The present application claims priority to Chinese patent application No. 201810098372.0, filed on Jan. 31, 2018, the entire disclosure of which is incorporated herein by reference as part of the present application.
Embodiments of the present disclosure relate to a fingerprint identification method, a fingerprint identification device, a display panel and a readable storage medium.
A fingerprint is an invariant features which is inherent and unique for a human being and distinguishable from others. The fingerprint consists of a series of ridges and valleys on the surface of a fingertip, and the compositional details of these ridges and valleys determine the uniqueness of the fingerprint pattern. Therefore, fingerprint identification technology has been used for personal identification from earlier.
At least an embodiment of the present disclosure provides a fingerprint identification method, which includes: controlling at least one first light emitting unit in a first light emitting array to emit light; receiving, at a plurality of first positions in the first light emitting array, reflected signals caused by the light of the at least one first light emitting unit, respectively, and obtaining a plurality of first reflected light signals; and performing a fingerprint identification based on the plurality of first reflected light signals and distances between the plurality of first positions in the first light emitting array and the at least one first light emitting unit.
In some examples, a plurality of first light emitting units in the first light emitting array are controlled to emit light sequentially; reflected signals caused by the light of the plurality of first light emitting units are respectively received at the plurality of first positions in the first light emitting array, and a set of first reflected light signals corresponding to the plurality of first light emitting units are obtained; and the fingerprint identification is performed based on the set of first reflected light signals and distances between the plurality of first positions and the plurality of first light emitting units.
In some examples, the plurality of first light emitting units emit light of a same characteristic.
In some examples, the characteristic includes at least one of wavelength and intensity.
In some examples, the plurality of first light emitting units are a plurality of sub-pixels having a same color; or, the plurality of first light emitting units are a plurality of pixels, and sub-pixels of a same color in the plurality of pixels are controlled to emit light.
In some examples, light emitted from each of the plurality of first light emitting units comprises light of at least two different characteristics; composite reflected signal caused by the light of the plurality of first light emitting units are simultaneously received at the plurality of first positions in the first light emitting array, and a plurality of composite reflected light signals corresponding to the plurality of first positions are obtained; and the fingerprint identification is performed at least based on the plurality of composite reflected light signals and the distances between the plurality of first positions and the plurality of first light emitting units.
In some examples, the first light emitting unit is a pixel, at least two sub-pixels included in the pixel are controlled to emit light of different characteristics.
In some examples, a plurality of first light emitting units in the first light emitting array are controlled to emit light of different characteristics, simultaneously; composite reflected signals caused by the light of the plurality of first light emitting units are respectively received at the plurality of first positions in the first light emitting array, and a set of reflected light signals corresponding to the plurality of first light emitting units are obtained; and the fingerprint identification is performed based on the set of reflected light signals and distances between the plurality of first positions and the plurality of first light emitting units.
In some examples, obtaining the set of reflected light signals corresponding to the plurality of first light emitting units includes: decomposing the composite reflected signals obtained at the plurality of first positions according to the different characteristics of the light emitted from the plurality of light emitting units, to obtain the set of reflected light signals corresponding to the plurality of first light emitting units.
In some examples, the plurality of first light emitting units are located at a plurality of positions in the first light emitting array, respectively.
In some examples, the plurality of first light emitting units are pixels, N pixels in the first light emitting array are controlled to emit N different characteristics of light, wherein N is an integer greater than 1.
In some examples, the fingerprint identification method further includes: controlling at least one second light emitting unit in a second light emitting array to emit light; receiving, at a plurality of second positions in the second light emitting array, reflected signals caused by the light of the at least one second light emitting unit, respectively, and obtaining a plurality of second reflected light signals; and performing a fingerprint identification based on the plurality of second reflected light signals and distances between the plurality of second positions in the second light emitting array and the at least one second light emitting unit.
In some examples, the plurality of first reflected light signals are superimposed into one first signal, the plurality of second reflected light signals are superimposed into one second signal, a fingerprint identification is performed based on locations of the first light emitting array and the second light emitting array, the first signal and the second signal.
