WO2016019882A1 - Vein recognition imaging device and method for security authentication of mobile terminal - Google Patents

Vein recognition imaging device and method for security authentication of mobile terminal Download PDF

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Publication number
WO2016019882A1
WO2016019882A1 PCT/CN2015/086222 CN2015086222W WO2016019882A1 WO 2016019882 A1 WO2016019882 A1 WO 2016019882A1 CN 2015086222 W CN2015086222 W CN 2015086222W WO 2016019882 A1 WO2016019882 A1 WO 2016019882A1
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Prior art keywords
optical
vein recognition
mobile terminal
vein
imaging
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PCT/CN2015/086222
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French (fr)
Chinese (zh)
Inventor
倪蔚民
沈洪泉
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苏州思源科安信息技术有限公司
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Publication of WO2016019882A1 publication Critical patent/WO2016019882A1/en

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    • GPHYSICS
    • G06COMPUTING; CALCULATING OR COUNTING
    • G06FELECTRIC DIGITAL DATA PROCESSING
    • G06F21/00Security arrangements for protecting computers, components thereof, programs or data against unauthorised activity
    • G06F21/30Authentication, i.e. establishing the identity or authorisation of security principals
    • G06F21/31User authentication
    • G06F21/32User authentication using biometric data, e.g. fingerprints, iris scans or voiceprints

Definitions

  • the invention relates to the field of opto-mechatronics, in particular to a vein recognition imaging device for mobile terminal safety certification and a control method thereof.
  • Mobile terminals include smart phones, tablets, wearable devices, etc.
  • mobile terminal devices are inevitably the most widely used devices in the future.
  • the conventional method for identity verification in the prior art is password input, but the means of identity verification is very low in security, and only a simple virus program needs to be implanted on the mobile terminal to leak the password. , causing corresponding losses.
  • the biometric identification method is used for mobile terminal security identity authentication; for example, the fingerprint recognition technology developed by Apple based on AuthenTec, which is applied to mobile phone terminals, greatly improves the mobile terminal.
  • Identity verification security since the fingerprint is static, although it is singular, it is extremely easy to obtain fingerprint information, even being copied, etc., so with the fingerprint technology on the mobile terminal As the application becomes more and more extensive, its security will also decline accordingly. Therefore, biometrics (vein recognition), which is more advantageous in terms of security, is a very effective method to solve the mobile identity authentication process, and vein recognition.
  • the system is the safest way to secure the living body in the existing biometrics.
  • the most typical ones are Japanese Hitachi finger vein recognition, and the transmission imaging method using a fixed contact structure seat determines that the volume and structure cannot be used for the common standard of 8mm*8mm*6mm in mobile terminals. Size; like Japan Fujitsu palm vein recognition, it also has a defect far larger than the common standard size in the mobile terminal, and the working distance is only 4-6cm, it can not be used in such a short working range, and the use actually needs to rely on additional The fixed contact structure can only be used.
  • the user is usually hand-held, and needs to be recognized during the moving travel. There is a very large and unpredictable movement of the finger or palm back of the hand, which seriously affects the image quality.
  • the usage scenario of the mobile terminal determines that the structure cannot be fixed contact type, and it is impossible to use it by attaching a fixed contact structure, which can only be realized by non-contact type.
  • the mobile terminal is battery-powered, and its power consumption for the vein recognition imaging module is very high.
  • the miniaturization of the vein recognition optical imaging module is in accordance with the general standard size of 8mm*8mm*6mm in the mobile terminal.
  • the technical problem to be solved by the present invention is to provide a vein recognition imaging module for mobile terminal security identity authentication and a control method thereof.
