the scope of this disclosure, and such designs are not difficult for professionals to understand. The LCD touch screen usually includes an LCD, a wire input/output (10). 201246087 A printed circuit board (PCB) for connecting and executing various functions of an integrated circuit (IC), and a touch-sensitive electric switch mounted on a transparent substrate And a protective layer or coating overlying the difficult circuit. The touch circuit and the LCD display are connected to the PCB. The touch circuit is usually embedded in the LCD or mounted on the LCD in the first method, and then over the LCD/touch screen group. Over the protective layer or coating (for example, a transparent cover) ). In the second method, the touch power is mounted on a mirror layer or a coating (for example, a cover plate), and the structure is mounted on the LCD above the touch circuit is mounted on the protective layer or the coating and the LQ. between. In all cases, the PCB touches the underlined position of the LCD. The biometric sensor can include a fingerprint sensor, a speed sensor, and an integrated circuit that is electrically coupled to the fingerprint sensor and the speed sensor. The biometric sensor can also include a sensor that is adapted and configured to take one or more parameters (e.g., a fingerprint). The conductive traces of the image sensor and the speed sensor can be formed on the upper side of the substrate by etching or other means, and a protective coating can be applied on the upper layer of the substrate, the image sensor and the speed sensor. To provide electrical insulation and mechanical protection of the sensor. In another method, the conductive trace of the image sensor can be formed on the bottom side of the substrate, and the plate can serve as a protective coating, and a hard coating layer can be added on the upper layer to further enhance the effect of the protective layer 4. For the fingerprint sensing Wei set, please refer to the "Finger, Grain Sensing Assembly and Manufacturing Method" (US Patent No., inventor Benkley ΠΙ) 'Brush Hole Electric Valley Fingerprint Sensing System and Method》 (US Patent No. Talk, inventor Benkley III), "Finger Placement Sensing Methods and Instruments" (US Patent No. 7'463'756 'Inventor Benkley m); "Electronic Fingerprint Sensor with Matching Noise Cancellation Function" ( US Patent No. 7, _, 697, inventor λ et al.); "Brush Capacitance Fingerprint Sensing System and Method i US Patent No. 7, _24, inventor EY 201246087 III); "Combined Fingerprint Acquisition and Control Equipment (US Patent No. 6,400,836, inventor Senior); and "combined fingerprint acquisition and control device" (US Patent No. 6,941, 〇〇 1, inventor Bolle). In the system disclosed herein, the fingerprint sensor is equipped with an electronic display placed at the uppermost layer or adjacent to the uppermost layer so that when the finger touches the uppermost layer of the system, the fingerprint sensor is located within about 1 mm of the finger. s position. In at least some configurations, the system can be configured to position the finger sensor about 8 microns from the finger when the finger touches the top layer of the system, such as being located at 600 microns, 550 microns from the finger. More preferably, it is in the range of 5 〇〇 micrometers, 4 〇〇 micrometers, 25 〇 micrometers, 200 micrometers, 150 micrometers, 100 micrometers or 5 micrometers. At least in some configurations, the system can be configured to position the finger sensor at a position 5 ft, 丨 (8) μm or more than 15 μm from the finger when the finger touches the top of the system' in some configurations. 'Configure the finger sensor to a position 2 μm above the finger'. In other configurations, the finger sensor is configured to be 25 μm, 400 μm, 5 μm, 55 μm, 6〇 from the finger. 〇Micron or a position above 8〇〇 microns. In some configurations, a single wafer can be provided that controls one or more of the electronic display, touch screen, and fingerprint sensing functions. In addition, fingerprint sensing can make the surface smooth or generally smooth. The ageing device and the secret can be configured in a unitary form, the operation of the 'or electronic display II' or the finished system of the system consisting of a single element. The texture sensing n can be placed under all or part of the protective layer, under the ink mask, or under the protective layer and ink mask. 1A and 1B are top or top views of an electronic device 100. The clefts can be any suitable electronic device, such as a smart phone, having a user-touchable device or display 201246087 interface 120. Depending on the device used and the nature of the display, _ Na from (4) (4) _ will be discussed in further detail below. The device itself has a top surface 102 and a bottom surface 1〇4. In addition, each of the lower-lower parts of the device has an upper layer (i.e., a surface facing the top surface of the device) and a lower layer (i.e., a surface facing the bottom surface of the device) which are visible from the cross-sectional view. The electronics housing (10) can be configured to interface with the display! 20 Fixed in electronic money (10) nuclear 11G _ border or miscellaneous m. A mask m (e.g., ink mask) may be provided' at least a portion of the display interface 12A is placed in its frame. The mask 124 inspection typically covers the device electronics located within the housing of a portion of the display interface 12A. For the touch screen interface, a portion of the display interface 12G that is not covered by the mask 124 has a plurality of touch sensors 134. The touch sensor 134 can be any suitable conductor from an indium tin oxide (IT〇) layer, a carbon nanotube, a metal, an inner conductor conductive compound, or a thin metal wire (eg, a copper wire). Including a transparent conductor. Further, at least the health fingerprint sensor 140 of the 'near electronic device' may be placed (as shown here, but not necessarily) at a position where the mask 124 is placed at the same time. In another configuration, A hole 35 is provided in the mask corresponding to a portion or all of the position where the fingerprint is sensed. The fingerprint sensor 14A may include a brushing or placement area 146, for example, where the user can swipe a finger or The finger is placed and then read by the fingerprint sensor 140 in a one-dimensional (1D) or two-dimensional (2D) manner. As shown in FIG. 1 , the position of the fingerprint sensor 140 and the touch sensor 134 are Partially overlapping. In some configurations, the fingerprint sensor 14A and the sensor of the touch sensor 134 are integrated together 'the sensor constitutes a