In some examples, the plurality of first reflected light signals being superimposed into one first signal includes superimposing first reflected light signals of photosensitive elements other than a photosensitive element having a maximum first reflected light signal in the first light emitting array to the maximum first reflected light signal to obtain the first signal, and the plurality of second reflected light signals being superimposed into one second signal includes superimposing second reflected light signals of photosensitive elements other than a photosensitive element having a maximum second reflected light signal in the second light emitting array to the maximum second reflected light signal to obtain the second signal.
In some examples, the first light emitting units and the second light emitting units at same positions of the first light emitting array and the second light emitting array are controlled to emit light at a same time, wherein the first light emitting array and the second light emitting array partially overlap each other such that a part of the first positions overlaps with a part of the second positions.
At least an embodiment of the present disclosure provides a computer readable storage medium, having stored thereon computer instructions, upon the computer instructions being executed by a processor, following operations being performed: controlling at least one first light emitting unit in a first light emitting array to emit light; reading reflected signals caused by the light of the at least one first light emitting unit and respectively received at a plurality of first positions in the first light emitting array, and obtaining a plurality of first reflected light signals; performing a fingerprint identification based on the plurality of first reflected light signals and distances between the plurality of first positions in the first light emitting array and the at least one first light emitting unit.
At least an embodiment of the present disclosure provides a fingerprint identification device, which includes: a plurality of light emitting arrays, wherein each of the plurality of light emitting arrays includes a plurality of light emitting units; a plurality of photosensitive elements, disposed at a plurality of positions in each of the plurality of light emitting arrays and configured to receive light of the plurality of light emitting units to generate a plurality of reflected light signals; and a processor, configured to: read the plurality of reflected light signals from the plurality of photosensitive elements; and perform a fingerprint identification based on the plurality of reflected light signals and distances between the plurality of positions and the plurality of light emitting units.
In some examples, the fingerprint identification device further includes light emitting control circuitry, configured to control the plurality of light emitting units in the plurality of light emitting arrays during a fingerprint identification phase.
In some examples, the light emitting control circuit is further configured to drive different light emitting units to emit light at different times during the fingerprint identification phase; or configured to modulate characteristics of light emitting signals of the plurality of light emitting units during the fingerprint identification phase.
In some examples, the plurality of light emitting arrays includes a first light emitting array and a second light emitting array adjacent to each other; wherein the first light emitting array and the second light emitting array share the plurality of photosensitive elements.
At least an embodiment of the present disclosure provides a display panel, which includes the fingerprint identification device provided by any one of the embodiments of the present disclosure.
In order to clearly illustrate the technical solutions of the embodiments of the disclosure, the drawings of the embodiments will be briefly described in the following; it is obvious that the described drawings are only related to some embodiments of the disclosure and thus are not limitative to the disclosure.
In order to make objects, technical details and advantages of the embodiments of the disclosure apparent, the technical solutions of the embodiments will be described in a clearly and fully understandable way in connection with the drawings related to the embodiments of the disclosure. Apparently, the described embodiments are just a part but not all of the embodiments of the disclosure. Based on the described embodiments herein, those skilled in the art can obtain other embodiment(s), without any inventive work, which should be within the scope of the disclosure.
Unless otherwise defined, all the technical and scientific terms used herein have the same meanings as commonly understood by one of ordinary skill in the art to which the present disclosure belongs.
In the following content provided by the present disclosure, for the purpose of describing sharing photosensitive element, in some embodiments, two adjacent light emitting arrays are respectively referred to as a first light emitting array and a second light emitting array, etc. In some other embodiments, the first light emitting array and the second light emitting array, etc., refer only to two different light emitting arrays.
At least one embodiment of the present disclosure uses a light emitting unit included in a light emitting array as a light wave emitting unit to emit an light signal along a display direction of a display panel, and uses a plurality of photosensitive elements disposed within a predetermined range in the vicinity of a plurality of predetermined light emitting units as receiving units to receive a plurality of reflected light signals of the light signal, and finally, performs a fingerprint identification based on distances between positions at which the reflected light signals are received and a position of the light emitting unit and the plurality of reflected light signals (for example, by comparing the distance and the plurality of reflected light signals).