  • the present invention provides a vein recognition imaging apparatus for mobile terminal security authentication, comprising a vein recognition imaging apparatus disposed on a mobile terminal;
  • the mobile terminal includes a mobile terminal motherboard, a processor chip, a memory, and a memory a power management module and a wireless baseband module;
  • the vein recognition imaging device is composed of a near-infrared LED illumination source and a vein recognition imaging module optical component;
  • the near-infrared LED illumination source is driven by a near-infrared LED current driver;
  • the imaging module optical component comprises a near-infrared optical filter for filtering the reflected light of the near-infrared LED illumination source and filtering the reflected light, and an optical imaging lens for focusing the filtered light of the near-infrared optical filter,
  • An image imaging sensor for focusing an optical imaging lens, and a vein recognition imaging module substrate for transmitting an image of the image imaging sensor;
  • the near-infrared LED illumination source is a surface patch package; and the near-infrared LED current driver drives a near-infrared LED illumination source to output a maximum radiation intensity I short-time T-pulse periodic timing emission light; the near-infrared LED illumination source outputs the highest radiation intensity I short time T pulse period timing synchronization image imaging sensor frame pixel global trigger exposure cycle timing; the near-infrared LED illumination source emission
  • the half-peak radiation or divergence angle of light is greater than or equal to optical Imaging angle of view FOV of the lens; the optical imaging lens fixed focus lens, liquid drive lens, liquid crystal drive lens, VCM voice coil drive lens, MEMS drive lens, EDOF phase wavefront coding lens, WLA wafer level lens array Any one of the half-peak transmission wavelength bandwidths FWHM of the near-infrared optical filter effectively matching or covering a half-peak radiation wavelength bandwidth FWHM of the light emitted by the near-inf
  • the near-infrared LED illumination source has a center peak wavelength range of 750-880 nm and a FWHM of 30-60 nm;
  • the near-infrared optical filter The center of the device has a peak wavelength range of 750-880 nm and a FWHM of 10-60 nm;
  • the near-infrared optical filter is any one of a narrow-band near-infrared optical filter or a band-pass near-infrared optical filter;
  • the optical imaging The field of view FOV of the lens has the following range of values: FOV ⁇ 2 * arctan ((DOI * SOP) / (2 * EFL)); the DOI is the number of diagonal pixels of the image imaging sensor; SOP is image imaging The physical scale of the sensor unit pixel; EFL is the equivalent focal length value of the optical imaging lens.
  • a further improvement of the vein recognition imaging apparatus for mobile terminal security authentication according to the present invention is that the near-infrared LED illumination source is provided with an optical diffusing diffuser for providing a uniform emission or radiation illumination light field.
  • a further improvement of the vein recognition imaging apparatus for mobile terminal security authentication according to the present invention is that the optical diffusing diffuser is an optical diverging mirror.
  • the near-infrared LED illumination source is provided with an optical linear polarizer; corresponding to the optical linear polarizer, a corresponding positive is set in the imaging optical path A 90 degree optical linear polarizer.
  • the mobile terminal is provided with a use state guiding prompt device;
  • the use state guiding prompt device includes a voice device, an indicator light, and a liquid crystal screen The voice device, the indicator light, and the liquid crystal screen are connected to the processor chip signal.
  • the method for performing safety authentication using the vein recognition imaging module of the mobile terminal comprises the following steps: 1) the processor chip acquires a digital vein image output by the image imaging sensor; 2) the processor chip performs a vein recognition algorithm to perform extraction of the vein feature 3), the processor chip generates a vein feature template through the vein feature information; 4) obtains at least 2 or more vein feature templates through the cycle steps 1) to 3), and performs cross-certification comparison between the vein feature templates to
  • the specific vein feature template of the best result after the cross-certification comparison is a standard vein feature template; 5) the standard vein feature template is encrypted by the cryptographic system and stored in the configuration processor chip as a key, and is guaranteed to be never Export and access; 6), the identity authentication of the vein feature template is performed inside the processor chip, ensuring that the mobile terminal is safe from external attacks during the entire identity authentication process.