whole piece, or its composition can be operated in a unified manner, the sensor Some parts of the device are adapted to have a touch sensor 12 201246087 =, 'Other - part is adapted to have the function of fingerprint: Wei:::=. However, the feeling does not need to put 2 graphics under = 'If the image scan line is directly placed in the "swipe to unlock" use If the fingerprints match, the user will be allowed to unlock the ship. Otherwise, and using the 3=1 design is not difficult to understand for a dedicated tAM. Other configuration ranges. ; #人8 is also very clear 'and does not deviate from the disclosure information f 2A map and 2B map is a cross-sectional view of the electronic device, such as the first picture = electronic touch ' along the 1A map and 1B _ M line shooting, display | face 220 placed along the upper layer of the device. There are two common cross-sectional configurations, but there are other configurations. In the first configuration shown in Figure 2A, the fingerprint sensor is placed on the permeable cover, 'below 疋—a touch sensing ^ and The rest of the device includes an electronic display. In the second configuration of the second embodiment, the pointing device is placed at the top of the transparent cover, the touch sensor is placed on the back (lower side) of the transparent cover, and the rest of the display and the t-mount are installed below. . One or more components can be configured into modules, and the four designs are not difficult for a professional to understand. The modules can be configured to be interchangeable components that can be exchanged with other components for assembly into different sizes, complexity or functions. The electronic device 200 includes a housing 21, a printed circuit board (pCB) 23A, and an electronic display 228, such as a [CD or LCD module. The device may also include a touch sensor 235 component, such as a glass layer, to which a conductive layer (e.g., steel tin oxide (ITO) or the like) may be applied to form a touch circuit. It is possible to form a pattern on the surface of the glass layer by the conductive layer, which is not difficult to understand for the professional 13 201246087. As shown in FIG. 2A, the first conductive layer 234 covers the second conductive layer of the upper layer 206' read by the touch sensor 253, and covers the lower layer 208 of the touch sensor. The transparent cover 238 can be constructed of a suitable material, including chemically strengthened glass. The touch circuit controller 226 is connected to a touch circuit or a digital converter, and the digital converter can be formed by the flexible circuit 232 using a conductive layer of the touch circuit device. The touch circuit controller 226 is mounted on the pCB 23A. The electronic frequency converter 228 is placed below the transparent cover 238 and above the pcB 23 。. The electronic display (10) includes a glass layer and any other components required to implement the power display, including logic. As shown here, fingerprint sensor 240 is completely placed under (but not necessarily) under cover 224. Fingerprint sensor 240 is shown coupled to fingerprint sensor controller 262 via flexible connector 26A. However, it is not difficult to understand that a design can be configured with an integrated circuit, a control circuit and a fingerprint sensor without departing from the scope of the disclosure. A protective layer 222 (e.g., a protective glass layer) is placed over fingerprint sensor 240 and electronic display 228. The fingerprint sensor 240 senses a finger fingerprint feature that is swept or placed on the surface of the protective layer on the surface of the protective layer 222 near the fingerprint sensor 240. The protective layer 222 and the display layer of the electronic display 228 can be constructed of any suitable electrically non-conductive material (e.g., glass, PET, or a suitable hard coating). The fingerprint sensor 240 is adapted and configured to sense the embossing and indentation or fingerprint parameters of the user's fingers within the target distance of the device surface. The target distance is no more than 1 mm, 800 microns, 600 microns, 550 microns, 500 microns, 400 microns, 250 microns, 200 microns; at least in some configurations, it is configured to be no more than 150 microns, 1 inch or 50 microns. At least in some configurations, the target distance can exceed 50 microns, 100 microns, 150 microns, 2 microns, 250 micro 14 201246087 ^ 00 micro to 500 micro, 550 micron, 6 〇〇 micro-coffee sensor can also _ Other records, the section will deviate from the details of the disclosure information, and Figure 2B depicts the alternative profile of the device shown in Figure 1A. The electrical package includes a housing 21 with a bezel or edge 212, a pcB 23 and a set. If the touch function is included, the electronic device 2gg can also be equipped with a lower layer of the transparent cover 238. The electronic device 200 < secures the protective layer 222 placed over the transparent cover 238. The touch circuit=system (4) is connected to the PCB through the flexible circuit or _232 and the conductive layer connector controller 262, and is placed on the lower part of the electronic display with the position 240 placed near the upper layer of the transparent cover, adapted and configured as Finger fingerprint features that are brushed or placed on the surface of the protective layer on the surface of the protective layer 222 near the fingerprint sensor can be sensed. The top view of the 32疋 interface (viewed from the upper layer 3〇2), the display has a mask 324 layer, the flexible portion 332 is adapted and configured to be with the conductor and the appropriate integrated circuit (1C) ), specific application of integrated circuit (fiber) or wafer connectivity. 4A and 4B are exploded views of the display farm shown in Figs. 2A and 2B. The first layer of Figure 4A includes a PCB43G layer with one or more controllers. In a configuration, all controllers are put together; in another configuration, different controllers are placed at opposite ends along a section of the PCB layer; other configurations may be used instead of revealing information. range. The control ^ can be one or more integrated circuit chips, adapted and controlled by itself - one or more devices, such as display and fingerprint sensing, as shown in Figure 4A, with an integrated controller for the touch screen 426 'Equipped with an integrated circuit 462 for the fingerprint sensor, the portion U of the pcb 43 layer is the electronic display 428 layer. If the device includes touch function 201246087, the next layer is the touch screen layer 435. As shown in this configuration diagram, the touch screen layer is provided with the first conductive layer on the first layer (upper layer 406) of the touch screen layer. 