First, when a finger is pressed on the display panel, a position of a valley and a position of a ridge in the fingerprint of the finger cause different reflected light signals for a same incident light signal. Because there exists an air gap between the position of the valley in the fingerprint of the finger and the touch panel, and energy of reflected light signal by the air is small and light reflection directions are many, few incident light signals are reflected to the photosensitive elements. There is no air gap between the position of the ridge in the fingerprint of the finger and the touch panel, so most of the incident light signals can be reflected. Then, if it is not a finger but a plane that can uniformly reflect light that contacts the touch panel, a relatively regular attenuation occurs (for example, the farther away from the light-emitting unit, the smaller the received reflected light signal) after the light signal emitted from each light-emitting unit is reflected and reaches the plurality of photosensitive elements located at different positions. Therefore, according to the fact that the attenuation regularity is destroyed by the valley and the ridge of the fingerprint, whether a corresponding photosensitive position belongs to a ridge or a valley can be determined. For example, the embodiment of the present disclosure can perform a fingerprint identification at least by comparing the plurality of reflected light signals to find whether there is a change in the attenuation regularity at respective positions.
The fingerprint identification device provided by the embodiments of the present disclosure has a simple structure, and can omit a physical button for fingerprint identification. The algorithm of the fingerprint identification method provided by the embodiments of the present disclosure has a small amount of computing, and can realize an under-screen fingerprint identification or even a full-screen fingerprint identification.
A fingerprint identification device 100 provided by the embodiment of the present disclosure is described below with reference to
The fingerprint identification device 100 of the embodiment of the present disclosure includes a plurality of light emitting arrays 113 and a processor 116 (as shown in
The plurality of light emitting arrays 113 can be evenly distributed in a region (for example, a display region of the display panel), but the density of the light emitting arrays 113 can also be set according to the frequencies at which different regions on the touch panel are contacted by the finger. For example, a large density of the light emitting arrays 113 can be disposed below a region where the finger is frequently contacted and a fingerprint identification is required, and a small density of the light emitting arrays 113 can be disposed below a region where a fingerprint identification is not often required.
Each of the light emitting arrays 113 can include one or a plurality of light emitting units 1131 arranged in an array. As shown in
The light emitting unit 1131 is configured to emit a light signal in a specific direction (i.e., in a direction in which the touch panel is located) in a fingerprint identification phase. For example, the light emitting unit 1131 can be a visible light emitting device for emitting a visible light signal of a predetermined wavelength range. For example, for the display panel, the light emitting unit 1131 can be a sub-pixel unit having a self-luminous function, such as an OLED sub-pixel unit.
The plurality of photosensitive elements 1132 are configured to receive a plurality of reflected light signals caused by the light of the light emitting unit 1131. For example, the photosensitive element 1132 can be a photo sensor, which can include any device that can respond to the intensity of the reflected light signal and provide a meaningful and detectable output. For example, examples of photo sensors that can be used in the embodiments of the present disclosure include, but are not limited to, photodiodes or phototransistors, etc.
The photosensitive elements 1132 can be disposed at a plurality of first positions in the light emitting array 113. For example, as shown in
It should be noted that, in one light emitting array 113 of the embodiments of the present disclosure, at least one light emitting unit 1131 and two photosensitive elements 1132 having different distances from the light emitting unit 1131 can be disposed. In the light emitting array 113 of the embodiments of the present disclosure, two or more light emitting units 1131 and at least two photosensitive elements 1132 having different distances from the light emitting units 1131 can also be disposed. The embodiments of the present disclosure do not limit the quantitative proportional relationship of the plurality of light emitting units 1131 and the plurality of photosensitive elements 1132 located in one light emitting array 113.
The processor 116 is configured to obtain the plurality of reflected light signals from the plurality of photosensitive elements 1132, and perform the fingerprint identification based on the distances between the plurality of positions where the photosensitive elements 1132 are located and the light emitting unit 1131 and the plurality of reflected light signals. For example, a “distance” herein refers to a distance between a light emitting unit that is currently emitting light during detecting and a photosensitive element for detecting the light emitted from the light emitting unit. For example, as shown in
The processor 116 can process and compute data signals, and can be of various computing architectures, such as a complex instruction set computer (CISC) architecture, a reduced instruction set computer (RISC) architecture, or an architecture that implements a combination of multiple instruction sets. For example, the processor 116 can be a digital signal processor (DSP), a microprocessor or a central processing unit, etc. For example, the processor 116 can be dedicated to fingerprint identification, and can also be used to process other tasks in addition to fingerprint identification.