  • the digitized vein image output by the image imaging sensor is obtained by the following steps: 1.1) defining the original unit of the vein recognition imaging module The photoelectric signal of the pixel brightness value Yraw; 1.2) defines the pixel area luminance statistical evaluation value Ysp; 1.3), and realizes the vein area pixel brightness statistical evaluation value Ysp in the preset [Yll, Yhl] brightness range.
  • the diameter of the optical aperture, FEL is the equivalent focal length value of the optical imaging lens
  • SOP is the
  • the present invention achieves the following effects required by the mobile terminal usage scenario:
  • the ambient light level required for user identification is required to satisfy 100,000 Lux from the indoor complete dark 0Lux to the outdoor direct sunlight.
  • the vein recognition imaging module realizes non-contact collection and use, and does not need to be attached with a fixed contact structure.
  • the power consumption of the light source of the vein recognition imaging module is low.
  • the volume of the vein recognition imaging module is miniaturized.
  • FIG. 1 is a general structural diagram of a vein recognition imaging module according to a specific embodiment of the present invention.
  • FIG. 2 is a structural diagram of an optical component of a vein recognition imaging module according to a specific embodiment of the present invention
  • FIG. 3 is a schematic diagram of a vein identification imaging module mounted on the back of a mobile smart phone according to a specific embodiment of the present invention
  • FIG. 4 is a timing sequence diagram of a frame pixel global trigger exposure (integration) of a maximum radiation intensity short-time pulse period timing synchronization imaging sensor generated by an infrared LED illumination source according to a specific embodiment of the present invention.
  • FIG. 1 shows a vein recognition imaging device for mobile terminal security authentication, comprising a vein recognition imaging module optical component 1, a near-infrared LED current driver 2, and a near-infrared LED illumination disposed on the mobile terminal.
  • the light source 3 and the vein recognition imaging module connection line 4; the mobile terminal comprises a mobile terminal motherboard 10, a processor chip 5, a memory 6, a memory 7, a power management 8 and a wireless baseband module 9.
  • the processor chip 5 is an ARM CORTEX-A processor chip configured with TrustZone's secure isolation mode; the memory 6 is DDR memory; the memory 7 is NAND FLASH memory; and the power management 8 is a PMIC power management module.
  • the above mobile terminal motherboard 10, processor chip 5, memory 6, memory 7, power management 8 and wireless baseband module 9 can all be purchased and assembled by the market.
  • the near-infrared LED illumination source 3 is connected to the near-infrared LED current driver 2, and the near-infrared LED illumination source 2 is driven by the near-infrared LED current driver 2 to generate a pulse period-time emission light that outputs the highest radiation intensity I for a short time T; here, in the selection
  • the surface mount package (SMD) is used to reduce the volume [using a surface mount package (SMD) near-infrared LED illumination source].
  • the mobile terminal board 10 and the vein recognition imaging module optical component 1 and the near-infrared LED current driver 2 are mutually connected by a vein identification imaging module connection line 4; the implementation includes a pixel clock, pixel data, pixel data synchronization signal, and I2C communication.
  • the near-infrared LED current driver 2 drives the control signal transmission of the near-infrared LED illumination source 3.
  • Mobile terminal board 10 integrated configuration TrustZone security isolation mode ARM CORTEX-A processor chip 5 (for performing all control, identification, application data processing calculation), DDR memory 6 (used to provide processor chip 5 processing calculations required Memory), NAND FLASH memory 7 (for storing all necessary power-down saveable data), PMIC power management 8 (providing power to all levels of the mobile terminal board 10) and wireless baseband module 9 (for wireless communication applications)
  • the mobile terminal motherboard 10 implements control and secure identity authentication of the vein recognition imaging module of the present invention.
  • Vein recognition imaging module optical component 1 for non-contact physical imaging to collect fingers The back vein image of the palm of the hand.
  • the specific structure of the vein identification imaging module optical component 1 comprises the following components: a front focus near-infrared optical filter 11, a fixed focal length optical imaging lens 12, a fixed mount of the optical imaging lens 13, and a rear.