434, a second conductive layer 434 is mounted on the second layer (lower layer 408) of the touch screen layer. The fingerprint sensor 440 can be placed on the upper layer 4 of the transparent cover 438, partially or completely covered by the mask layer 424, and the mask layer selectively covers the transparent cover 438. The entire assembly is covered by a protective layer 422. Other layered configurations can also be used without departing from the scope of this disclosure. Figure 4B also has a first layer that includes a PCB 430 layer with one or more controllers installed. The controller can be one or more integrated circuit chips that are adapted and configured to control one or more displays, touch sensors, fingerprint sensors, and the like. As shown in Fig. 4B, an integrated controller 426 is provided for the touch screen, and an integrated circuit 462 is provided for the fingerprint sensor. The next layer is the 428 layer of the electronic display. If the device has a touch function, the next layer is a touch screen layer 435. As shown in this configuration diagram, the touch screen layer has a first conductive layer 434 on the second layer (lower layer 408) and is directly mounted on the transparent layer. On the cover. Fingerprint sensor 440 is placed at the upper layer 406 of transparent cover 438 and may be partially or fully covered by mask layer 424. The mask layer 424 can also be configured to have an aperture 425 corresponding to the fingerprint sensor over all or a portion of the display. entire.  A protective layer 422 is mounted on the assembly. _ Figure 5A shows the stratification of the fingerprint sensor 54. As described above, the fingerprint sensor can be adapted and configured to be integrated with the display, with an upper layer 5〇2 and a lower layer 504. The fingerprint sensor 540 is shown in the transverse wear surface along line 2_2 in Figures 1A and 1B. Fingerprint sensor 540 has a patterned conductor layer 548. The uppermost layer is a flexible film that functions as a protective layer 564. A suitable film may be polyethylene terephthalate (PET) or any suitable hardened thermoplastic polymer resin. The 201246087 film may have a hard coat. The film has a thickness of less than 5 microns so that the fingerprint sensor 540 operates effectively. A mask 524 is placed on the bottom layer 5 of the film and placed on the film of the lower (bottom) layer. Mask 524 may be a suitable ink layer. The next layer forms part of the ridge sensor 540, which is a conductive layer, typically a transparent conductor or a patterned transparent conductor (i.e., conductor layer 548). The transparent conductor (i.e., conductor layer 548) constitutes the first metal layer and may be formed of any suitable guide material, including indium tin oxide (ITO), carbon nanotubes or fine metal. The second metal layer (i.e., the conductor layer 5) may partially overlap at least the first metal layer (i.e., conductor layer 548). The conductor layer 548, =8, is located on the bottom surface of the film (toward the inside). In some of the finger sensor configurations with displays, the optical coating can be added to reduce or prevent reflections and assist in covering the conductive layer. The adhesive layer 552 adheres the conductor layer 548 of the fingerprint sensor 540, the film, and the mask to the transparent cover 538. The adhesive layer 552 is typically an optically clear adhesive. The second gold wu flexible _ road' film 522 can be covered by a transparent cover plate, and a second metal layer (ie, conductor layer 548) can be formed in electrical communication, and the cable has a flexible circuit 5 Crystal (10). The replaceability circuit 560 and the chip 562 can be used as a flip-chip film (c〇f) to provide direct micro-and micro-transistors (9), which can be connected to two metal layers and then mounted to the assembly device as required. ;: Through the flexible keys, the Wei has set a private scope. This kind of...+ does not go beyond the disclosure of information. It is not difficult for professionals to turn around. Body 548 and touch glory constitute A whole. Centering, the 2A diagram and the 2B diagram are displayed in a manner. However, the ^ sensor can be configured according to the first levisable circuit, instead of the c〇f configuration, this mei can be used to understand. No. 201246087 Figure 5B depicts the configuration shown in Figure 5A, in which the film cover and conductive layer are placed. Then, the second conductive layer is placed for the coating. Can be placed on the surface of the film or another suitable surface 2: Learn first ^ After this, the transparent cover can be glued to the optical coating or conductive layer, and then connect the coffee and conductive layer to the power supply. (10) Through (4) steps can be This method of connecting the coffee is not difficult for the professional to understand. In some of the plates, the _ sigh _ can be used to make the _ along the transparent cover around the f, in the device housing. Then the entire device Loading the device housing 510, the upper layer should be aligned with the upper layer of the housing, or with the entire display Alignment, as shown in Figure 2A. Figure 6A shows the fingerprint sensor 64A with two metal layers on the top of the film. The first layer is a protective layer 'such as hard coat 622. The thickness of the hard coat is less than 5〇. Micron, so that the fingerprint sensor operates effectively. The mask 624 is placed near the bottom layer of the film or under the film bottom layer. The mask 624 can serve as a suitable ink layer. The first conductive layer (ie, the conductor layer 648) is then placed. (10) Typically the transmissive or patterned transparent conductor transparent conductor (ie, conductor layer 648) constitutes the first metal layer and may be constructed of any suitable electrically conductive material, including indium tin oxide (10)), carbon nanotubes or fine metals. The layer is located at the bottom (toward the inner) position. A second conductive layer (ie, conductor layer 648') is formed. The conductive layer is connected to the first conductive layer. The second conductive layer may be associated with a suitable transparent conductor (eg, copper). The film layer 664 is adhered to the transparent cover 638 of the display through a layer of adhesive (ie, the adhesive layer 652). The adhesive layer 652 is usually optically transparent. As shown, it can be used in electrical communication. Forming a