The process and related principle of the processor 116 performing fingerprint identification based on the distances and the plurality of reflected light signals are described below with reference to
The light emitting array 113x shown in
The light emitting array 113x shown in
For example, at a certain time t, the light emitting unit 1131e located at the center of the light emitting array 113x emits light, and the remaining light emitting units do not emit light. When the incident light emitted from the light emitting unit 1131e is irradiated to the touch panel, the touch panel or the finger on the touch panel reflects the incident light to the nine photosensitive elements (i.e., reflects the incident light to the first photosensitive element 1132a, the second photosensitive element 1132b, the third photosensitive element 1132c, the fourth photosensitive element 1132d, the fifth photosensitive element 1132e, the sixth photosensitive element 1132f, the seventh photosensitive element 1132g, the eighth photosensitive element 1132h and the ninth photosensitive element 1132i). Therefore, each of the nine photosensitive elements will receive a reflected light signal, and a total of nine reflected light signals are obtained.
The abscissa in
At least one embodiment of the present disclosure utilizes the principle that the reflected light signals received by the plurality of photosensitive elements 1132 are related not only to distances, but also to that whether a valley or ridge of the fingerprint is at the positions resulting in the reflected light signals, to perform fingerprint identification by receiving reflected light signals at a plurality of positions at different distances from the light emitting unit and analyzing the changing rule of these reflected light signals.
The fingerprint identification device 100 provided by at least one embodiment of the present disclosure can omit complex fingerprint identification circuits and simplify fingerprint identification algorithms.
A fingerprint identification device 100 provided by another embodiment of the present disclosure is described below with reference to
The structure and function of the light emitting array 113 and the processor 116 included in the fingerprint identification device 100 of
The light emitting control circuit 114 is configured to control the light emitting units 1131 in the light emitting array 113 to emit light in the fingerprint identification phase. For example, the light emitting control circuit 114 is further configured to drive different light emitting units 1131 to emit light at different times in the fingerprint identification phase; or configured to modulate the characteristics of the light signals of the plurality of light emitting units 1131 in the fingerprint identification phase.
In at least one embodiment, different light emitting units 1131 in the light emitting array 113 can be made to emit incident light signals of the same characteristic by the light emitting control circuit 114, or different light emitting units 1131 can be made to emit the incident light signals of different characteristics by the light emitting control circuit 114.
In at least one embodiment, the light emitting control circuit 114 can also control the plurality of light emitting units 1131 located in a same array 113 to emit incident light signals of different characteristics simultaneously, or to emit incident light signals of a same characteristic sequentially.
For example, in one fingerprint identification process, one of the light emitting units 113 may be controlled to emit light by the light emitting control circuit 114 (for example, only the light emitting unit 1131 located at a central position of the light emitting array 113 is controlled to emit light), alternatively, the plurality of light emitting units 1131 in the light emitting array 113 can also be controlled to emit light sequentially or to emit light simultaneously.
The embodiment of the present disclosure can control the light emitting timing and the light emitting characteristics of the light emitting unit 1131 by the light emitting control circuit 114, and at least two examples can be provided. For example, in a first example, the light emitting control circuit 114 controls the plurality of light emitting units 1131 in a same light emitting array to emit light of different characteristics, simultaneously. In a second example, the light emitting control circuit 114 controls the plurality of light emitting units 1131 in the same light emitting array to emit light of a same characteristic, sequentially. In these way, it is at least possible to distinguish each of the light emitting units 1131 by timing (i.e., time division operation mode), or to distinguish each of the light emitting units 1131 by light signal characteristics (for example, frequency division operation mode). Therefore, respective photosensitive elements 1132 use the processor 116 to complete the fingerprint identification process based on the distances from the corresponding light emitting unit 1131.