  • the image recognition sensor 15 , the back focus near-infrared optical filter 14 , the fixed mount 13 of the optical imaging lens, the optical imaging lens 12 with a fixed focal length, and the front focal near infrared optics are sequentially disposed from the bottom to the top of the vein recognition imaging module substrate 16 .
  • Filter 11 The image recognition sensor 15 , the back focus near-infrared optical filter 14 , the fixed mount 13 of the optical imaging lens, the optical imaging lens 12 with a fixed focal length, and the front focal near infrared optics are sequentially disposed from the bottom to
  • the vein recognition imaging module substrate 16 is composed of a printed circuit board, a flexible circuit board or a soft and hard bonding board, and is used for providing a fixed structure carrier in which the optical component 1 of the vein recognition imaging module is integrally mounted.
  • the fixed mount 13 of the optical imaging lens is used to mount a fixed focal length optical imaging lens 12.
  • the highly mature mobile terminal component design and manufacturing process can realize the miniaturization of each optical component in the optical component 1 of the vein recognition imaging module, and adopts the mature technical field of the art to design and manufacture the vein identification imaging module to fully satisfy the movement.
  • the near-infrared light radiated by the near-infrared LED illumination source 3 enters the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 after the optical biological effect of absorption, scattering, and reflection of the object square vein (
  • the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are simultaneously present, the front focus near-infrared optical filter 11 is alone or the back focus near-infrared optical filter 14 is separate.
  • the three NIR optical filters can be set in the best case of the invention for non-imaging interference light filtering, then enter the fixed focal length optical imaging lens 12; fixed focal length optical imaging
  • the lens 12 is an autofocus AF optical imaging lens or a fixed focus optical imaging lens for realizing non-contact optical physical focusing to the image imaging sensor 15 located at the image side, causing the image optical signal to be converted into an image electrical signal output, and finally by vein recognition.
  • the imaging module connection line 4 is connected to the mobile terminal motherboard 10, and the vein recognition imaging module of the present invention is controlled by the processor chip 5.
  • the vein recognition imaging module of the present invention is further provided with a use state guiding prompting device.
  • the use state guiding prompting device includes a voice prompting device (speaker), an indicator light, and a liquid crystal screen for indicating a state guiding when the user uses, such as a finger palm back placement position and distance, recognition result feedback, and the like.
  • the near-infrared LED illumination source 3 described above has a center peak wavelength range of 750-880 nm, a FWHM of 30-60 nm, and a center peak of the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14.
  • the lighter 14 can be a narrowband near-infrared optical filter or a bandpass near-infrared optical filter).
  • the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are coated with an optically transparent glass such as BK7 or an optical material such as colored glass or optical resin, and the current coating process and technology can achieve the background.
  • Depth cutoff rate or Signal-to-noise ratio SNR SNR: signal-to-noise ratio
  • SNR Signal-to-noise ratio
  • the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 filters the wavelength used for imaging such that the imaging wavelength interferes with the non-imaged background by the signal-to-noise ratio SNR of the stray light (SNR: signal-to -noise ratio) Satisfaction: ⁇ 60dB (1000:1).
  • Ambient non-imaging interference light ie, non-imaging background interference stray light
  • Non-imaging interference stray light with different illumination levels in the environment seriously affects the quality of vein image; the greater the illumination, the greater the influence of vein image quality.
  • different moving speeds will cause motion blur, which will seriously affect the quality of the vein image; the greater the moving speed, the greater the influence of the vein image quality.
  • the present invention adopts the following design:
  • the near-infrared LED illumination source 3 and the image imaging sensor 15 are combined and configured as follows:
  • the highest radiation intensity generated by the near-infrared LED illumination source 3 is short time T pulse period timing synchronization image imaging sensor 15 frame pixel global trigger exposure (integration) cycle timing;
  • the method for synchronizing periodic timing frame pixel global trigger exposure (integration) of the image imaging sensor 15 of the present invention employs triggering all frame pixel synchronization of the image imaging sensor 15 only in the imaging wavelength range and the highest radiation intensity short time period sequence. Exposure (integration).