second metal layer That is, the conductor layer 648') has a flexible circuit 66A and a wafer 662. The flexible circuit 66 can be placed on the upper end of the second metal layer (i.e., the conductor layer 648). The towel layer and the conductor layer (10) are finely controlled to touch the whole body. 201246087 Fig. 6B shows the condition of each layer of Fig. 6A in the device casing 61. The film layer 664, the flexible circuit 660, the mouth wafer 662 can be along the transparent cover The plate (10) and the like are bent to place the wafer into the device housing. The transparent cover 638 may have a rounded edge so that the film layer 664 is bent along the transparent cover. When the component is assembled, the conductor is placed into the transparent plastic film. The (PET) layer 'the second body layer is placed on top of the first portion of the first conductor layer. Then add a mask and a protective layer. Thereafter, the glass plate or transparent cover of the display can be adhered to the bottom layer of the adhesive, and the flexible circuit can be bonded to the upper layer of the second conductive layer. Fig. 7A shows the layered mud of the fingerprint sensor 74. The fingerprint sensor has a flexible transparent body on the bottom surface of the film. The first layer is a thief, such as ρΕτ, and the top of the film has a hard coat 722. The thickness of the film does not exceed 25 μm for the fingerprint sensor to operate effectively. The thickness of the film is not more than that of micron, 15 μm or micron. The thin profit is no more than 50 «best. Next, add _ 724, which can be placed on the top film ’ toward the shock casing and facing away from the outside of the device. Mask 724 may be a suitable ink layer. A conductive layer 748 of flexible material is provided along the table, and the conductive layer is usually a sense conductor or a transparent conductor. The conductive layer can be secreted by a suitable age-sensitive conductive material, including carbon nanotubes, metal wires, conductive polymers, and fine metals. The conductive layer is located at the bottom of the film (toward the (four) side). An anti-reflective or refractive 2-coating layer 750 can be added to the beta cover 738, film or other suitable skin. Adhesive layer 752 bonds the film, patterned conductor and ink to the glass cover', typically a wire flip. A conductive layer can be formed in the Wei communication. The conductive layer is provided with a levisable circuit and a wafer 762. The flexible circuit 760 is connected to the wafer via a flexible circuit on the bottom surface of the conductive layer. Figure 7 depicts the sensor 740 in the outer casing 710 shown in Figure 7 layered 201246087. When assembling the component, a mask is placed over the film and the conductor is then mounted to the film and mask layer. Thereafter, the glass cover or transparent cover of the display can be attached to the bottom layer of the transparent plastic film, and the flexible circuit can be bonded to the upper layer of the conductive layer. Figure 8A shows the stratification of fingerprint sensor 840, which has a flexible transparent conductor on the upper side of the film. Equipped with a hard coat 822, the hard coat position.  Above the mask 824. A patterned flexible material conductive layer 848 is provided that is in electrical communication with the COF assembly comprised of flexible circuit 860 and wafer 862. A transparent plastic film 864 (such as a PET layer) is also provided, which can be adhered to the glass cover or transparent cover 838 using adhesive 852. Figure 8B depicts the stratification of fingerprint sensor 840 within housing 810 as shown in Figure 8A. When assembling the component, place the conductor on a transparent plastic film (pET). Then add a mask and a protective layer or hard coat. Thereafter, the glass cover or transparent cover of the display can be attached to the bottom layer of the transparent plastic film, and the flexible circuit can be bonded to the upper layer of the conductive layer. Figure 9A shows the layered condition of the fingerprint sensor 94A suitable for integration with the display. An ultra-thin glass layer 923 is placed over the mask 924. A patterned conductive material conductive layer 948 is then placed. The patterned conductive layer 948 is transmitted through the anisotropic conductive film.  (ACF) 966 is in communication with the flexible circuit assembly. The flexible circuit assembly includes a flexible circuit 960 and a wafer 962. A transparent cover 938 is placed between the patterned conductive layer 948 and the wafer 962. The transparent cover is bonded to the conductive layer by a suitable adhesive 952 (e.g., optically transparent adhesive). The flexible circuit assembly is configured to bend along the end of the glass cover. In this configuration, the existing flexible circuit can be used in polyimide technology and then placed under the ink mask 924. Figure 9B depicts the fingerprint sensor placement in the housing 910 as shown in Figure 9A. When assembling the component, place a mask on the bottom of the ultra-thin glass layer. Then, a conductive layer is placed on the ultra-thin glass/mask combination layer. The woven fabric is then adhered to the surface layer of the c〇f-layer anisotropic film. Then stick the glass plate or transparent cover to the conductive layer on the conductive layer. The COT can be placed at the end of the transparent cover. - 帛 1GA _ shows the stratification of the fingerprint sensor 1040 formed by placing a brittle conductor on the transparent cover. Add a hard coat 1〇23 to the mask 1〇24. A flat polishing layer 1068 can also be added. The flexible circuit assembly includes a flexible circuit connector 1060 and a wafer leg. One end of the flexible circuit connector is connected to a glass cover or a transparent cover 1038, and a transparent cover or glass cover has been mounted through the ACF to form a conductive layer 1048. Further, Fig. 10B depicts the hierarchical shape of the fingerprint sensor placed in the casing 1〇1 shown in the first item. When assembling the component, the upper layer of the transparent cover is provided with a conductive layer. The ACF is mounted on the end of the conductive layer on the COT flexible circuit. • A flat polishing layer can be placed on the upper layer, followed by a mask layer and a protective hard coat layer. The flexible circuit surrounds the transparent cover to place the circuit under the transparent cover inside the unit's casing. Figure 11 shows the portion of the display. The display uses printed conductors 1134 (e.g., metal wires) around the display transparent cover 1138.