A light emitting array 113 provided by still another embodiment of the present disclosure will be described below with reference to
Different from the above embodiments, the first light emitting array 113x and the second light emitting array 113y shown in
In
For example, the numbers of the light emitting units and the photosensitive elements in the first light emitting array 113x and the second light emitting array 113y in
The first photosensitive elements (1132a, 1132b) are respectively disposed at two positions of the first light emitting array 113x in
The shared light emitting units (1131c, 1131d) and the shared photosensitive elements (1132c, 1132d) described above are both located in the sharing area formed between the first light emitting array 113x and the second light emitting array 113y. The sharing region includes a part of the first positions and a part of the second positions, and the rest of the first and second positions are located in the non-sharing region (such as the first position where the photosensitive element 1132a is located and the first position where the photosensitive element 1132b is located). Herein, the “first position” and the “second position” are merely intended to distinguish the positions of the photosensitive elements in different light emitting arrays (the first light emitting array and the second light emitting array), and the “first” and “second” here are not to indicate any importance or sequence, etc. For example, the “first position” indicates a position of each photosensitive element in the first light emitting array, and the “second position” indicates a position of each photosensitive element in the second light emitting array. Taking the first light emitting array 113x as an example, four photosensitive elements are respectively located at four positions of “upper left”, “lower left”, “upper right” and “lower right” in the first light emitting array. However, the embodiments of the present disclosure are not limited thereto, and photosensitive elements can be disposed at more positions in each of the light emitting arrays.
The shared photosensitive elements (1132c, 1132d) in
It should be noted that the embodiments of the present disclosure do not limit the number of photosensitive elements 1132 shared by the first light emitting array 113x and the second light emitting array 113y. In different embodiments, the number and position of the shared photosensitive elements 1132 can be set as needed, and the number and position of the shared light emitting units 1131 can also be set as needed.
The embodiments of the present disclosure can reduce the number of components for fingerprint identification by sharing the photosensitive elements 1132, which facilitates miniaturization or integration of the device. At the same time, the light emitting units 1131 can be more fully utilized and the accuracy of fingerprint identification can be improved.
A display panel 111 provided by at least one embodiment of the present disclosure is described below with reference to
The display panel 111 in
At least one embodiment of the present disclosure provides a display device, which includes the above-described display panel 111. The display device can be implemented as any product or component having a display function, such as a mobile phone, a tablet computer, a television, a display, a notebook computer, a digital photo frame, a navigator, etc.
The specific structure of the light emitting array 113 in
An exemplary structure of the display panel 111 is described by taking an OLED display panel as an example and with reference to
Each pixel on the OLED display panel 111 of
The OLED display panel 111 in
How to set the sub-pixels shown in
The OLED display panel 111 in
In some examples, the OLED display panel 111 can further include at least a thin film encapsulation layer 122, a polarizer 121, a first optical adhesive layer 120, a touch control film layer 123, a second optical adhesive layer 125, a glass cover plate 126, a low temperature poly-silicon layer 127, a substrate (for example, a flexible substrate) 128, a support column 129, an anode 603, and a cathode 606, etc., as shown in
Referring to
The structure of the OLED display panel 111 will be described below in conjunction with
The OLED display panel 111 in
It should be noted that, in a case where the plurality of photosensitive elements 1132 are located at a gap between the plurality of OLED pixels, the original black matrix at the gap between the plurality of OLED pixels can be at least partially replaced. Moreover, in a case where the plurality of photosensitive elements 1132 are located one by one on the black matrix between the plurality of OLED pixels, the plurality of photosensitive elements 1132 can be located in an original protective layer of the black matrix. The protective layer in the black matrix is used to prevent oxidation of OLED pixels caused by impurities such as water, etc.
The working process of the OLED display panel 111 in
Assuming that the transistor switches connected to the first row of sub-pixels in
In the former period, the grayscale data for image display is transmitted to the sub-pixels of the first row through the data line D, and image display is performed. In the latter period, the light emitting control signals for controlling light emission of the light emitting units 1131 are transmitted to the light emitting units 1131 of the first row (here, for example, transmitted to the green sub-pixels of the present row) through the data line D, so that the corresponding light emitting units 1131 emit incident light signals outward. At the same time, the switches (i.e., the transistors connected to the photosensitive elements 1132 in
It should be understood by those skilled in the art that dividing the above period T1 into four quarters to control image display and fingerprint identification is for illustrative purposes only. The embodiments of the present disclosure do not limit how image display and fingerprint recognition are multiplexed for a period of time. For example, for a display device 111 that needs to perform fingerprint identification frequently, a longer continuous period can be set for the display device 111 to be used for fingerprint identification; and for a display device 111 that is used for display for a large amount of time, a longer continuous period can be set for display device 111 to be used for image display.