  • the exposure cycle timing of different rows is inconsistent, but under the condition that the imaging triggers (integration) of all the frame pixels in the imaging wavelength range and the highest radiation intensity short time period timing are synchronized.
  • the ratio of exposure (integral) photon signal accumulation outside the shortest time period of the highest radiation intensity to the highest radiation intensity is much greater than 1000:1, so that the most effective resolution for a typical imaging sensor ADC is only 8 bits or 10 digits can be ignored. Therefore, the method is applicable to various types of imaging sensors, such as a global shutter, an electronic rolling shutter (ERS) or a global release shutter GRS, and various types of imaging sensors.
  • the method of synchronizing the highest radiation intensity I generated by the near-infrared LED illumination source 3 with the short-time T-pulse period timing and the period timing of the image-imaging sensor 15 frame pixel global trigger exposure (integration), the synchronization pulse period timing radiation and exposure method It is an important advantage of the present invention.
  • the vein recognition optical imaging module designed in this way has low power consumption of the light source and only 1/30 equivalent radiation compared with the conventional continuous radiation source.
  • the radiation and exposure methods that emphasize the traditional continuous cycle timing are only a special case of the radiation and exposure methods of the synchronous pulse period timing of the present invention.
  • the pulse period is 100% duty cycle timing
  • the radiation and exposure are equal to the continuous period timing radiation and exposure.
  • the SNR SNR: signal-to-noise ratio
  • the ambient illuminance requirements of the vein recognition optical imaging module of the present invention are such that it is from indoor complete darkness (0 Lux) to outdoor direct sunlight (100,000 Lux).
  • High-radiation intensity short-time periodic timing frame pixel synchronization global trigger exposure can completely eliminate motion blur up to 1m/s, so that the moving speed of vein image imaging needs to meet the moving speed from moving speed 1m/s to completely static moving speed 0cm /s.
  • the near-infrared LED illumination source 3 and the optical imaging lens 12 are combined and configured as follows:
  • the half-peak radiation or divergence angle of the near-infrared LED illumination source 3 is greater than or equal to the imaging field of view angle FOV of the optical imaging lens 12.
  • the field of view angle FOV of the optical imaging lens has the following values:
  • the DOI described in the above formula is the number of diagonal pixels of the image imaging sensor; the SOP is the physical scale of the image imaging sensor unit pixel; and the FEL is the equivalent focal length value of the optical imaging lens.
  • the near-infrared LED illumination source 3 is provided with an optical diffusing diffuser for providing a uniform emission or radiation illumination field to form a vein image with a balanced brightness distribution, which effectively reduces total reflected light from the back surface of the palm of the hand.
  • the optical diffusing diffuser can be configured as an optical diverging mirror.
  • the near-infrared LED illumination light source 3 is configured with an optical linear polarizer, and an orthogonal state 90-degree optical linear polarizer is disposed in the imaging optical path (front or rear of the optical imaging lens 12), and an orthogonal state line is formed through the transmitting and receiving ends.
  • the polarizer completely removes the total reflected light from the back surface of the palm of the hand.
  • the near-infrared LED illumination source 3 and the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are configured as follows:
  • the half-peak transmission wavelength bandwidth FWHM of the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 effectively matches or covers the half-peak radiation of the near-infrared LED illumination source 3 Wavelength bandwidth FWHM.
  • This design allows for maximum imaging wavelength utilization and imaging of high quality vein images.
  • the near-infrared LED illumination source has a peak wavelength range of 750-880 nm and a FWHM of 30-60 nm; a near-infrared optical filter has a peak wavelength range of 750-880 nm and a FWHM of 10-60 nm.