Fig. 12A shows the state in which the surrounding wires are attached by the direct built-in method of the fingerprint sensor 1240. A protective layer (e.g., hard coat 1223) is placed over the mask 1224. A planar polishing layer 1268 can also be used to place the planar polishing layer over the patterned conductive layer lug. One end of the transparent cover 1238 is surrounded by a wire 1234 having a flexible circuit 1260 on which a wafer 1262 is mounted through the ACF. i2B 21 201246087 The diagram depicts the stratification condition in the casing πιο shown in Fig. 12A. Fig. 13 shows the state in which the surrounding wires are used in accordance with the ultra-thin glass method of the fingerprint sensor 134〇. A protective layer, such as ultra-thin glass 1322, is provided which is overlying the mask 13M. The patterned conductive layer is placed on the optional optical coating. A transparent cover 1338 with a display has printed surrounding wires. The transparent cover can be adhered to the optical coating 135〇 (if any), the patterned conductive layer, the mask and the ultra-thin glass with adhesive 1352. The flexible circuit 136 with the wafer 1362 can be connected to the surrounding wire of the cover glass or transparent cover by the ACF 1366. 1st map depicts the stratification in the enclosure shown in Figure 13A. Figure 14 shows the configuration of the fingerprint sensor with a thin layer of glass and a transparent flexible circuit. A thin glass layer 1423 is used as the first layer. A mask 1424 can be placed on the bottom layer of the thin glass layer 1423. _ A layer of duck glue 1452 is added between the thin glass layer and the transparent plastic layer 1464. In some locations, the transparent adhesive 1452 will contact one or more of the transparent sensors 1434, the traversable circuit, and the clear plastic layer 1464. The transparent plastic layer 1464 can be configured to wrap around the end of the transparent cover 1438 (as shown) or to extend to the outer two-dimensional geometry of the transparent cover. It is also possible to add a layer of glue 1439 below the layer of the plate 1438. A transparent device 1434 (eg, a sensing n made of a transparent conductor) is connected to or connected to a flexible circuit that surrounds the end of the cover plate 1438, and can be placed at the end of the cover plate. The rib circuit can be a transparent flexible circuit through the ACF 1466 and the surrounding wire of the glass cover or the transparent cover. In addition, the transparent conductor can be combined with a tractable circuit. As with the previous configuration, the entire electronics interface can be placed in a suitable electronic light enclosure. Fingerprint feel · 1440 available copper or another type 22 201246087 side; you can choose to use the same surface layer or . In at least some configurations, the touch conductor is formed below the ink mask 1424; an additional surface layer is formed with a transparent touch sensor 1435. The sensor and fingerprint sensor are placed on the same layer. In some configurations, the flexible circuit 1448 and the fingerprint sensor 1440 can be constructed of copper circuitry to form a transparent touch sensor with a transparent conductor. Figure 15 is a diagram 150 = of a sensing device _ configured for use with a display device. The apparatus also includes a basic fine senser control logic 1552 configured to control the sensor elements. The actual operation of the sensor elements constrained by the sensor logic control depends on the particular tone sensing device employed, and may include electrical relays, pixel reset controls or data contacts, output signal controls, certain optics The sensor's cooling control device and other basic control weaving of the ❹m component. Control relay

A linear array 1512 and a sensor element sensing device are further included to include a read circuit (5) 4 for reading from the sensor element 15() 2 when reading a fingerprint juxtaposed on the sensor surface 1507. The analog output signal two read circuit 1554 includes an amplifier (10) configured to amplify the analog decidate 'to read the signal more accurately in subsequent operations. A low pass 1 1558 ’ can be configured to transition any noise from the analog signal to more efficiently process the analog signal. The read circuit 1554 can also include an analog/digital (A/D) converter 1560' that is configured to convert the output signal from the sensor element to a health number, which represents _ series 0 and 丨, Fingerprint feature sensing is defined for pixel material contact points that pass through the surface of the sensor. Such U can be received by the motion sensing II and the fingerprint sensing surface, and read and read separately. 23 201246087 The reading circuit 1554 can store the output signal in the storage 1562, and the fingerprint data i564 is temporarily stored and stored in the storage. , or saved to the processor 1566 can process the signal, or later for processing. Processor 1566 includes an arithmetic unit configured to process algorithms for cursor navigation and fingerprint reconstruction. Processing logic 1570 is configured to process information and to ride on digital converters, amplifiers, signal filters, logic gates (both not shown), and other logic used by the processor. The software application 1578 used by the 1574 thief 1574 threatening algorithm 1576 domain processor 1566 is used for the various functions described above, as explained in more detail below. The line flow is a gambling gamble, configured to initiate communication of various components contained in the 15GG of the sensing device. The memory and storage can be any suitable computer readable ship, which is difficult for professionals to make. The system also includes a controller in communication with the fingerprint sensor circuitry to capture a fingerprint image when the user's finger is fingerprinting on the fingerprint or _ thief. Therefore, the system can be equipped with 1D and/or 2D flashing fingers or fingerprints. In a system, it is possible that the display and the fingerprint sensor have no control, and in this system, the system is configured to include a display control, a visual display that separates the control from the test. Another method is to make the (four)-health (four) (four) visible display and fingerprint sensor operation. It is also possible to place the fingerprint sensor on the top glass cover of the display, rather than on the touchscreen. Figure I6 shows the use of fingerprint sensors in accordance with the disclosure information in the communication network. Current