It should be noted that the embodiments of the present disclosure do not limit the use of time division multiplexing to control the display panel 111 to perform the two functions of display and fingerprint identification. In some other embodiments of the present disclosure, fingerprint identification can also be performed by sensing a touch action and determining a corresponding touch region (for example, a partial touch region 1133 is shown in
In addition, the above OLED display panel 111 is for illustrative purposes only, and the embodiments of the present disclosure do not limit the type of the display panel 111. For example, the display panel 111 of the embodiments of the present disclosure can also be an LCD display panel or the like. For example, light emitting units for emitting detective light can be additionally provided in pixels of the LCD display panel. For example, such light emitting units can be an emitting element that emits visible or invisible light as long as such light can be detected by the photosensitive element.
A fingerprint identification method 300 of an embodiment of the present disclosure will be described below with reference to
In order to describe a plurality of embodiments included in the fingerprint identification method 300, one of the light emitting arrays 113 in
As shown in
operation S310: controlling at least one first light emitting unit (i.e., any one of the light emitting units in
operation S320: receiving, at a plurality of first positions (e.g., the positions where the photosensitive elements 1132 in
operation S330: performing a fingerprint identification based on distances between the plurality of first positions in the first light emitting array and the at least one first light emitting unit and the plurality of first reflected light signals.
Steps included in an example of the fingerprint identification method 300 in a case where operation S310 controls one first light emitting unit in the first light emitting array to emit light are described below.
Operation S310 is executed to control one first light emitting unit in the first light emitting array to emit light. Then, operation S320 is executed to receive the reflected signals caused by the light of the first light emitting unit at L (for example, L is an integer equal to or greater than 2) different positions in the first light emitting array, respectively, so as to obtain L first reflected light signals. Finally, operation S330 performs a fingerprint identification based on L distances (L distances, that is, distances between L different positions and the first light emitting unit) and the L first reflected light signals.
A process of controlling one first light emitting unit to emit light for fingerprint identification is exemplarily described below with reference to
As shown in
The plurality of first positions involved in the above operation S320 are position A, position B, position C, position D, position E, and position F where the six photosensitive elements 1132 in
Operation S310 is executed to cause one of the six light emitting units 1131 (e.g., the light emitting unit in the first row and the second column) in
The incident light signal of the first characteristic reaches the touch panel, and then is reflected by an operating body (for example, the operating body can be a finger or a palm, etc.) to reach position A, position B, position C, position D, position E, and position F in
Operation S320 is performed to receive the reflected light signals by the six photosensitive elements 1132 (for example, photosensitive sensors) at the six positions, and convert the received reflected light signal into current signals to obtain six first reflected light signals.
Operation S330 is performed to combine the six first reflected light signals, and six distances between the six first positions and the one of the light emitting units involved in operation S310 to identify the fingerprint information.
In the above embodiments of the present disclosure, fingerprint identification is performed by controlling one first light emitting units in the first light emitting array to emit light, so that the process of fingerprint identification can be accomplished quickly and the sensitivity of fingerprint identification can be improved.
Next, steps included in the fingerprint identification method 300 in a case where operation S310 controls a plurality of first light emitting units in the first light emitting array to emit light will be described with reference to
The fingerprint identification method 700 provided in
The fingerprint identification method 700 in
operation S3101: controlling a plurality of first light emitting units in the first light emitting array to emit light sequentially;
operation S3201: receiving, at a plurality of first positions in the first light emitting array, reflected signals caused by the light of the plurality of first light emitting units, respectively, and obtaining a set of first reflected light signals corresponding to the plurality of first light emitting units;
operation S3301: performing a fingerprint identification based on distances between the plurality of first positions and the plurality of first light emitting units and the set of first reflected light signals.
The plurality of first light emitting units in the present embodiment emit light of a same characteristic. The characteristic here can include at least one selected from the group consisting of intensity, phase and frequency. For example, in at least one embodiment, the characteristic includes wavelength or intensity. For example, in one embodiment, the plurality of first light emitting units emit light of a same wavelength. For example, in one embodiment, the plurality of first light emitting units emit light of a same wavelength and a same intensity. It should be noted that, for the plurality of first light emitting units to emit light of a same frequency characteristic, it is not that the frequency values of the light signals emitted from the plurality of first light emitting units are absolutely equal, but rather that the frequencies of the light signals emitted from the first light emitting units all belong to a predetermined range. Light signals of this predetermined range can be sensed by the photosensitive elements to generate corresponding electrical signals.