  • the fixed focal length optical imaging lens 12 is selected from the group consisting of a fixed focus lens, a liquid drive lens, a liquid crystal drive lens, a VCM voice coil motor drive lens, a MEMS microelectromechanical system drive lens, an EDOF wavefront code lens or a WLA wafer level lens array. Any one. Liquid drive lens, liquid crystal drive lens, VCM voice coil drive lens, MEMS drive lens, EDOF phase wavefront code lens, WLA wafer level lens array are configured to achieve autofocus AF of optical imaging lens, auto focus can be further increased The working distance and range of non-contact acquisition make it easier to use.
  • the vein identification imaging module of the specific implementation column 1 described above is installed on the mobile smart phone, and the state of the user in use is as shown in FIG. 3: the mobile phone back side 100 is provided with the vein recognition imaging module optical component 1 and the surface patch package. (SMD) near-infrared LED illumination source 3.
  • SMD surface patch package.
  • the palm of the hand is placed in front of the vein recognition imaging module optical component 1.
  • the near-infrared LED illumination source 3 provides illumination to the front finger palm back, and the near-infrared LED illumination source 3 radiates near-infrared light.
  • the optical component 1 entering the vein recognition imaging module realizes non-contact optical physical focusing to the image imaging sensor 15 located at the image side to convert the image light signal into an image electrical signal output. The process is as follows:
  • the T described above is the frame pixel global trigger exposure time exposure time or integral time integrationtime of the image imaging sensor, and the cycle timing is synchronized with the short-time T pulse period timing of the near-infrared illumination source; T ⁇ 3.33ms (milliseconds);
  • I is the highest radiation intensity of the near-infrared illumination source; I ⁇ 10mW/sr (milliwatts per sphericity);
  • the GAIN described above is the analog gain of the image imaging sensor; the image-to-noise ratio SNR of the image imaging sensor generated by the maximum GAIN value is ⁇ 38db;
  • D is the diameter of the aperture or clear aperture of the optical imaging lens
  • FEL is the equivalent focal length of the optical imaging lens
  • SOP is the physical scale of the image imaging sensor unit pixel
  • is the equivalent peak wavelength of the near-infrared LED illumination source
  • the above C is the fixed photoelectric signal conversion rate constant of the vein recognition imaging module
  • the S described above is a venous region pixel brightness statistical evaluation function, and the pixel brightness system
  • the method used by the evaluation function includes: pixel luminance histogram statistics, pixel luminance spectrum statistics, pixel luminance average, pixel luminance weighted average, or pixel luminance median value;
  • Yll described above is the lower limit of the pixel brightness of the vein region, and Yhl is the upper limit of the pixel brightness of the vein region;
  • the photoelectric signal processing control described above is based on the linear product control relationship defined in the first step, and the photoelectric signal is changed to realize the original unit pixel luminance value Yraw, so that the corresponding vein region pixel luminance evaluation value Ysp satisfies Yll ⁇ Ysp ⁇ Yhl's preset conditions.
  • the present invention also provides a method for performing security authentication using the above-described vein recognition imaging module for a mobile terminal, comprising the following steps:
  • the processor chip 5 configured with the security mode is connected to acquire the digitized vein image output by the image imaging sensor 15 (the vein image is acquired through the above steps 1, 2, and 3, and converted into a digitized vein image);
  • the processor chip 5 configured with the security mode performs a vein recognition algorithm and extracts vein characteristic information
  • the processor chip 5 configuring the security mode generates a vein feature template by using the vein feature information
  • the three vein feature templates are obtained for cross-certification comparisons of 1-2, 1-3, and 2-3, respectively; if the 2-3 authentication comparison results are the worst, then 1 is the best result for the specific vein feature template.
  • Standard vein feature template
  • the standard vein feature template is encrypted by a cryptographic system and stored in a processor chip configured in a secure mode as a key, and is guaranteed to be never exported and accessed;
  • the identity authentication comparison of the vein feature template is performed inside the processor chip 5 configured with the security mode, ensuring that the mobile terminal is safe from external attacks during the entire process of identity authentication.