disclosures may also include a variety of functions within a communication network implemented by a computer processor (e.g., a microprocessor) that is specifically understood. Micro-processing can be a full-time processing of H, configured to expose the pre-existing task of 2012-0487 facet (4). Micro-processing n (4) is set to operate other devices, such as memory access module, memory storage, /, /, '" set, body and related to the information transmission according to the disclosure Mei soft, format, such as, / coffee, C + +, Wei (Extensible Markup Language) Sexual operation ^ ^ meaning related to the operation of the device, the implementation of the function related to the disclosure of the information. The code can be language and style (4) /, I know well. Different code formats, code configurations, styles and forms of software programs, and other disclosures: the method of configuring the code for the operation of the processor does not deviate from the spirit and scope of the disclosure. ...in a non-type device, such as a laptop or desktop computer, with a processing: or a hand-held device that handles miscellaneous items, and may include computer data, other devices that use information to disclose information. There are a variety of (4) devices that can be stored and Retrieve the information while performing the function according to the disclosure information. Such t-brain wipes include a cache memory i, and central processing H makes it a convenient storage location for storing and retrieving information frequently. In contrast, the permanent memory has also been used in such electrical occupations to store information that is centrally processed for routine search but not often changed in permanent memory. This is different from cache memory. It also typically includes main memory for storing and storing a larger amount of information, for example, configured to execute the Wei (4) material and the program according to the disclosure information when the central processor executes the instruction. Such memory can be configured to rely on access memory (RAM), static random access memory (jSRAM), dynamic random access memory (dram), flash memory, and other potentially broken central processor accesses. A memory storage device for storing and retrieving information. These memory devices are changed to have different 25 201246087 states during data storage and retrieval operations, such as different charges, different magnetic poles, and the like. Accordingly, the systems and methods described herein in accordance with the disclosed configuration enable physical changes to such memory devices to be monthly b. Accordingly, the disclosures described herein are applicable to novel and useful systems and methods in which a memory device can be changed to another state. The disclosure is not limited to any particular type of memory device or any procedure commonly used to store and retrieve information from such memory. One or more sets of private media or multiple media (eg, centralized or distributed repositories and/or associated caches and servers) can be used. Any medium (e.g., computer readable medium) capable of storing, encoding, or equipping a set of instructions for the machine to perform and causing the machine to perform any one or more of the disclosed information descriptions is suitable for use herein. The machine readable medium or electrographically readable medium also includes any mechanism that is provided (i.e., stored and/or transmitted) in the form of a machine (i.e., computer, pda, cell phone, etc.). For example, a machine-readable medium includes § memory (such as the memory described above); magnetic disk storage media; optical storage media; flash memory devices; bioelectronics, mechanical systems; electrical, optical, acoustic, or other forms of communication Signal (eg, carrier, infrared, digital, etc.). The device or machine readable medium can include a microelectromechanical system (10) MS), a nanotechnology, an organic, a holographic, a blister, and a money thief optical disk. The d-south sub-segment can be distributed with different machines II, such as in an interconnected computer or as a different virtual computer. In addition, computer readable media can be placed anywhere within the network. The 16th _ shows - finer than the demonstration _ road calculation Wei Cong, in this environment there is a ship that communicates with the client computer through the communication _ 165G. As shown in Figure 16, the feeder 1610 can be deleted via a communication network (but fixed line or wireless LAN, WAN, intranet, extranet, peer-to-peer or a combination of such networks) 26 201246087 】^^= 6 environments (such as tablet computer, mobile phone, smart phone personal computer 1603 and personal digital assistant 608) are interconnected.职(四)咖转网_路赖路魏辄器1610 乍 乍 专 专 专 专 专 专 专 专 专 16 16 16 16 16 ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( ( Object Access Protocol (SOAP) or Wireless Protocol (wAp) processes data, transmits to the customer environment (4), and receives data from the client environment. Other wireless protocols can also be used without exceeding the scope of the disclosure information. Including Wireless Markup Language (WML), DoCoMo Café (used in Japan, etc.) and Lisboa Basic. In addition, the network computing environment can use various data security protocols, such as Secure Communication Layer (SSL) or good security. Protocol (pGp). Each client computing environment sentence can be equipped to support one or more computing applications (such as web browser (not shown) or other graphical user interface (not shown) or mobile desktop environment (not The operating system 1638 is shown to access the server computing environment. The communication device with the display device (eg, computer deleted, smart phone 1604, and PDA 1608) can be configured as The data is obtained from the fingerprint sensor according to the above method. This design is not difficult for the professional to understand. In addition, the information from the fingerprint sensor can be transmitted to other devices in the network to assist in the network environment. User authentication, regardless of whether the receiving device has a display. The device disclosed herein can be used as part of a communication network to provide a mechanism for biometric information, such as 'sensing biometrics associated with a certain user. Information; the sensed information can then be compared with the biometric template associated with the user; if the biometric information matches the biometric template, the credentials