Operation S3101 in
For example, in one example, operation S3101 in
For example, in another example, operation S3101 of
Thereafter, the above two examples will continue to execute operation S3201 such that the plurality of photosensitive elements in
For example, in some embodiments, whether to adopt the example corresponding to
It should be noted that the embodiments of the present disclosure do not limit the types of light signals emitted from the first light emitting units corresponding to the example illustrated in
In at least one embodiment of the present disclosure, light intensity values of the plurality of reflected light signals received a plurality of times by the photosensitive elements can be further superimposed. Using a superimposed signal for fingerprint identification can further improve the identification accuracy.
A superposition algorithm is briefly described below in combination with Table 1, Table 2, Table 3 and
The nine light emitting units in
In some examples, in order to further increase the light intensity value of the reflected signal perceived by the photosensitive element 1132e at the central position, a received maximum light intensity value can be used as a reference and the reflected light signals received by the photosensitive element 1132e for the remaining eight times can be superimposed to the maximum value (as indicated by the arrows in Table 2). For example, in each of the light emitting arrays, a photosensitive element having the maximum received light intensity value (for example, a photosensitive element closest to the light emitting unit) can be selected as a superimposing target, and the reflected light signals of the photosensitive elements around this photosensitive element can be superimposed on the light intensity value of this photosensitive element. However, the embodiments of the present disclosure are not limited thereto, and the superimposition can be performed on other photosensitive elements.
Table 3 above shows that after the superposition processing, the intensity value of the final reflected light signal received by the central photosensitive element 1132e (i.e. the fifth photosensitive element 1132e in
In some embodiments, a plurality of light emitting arrays can be selected for fingerprint identification. For example, the light intensity values of the reflected light signals of each light emitting array can be superimposed on one photosensitive element by the above-mentioned superposition processing method, and then the fingerprint identification is performed based on the positions of different light emitting arrays and the superimposed light intensity values corresponding to the different light emitting arrays.
It should be noted that, in the embodiments of the present disclosure, it may need to ensure that the information of the valley and the ridge of the fingerprint does not crosstalk when performing the superimposing operation. The embodiments of the present disclosure do not limit whether the received maximum light intensity value is taken as a reference or not, and any other smaller light intensity value can be selected as a reference to superimpose the light intensity values of the remaining times on the smaller light intensity value, so as to obtain the superimposed light intensity value as a basis for fingerprint identification.
The present disclosure makes the plurality of first light emitting units in the first light emitting array emit light sequentially through the embodiment of
The accuracy of fingerprint identification can be improved by using a plurality of light emitting units of the embodiments of the present disclosure to emit light sequentially to obtain multiple sets of reflected light signals for fingerprint identification.
A fingerprint identification method 900 provided by still another embodiment of the present disclosure is described below with reference to
The fingerprint identification method 900 provided in
As shown in
operation S3102: controlling a plurality of first light emitting units in the first light emitting array to emit light of at least two different characteristics simultaneously;
operation S3202: receiving, at a plurality of first positions in the first light emitting array, composite reflected signals caused by the light of the plurality of first light emitting units, respectively, and obtaining a set of composite reflected light signals corresponding to the plurality of first light emitting units;
operation S3302: performing a fingerprint identification based on distances between the plurality of first positions and the plurality of first light emitting units and the set of composite reflected light signals.
The light signals of different characteristics in operation S3102 can include light signals of different frequencies, light signals of different intensities, or light signals of different phases. For example, light signals of different frequencies can be light signals of different colors. Furthermore, the so-called different frequencies, different intensities or different phases in some embodiments refer to that light signals being emitted belong to different predetermined ranges. For example, operation S3102 in
Operation 53102 causes the plurality of first light emitting units to emit light of at least two different characteristics simultaneously, so that the light of the two characteristics is reflected to the plurality of first positions (for example, the position where the photosensitive elements 1132 are located), and reflected light signals of composite light signals of the light signals having at least two characteristics can be received at the plurality of first positions.