  • the cryptography system is a known technique. As a whole purpose of the security authentication of the mobile terminal, the above method is indispensable.

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Abstract

A vein recognition imaging device for security authentication of a mobile terminal. The vein recognition imaging device comprises a vein recognition imaging device disposed on a mobile terminal. The mobile terminal comprises a processor chip (5) and the like. The vein recognition imaging device is composed of a near-infrared LED illumination light source and a vein recognition imaging module optical component (1). The near-infrared LED illumination light source is driven by a near-infrared LED current driver (2). The vein recognition imaging module optical component comprises a near-infrared optical filter (11, 14) used for filtering scattered and reflected light rays of an irradiation light source of the near-infrared LED illumination light source, an optical imaging lens (12) used for focusing the light rays filtered by the near-infrared optical filter, an image imaging sensor (15) used for imaging the light rays focused by the optical imaging lens, and a vein recognition imaging module substrate (16) used for conducting signal transmission on images of the image imaging sensor. The processor chip (5) is in signal connection with the near-infrared LED current driver (2) and the vein recognition imaging module substrate (16).

Description

用于移动终端安全认证的静脉识别成像装置及方法Vein recognition imaging device and method for mobile terminal safety certification 技术领域Technical field
本发明涉及光机电领域,尤其是一种用于移动终端安全认证的静脉识别成像装置及其控制方法。The invention relates to the field of opto-mechatronics, in particular to a vein recognition imaging device for mobile terminal safety certification and a control method thereof.
背景技术Background technique
移动终端包括智能手机、平板、可穿戴设备等,案子现在的信息技术移动化发展趋势来看,移动终端设备必然是未来适用最广泛的设备。Mobile terminals include smart phones, tablets, wearable devices, etc. In the current trend of information technology mobileization, mobile terminal devices are inevitably the most widely used devices in the future.
目前,现实应用中的移动终端在移动安全支付、账户安全登陆、网上银行方面运用已经极其的广泛了,如余额宝(APP)、微信(APP)、***管理(APP)等方面的运用,虽然在其使用过程中,为生活带来了极大的便利,但是一种新型的通过移动终端安全性能薄弱等特点进行的***逐渐的兴起。At present, mobile terminals in real-world applications have been widely used in mobile secure payment, account secure login, and online banking, such as the application of balance treasure (APP), WeChat (APP), and credit card management (APP). In the course of its use, it has brought great convenience to life, but a new type of economic crime caused by the weak security features of mobile terminals has gradually emerged.
而移动终端中,现有技术进行身份确认的惯用手段就是密码输入,但是这种身份确认的手段安全性能十分的低,只需要在移动终端上植入简单的病毒程序,就能将该密码泄露,造成相应的损失。为了解决这个问题,国际上还是用生物识别的方式进行移动终端安全身份认证;如苹果公司提出的基于AuthenTec公司开发的指纹识别技术,该技术运用在手机终端上,极大的提高了移动终端的身份确认安全性;但是,指纹技术识别的过程中,由于指纹是静态的,虽然具有单一性,但是也极其容易被获取指纹信息,甚至被仿制等,所以,随着指纹技术在移动终端上的运用越来越广泛,其安全性也会相应的呈下降趋势,所以,在安全性方面更加具有优势的生物识别(静脉识别)是解决移动终端安全身份认证过程中非常有效的方法,而静脉识别***是现有的生物识别中安全活体防伪特征最为安全的。In mobile terminals, the conventional method for identity verification in the prior art is password input, but the means of identity verification is very low in security, and only a simple virus program needs to be implanted on the mobile terminal to leak the password. , causing corresponding losses. In order to solve this problem, the biometric identification method is used for mobile terminal security identity authentication; for example, the fingerprint recognition technology developed by Apple based on AuthenTec, which is applied to mobile phone terminals, greatly improves the mobile terminal. Identity verification security; however, in the process of fingerprint technology identification, since the fingerprint is static, although it is singular, it is extremely easy to obtain fingerprint information, even being copied, etc., so with the fingerprint technology on the mobile terminal As the application becomes more and more extensive, its security will also decline accordingly. Therefore, biometrics (vein recognition), which is more advantageous in terms of security, is a very effective method to solve the mobile identity authentication process, and vein recognition. The system is the safest way to secure the living body in the existing biometrics.