associated with the user can be received based on the biometric information. Transfer the credentials to the 27 201246087 requester. In another program, the biometrics installed in the client device with the secret application can be identified. After that, the biometric M related to a certain user can be identified. And creating a biometric related to the biometric information of the user, and the template system can be set to receive the same as the (4) According to the combination, the user's credentials are combined with the biometric template. The device can also be executed on the disclosed device. The device includes a configuration for transmitting biometric services and/or multiple stations. The network player and the exposed biometric extension unit of the communication and communication. The token activation can also be used to activate the time, as the use of the integrated sensor can help the use of the network drama program. The application knowledge is configured on the client device to be executable by the client processor to assist in secure transactions, such as financial transactions, which can be authenticated by integrating information obtained by the sensor (eg, exposed sensors). The official display and description of the invention is shown here. For professionals, 'such devices (4) are only used as examples. The specialists can use a variety of variations, alterations and alternatives instead of It will depart from the scope of the invention. It should be noted that the various (fourth) generations of the bribes that were placed here may appear in the application. The following statements are intended to define the scope of the invention and the methods and structures in the scope of the claims [Simple description of the diagram] The top view and the m (4) top view of the electronic device equipped with electronic display. Figures 2A and 2B are the 1A and mth drawings (cross-sectional view of the line device, showing the integration of different fingerprint sensors. Figure 3 shows the H-face, the axis is covered The cover layer and the assembly 28 201246087 and the configuration to connect the wafer to the inner surface of the outer casing can be exploded. Figure 4B is a schematic diagram of the display knife shown in Fig. 2A and Fig. 2; Figure 5A shows the stratification of the fingerprint flipper with two layers of conductors at the bottom of the film. The schematic diagram of the layered domain is a subtle diagram of the 5A diagram. The sixth diagram shows the stratification of the fingerprint _ of the two layers of conductors at the top of the film. Figure 6 is a schematic diagram of the state of the 6th layer of the fingerprint sensor near the wall of the device. Figure 7 is a schematic diagram of the layered condition of a flexible transparent conductor at the bottom of the film. The layered shape of the domain 峨 峨 细 细 细 细 细 = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = = =9A is a fingerprint sensing using ultra-thin glass Schematic diagram of the stratification situation. Schematic diagram of the layer condition. The sub-figure map _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ _ 29 201246087

Figure 10B is a schematic diagram showing the ancestor stratification of the fingerprint sensor as it approaches the wall of the device housing. J “ =11 is a part of the display, which is printed on the edge of the cover using printed metal wires. The figure is a schematic diagram of the condition of using the surrounding wires in the direct build-up method. Figure 12B shows the fingerprint sensor in the vicinity of the device case. Schematic diagram of the stratification of the figure in the position of the wall. Figure 13A is a schematic diagram of the condition of using the surrounding wire in the ultra-thin glass method. The figure is the stratification of the μ map when the sensor is adjacent to the wall of the casing. The figure is a schematic diagram of the stratification status of the other type of fingerprint (four) device configuration. The first picture shows the status of the device with the display of I with the display of I. Figure 16 shows the information in the communication network. Status indication β ° [Main component symbol description] 100, 200 electronic device 102 top surface 104 bottom surface 110, 210 housing 112, 212 edge 120 > 220 display interface 124, 224, 324 mask 134 ' 235 touch sense Detector 201246087 140, 240, 440 fingerprint sensor 146 placement area 206, 302, 406 upper layer 208 ' 408 lower layer 222 '422 protective layer 226 touch circuit controller 228 '428 electronic Display 230, 430 Printed Circuit Board 232 Flexible Circuits 234, 234, Conductive Layers 238, 438 Transparent Cover 260 Flexible Joint 262 Fingerprint Sensor Controller 320 Display Interface 332 Flexible Port 424 Mask Layer 425 Pore 426 integrated controller 434, 434, conductive layer 435 touch screen layer 462 integrated circuit 502 upper layer 504 lower layer 508 film bottom layer 31 201246087 510, 610, 522 524, 624, 538, 638, 540, 640, 548, 548, 550 552 560 , 660 , 562 , 662 , 564 622 , 722 , 648 , 648 ' 652 ' 752 664 748 , 848 , 750 810 , 910 , 824 , 924 , 838 > 938 > 840 , 940 , 852 ' 952 ' 860, 960, 862, 962, outer casing film cover transparent cover fingerprint sensor conductor layer optical coating adhesive layer flexible circuit wafer protective layer hard coating conductor layer adhesive layer film layer conductive layer coating shell cover Cover transparent cover fingerprint sensing adhesive flexible circuit chip 32 201246087 864 923 966, 1023 1048 1060 1068 1134 1138 1210 1224 1240 1262 1322 1350 1360 1423 1434 1435 1438 1448 1452 1464 Transparent plastic film ultra-thin glass layer 1066, 1366 isotropic conductive film, 1223 hard coating, 1248, 1348 conductive layer flexible circuit connector, 1268 flat polished layer, 1234 wire, 1238, 1338 transparent cover Enclosure, 1324, 1424 mask, 1340, 1440 fingerprint sensor, 1362, 1462 wafer ultra-thin glass optical coating flexible circuit thin glass layer transparent sensor transparent touch sensor transparent cover flexible circuit 1439 Adhesive transparent plastic layer anisotropic conductive film 33 1466 201246087 1500 Sensing device 1502 Sensor component 1507 Sensor surface 1512 Linear array 1552 Sensor control logic 1554 Read circuit 1556 Amplifier 1558 Low pass filter, wave 1560 Converter 1562 Memory 1564 Fingerprint 1566 Processor 1568 Unit 1570 Processing Logic 1574 Resident Memory 1576 Algorithm 1578 Software Application 1580 System Bus 1600 Network Computing Environment 1602 Tablet 1603 Personal Computer 1604 Smart Phone 1606 Telephone 1608 Personal digital assistant 34 201246087 1610 1 638 1650 Server Operating System Communication Network 35