In at least one embodiment, operation 53302 can employ a decomposition algorithm to decompose M composite reflected light signals received at M (M is greater than or equal to 2) the first positions, and each of the composite reflected light signals can be decomposed into light signals of K characteristics (K is greater than or equal to 2 and K represents the types of light signals emitted from all of the light emitting units in the first light emitting array). Therefore, reflected light signals of the K characteristics, that is, light signal of a first characteristic, light signal of a second characteristic, . . . , light signal of a Kth characteristic, are obtained by the decomposition algorithm at each of the first positions. Then, a first fingerprint identification is performed by using the light signals of the first characteristic of the M first positions, a second fingerprint identification is performed by using the light signals of the second characteristic of the M first positions, . . . , and so on, until a Kth fingerprint identification is completed by using the reflected light signals of the Kth characteristic, and finally results of the K times of fingerprint identifications are integrated as a final result of fingerprint identification. The fingerprint identification method 900 in
The light emitting array 113 in
Operation S3102 in
The embodiment of the present disclosure obtains a plurality of fingerprint identification results by controlling a plurality of first light emitting units in one light emitting array 113 to emit light signals of different characteristics simultaneously, and then decomposing the composite reflected light signals. Finally, the final result of fingerprint identification is obtained based on the plurality of fingerprint identification results, which improves the accuracy of fingerprint identification.
A fingerprint identification method 1100 according to an embodiment of the present disclosure is described below with reference to
It should be noted that the second light emitting array in
The fingerprint identification method 1100 provided in
operation S340: controlling at least one second light emitting unit in a second light emitting array to emit light;
operation S350: receiving, at a plurality of second positions in the second light emitting array, reflected signals caused by the light of the at least one second light emitting unit, respectively, and obtaining a plurality of second reflected light signals;
operation S360: performing a fingerprint identification based on distances between the plurality of second positions in the second light emitting array and the at least one second light emitting unit and the plurality of second reflected light signals.
The meanings of the plurality of second positions can refer to the plurality of first positions described in the above-mentioned embodiments, and details are not described herein.
Specific execution details of operation S340 in
In addition, operation S340 in
Moreover, in some embodiments, the second light emitting array in
A fingerprint identification method provided by still another embodiment of the present disclosure is described below with reference to
In at least one embodiment, the fingerprint identification method further includes controlling the first light emitting units (i.e., the light emitting units 1131a and the light emitting unit 1131b in
It should be noted that the fingerprint identification method of sharing photosensitive elements in
In some examples, the first light emitting array (e.g., 113x of
In some other examples, the first light emitting array (e.g., 113x of
At least an embodiment of the present disclosure provides a computer readable storage medium, which stores computer instructions thereon. Upon the computer instructions being executed by a processor, the following operations are performed: controlling at least one first light emitting unit in a first light emitting array to emit light; reading reflected signals caused by the light of the at least one first light emitting unit and respectively received at a plurality of first positions in the first light emitting array, and obtaining a plurality of first reflected light signals; performing a fingerprint identification based on distances between the plurality of first positions in the first light emitting array and the at least one first light emitting unit and the plurality of first reflected light signals. The computer readable storage medium is, for example, a magnetic storage medium, an optical storage medium or a semiconductor storage medium; the storage medium can be a non-volatile storage medium; the storage medium can be used not only to store computer executable instructions, but also to store data required for running the computer executable instructions or data generated by running the computer executable instructions.
The accompanying drawings involve only the structure(s) in connection with the embodiment(s) of the present disclosure, and other structure(s) can be referred to common design(s). In case of no conflict, the embodiments of the present disclosure and features in the embodiments can be combined.
What have been described above are only specific implementations of the present disclosure, the protection scope of the present disclosure is not limited thereto. Any changes or substitutions easily occur to those skilled in the art within the technical scope of the present disclosure should be covered in the protection scope of the present disclosure. Therefore, the protection scope of the present disclosure should be based on the protection scope of the claims.
Number | Date | Country | Kind |
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201810098372.0 | Jan 2018 | CN | national |
Filing Document | Filing Date | Country | Kind |
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PCT/CN2018/111146 | 10/22/2018 | WO | 00 |