Claims (1)

201246087 VII. Patent application scope: 1. A fingerprint sensor comprises: a sensor disposed at a position within a range of less than 丨m from an uppermost layer of an electronic display; and a controller connected to the sensor, For capturing a fingerprint parameter 'where the controller is disposed on the lower layer of the electronic display; wherein the sensor is placed in the electronic display and located between a transparent cover and a protective layer. 2. The fingerprint sensor of claim 1, wherein the electronic display further comprises a touch sensor. 3. The fingerprint sensor of claim 2, wherein the touch sensor is controlled by a touch sensor controller. 4. The fingerprint sensor of claim 1, wherein the controller is further coupled to a touch sensor. 5. The fingerprint sensor of claim 1, further comprising a mask layer' having an upper layer adjacent to the protective layer. 6. The fingerprint sensor of claim 5, wherein one of the conductive layers is disposed on the bottom layer of the mask layer, the mask layer is disposed on the lower layer of the protective layer. 7. The fingerprint sensor of claim 5, wherein the mask layer further comprises a fingerprint sensing area indicator. 8. The fingerprint sensor of claim 1, wherein the control device is a flip chip. 9. The fingerprint sensor of claim 1, wherein the sensor comprises at least one electrically conductive layer. The fingerprint sensor of claim 9 wherein the conductive layer is selected from the group consisting of indium tin oxide, carbon nanotubes, metal nanowires, transparent conductive agglomerates, and fine metals. One or more of them. 11. The fingerprint sensor of claim 9, wherein the conductive screen is a flexible material. 9 12. The fingerprint sensor of claim 1, further comprising one or more flat layers, an optical coating, an optically clear adhesive, a transparent plastic film, and a hard coat layer. 13. The fingerprint sensor of claim 1, wherein the protective layer is selected from the group consisting of ultra-thin glass and poly-p-dicarboxylic acid. The fingerprint sensor of claim 13, wherein the protective layer has a hard coat layer. 15. The fingerprint sensor of claim 2, wherein the fingerprint sensor further comprises a conductive layer, the touch sensor further comprising a conductive layer, wherein the conductive layer of the fingerprint sensor The conductive layer of the touch sensor is formed as a whole. The electronic display comprises: an electronic display module for generating a visible display; a protective layer located above the electronic display module and for long-term contact with the surface of the user's finger; a fingerprint sensor; And controlling the controller to be connected to the fingerprint sensor for capturing a fingerprint parameter when sensing the finger. The electronic display of claim 16 further comprising a motion sensor </ RTI> for detecting a finger movement condition on the fingerprint sensor. 18. The electronic display of claim 16 further comprising a presence sensor 37 201246087 for detecting a finger placed on the fingerprint sensor. 19. The electronic display of claim 16 further comprising a display controller coupled to the electronic display module for not displaying the visible display of the electronic display module. Control 20. The electronic display of claim 19, wherein. The controller is also connected to the fingerprint sensor and used to control the fingerprint sensor. The electronic display H according to claim 16, wherein the finger further comprises a conductive layer disposed under a mask layer, and the cover layer is located at a bottom layer of the protective layer . The electronic display of claim 21, comprising the fingerprint sensing area indicator. 23. The electronic display of claim 16, wherein the flip chip is laminated. 24. The electronic display of claim 16, wherein the detector comprises at least one electrically conductive layer. The electronic display of claim 24, wherein the conductive layer is selected from the group consisting of indium tin oxide, carbon nanotubes, metal nano-transistors, transparent conductive polymers, and fine metals. 26. The electronic display of claim 1 wherein the electrically conductive layer is a flexible material. The electronic display of claim 16 further comprising one or more flat layers, an optical coating, an optically clear dispensing, a transparent plastic film, and a hard coating. The electronic display of claim 16, wherein the protective layer is selected from the group consisting of ultra-thin glass and poly-p-xylene-group combinations. The electronic display of claim 28, wherein the protective layer has a hard coat layer. 30. The electronic display of claim 16 further comprising a touch sensor. The electronic display of claim 3, wherein the fingerprint sensor further comprises a conductive layer, the touch sensor further comprising a conductive layer, wherein the fingerprint sensor The conductive layer and the conductive layer of the touch sensor form a whole. 32. A method of assembling an electronic display, the method comprising: providing a substrate; mounting a display controller on the substrate; mounting an electronic display module on the substrate; and disposing a circuit of the fingerprint sensor on the electronic display An upper end of the module, wherein the fingerprint sensor is disposed within a distance of less than 丨m from the uppermost layer of the electronic display; and μ. a protective layer is disposed on the uppermost layer of the electronic display, the protective layer is located on the circuit of the fingerprint sensor The method of claim 32, further comprising the step of providing a mask layer between the protective layer and the electronic display. 34. The method of claim 32, further comprising the step of placing a user protection layer over the mask layer. 35. The method of claim 32, wherein the display controller is to control a motion sensor and the fingerprint sensor. 36. Green as described in claim 35, further includes the step of connecting display controller 39 201246087 to the motion sense and fingerprint sensor. The method described in the patent application is also included in the step of placing a fingerprint sensor controller on the substrate. 38. The method of claim 37, further comprising the step of connecting the display controller to the circuitry of the motion sensor and the step of connecting the fingerprint sensor controller to the circuitry of the fingerprint sensor.