目前所有静脉识别***技术和产品中,最典型的如日本日立手指静脉识别,采用固定接触式结构座的透射成像方式决定其体积和结构无法被用于移动终端中8mm*8mm*6mm的通用标准尺寸;再如日本富士通手掌静脉识别,其也存在远大于移动终端中的通用标准尺寸的缺陷,且工作距离仅4-6cm,在如此短工作范围根本无法使用,使用实际上也需要依靠附加的固定接触式结构座才能使用。Among all the vein identification system technologies and products, the most typical ones are Japanese Hitachi finger vein recognition, and the transmission imaging method using a fixed contact structure seat determines that the volume and structure cannot be used for the common standard of 8mm*8mm*6mm in mobile terminals. Size; like Japan Fujitsu palm vein recognition, it also has a defect far larger than the common standard size in the mobile terminal, and the working distance is only 4-6cm, it can not be used in such a short working range, and the use actually needs to rely on additional The fixed contact structure can only be used.
并且,目前所有静脉识别***技术和产品中,都在室内,并且通过采用的固定接触式结构座限制工作距离,严格控制了使用场景环境光照度和用户手指或手掌手背运动模糊,基本上都不能满足移动终端上的使 用标准。Moreover, all current vein recognition system technologies and products are indoors, and the working distance is limited by the fixed contact structure seat adopted, and the illumination illuminance of the use scene environment and the motion blur of the back of the user's finger or palm are strictly controlled, which basically cannot satisfy Make on the mobile terminal Use the standard.
更进一步的,应用于移动终端还存在以下更严重的问题:Further, the following more serious problems apply to mobile terminals:
1、移动终端使用过程中,用户通常是手持的,而且需要在移动行进中识别,存在使用时非常大不可预测的手指或手掌手背运动模糊,其严重影响图像质量。1. During the use of the mobile terminal, the user is usually hand-held, and needs to be recognized during the moving travel. There is a very large and unpredictable movement of the finger or palm back of the hand, which seriously affects the image quality.
2、用户识别时使用场景是无法预测的,其使用环境光照度从室内完全黑暗0Lux到室外太阳直射100,000Lux都有可能,其环境杂光同样严重影响图像质量。2, the use of the scene when the user is unpredictable, the use of ambient light from the indoor complete dark 0Lux to outdoor direct sunlight 100,000Lux is possible, its ambient stray light also seriously affects the image quality.
3、移动终端的使用场景决定其结构无法采用固定接触式,不可能通过附加固定接触式结构来使用,既只能通过非接触式实现。3. The usage scenario of the mobile terminal determines that the structure cannot be fixed contact type, and it is impossible to use it by attaching a fixed contact structure, which can only be realized by non-contact type.
4、移动终端是电池供电的,其对静脉识别成像模组的光源功耗要求非常高。4. The mobile terminal is battery-powered, and its power consumption for the vein recognition imaging module is very high.
5、静脉识别光学成像模组的小型化,体积符合移动终端中8mm*8mm*6mm的通用标准尺寸。5. The miniaturization of the vein recognition optical imaging module is in accordance with the general standard size of 8mm*8mm*6mm in the mobile terminal.
6、需要一套安全的身份认证流程实现。6. A secure identity authentication process is required.
解决以上问题是目前技术面临的最大挑战。Solving the above problems is the biggest challenge facing the current technology.
发明内容Summary of the invention
本发明要解决的技术问题是提供一种用于移动终端安全身份认证的静脉识别成像模组及其控制方法。The technical problem to be solved by the present invention is to provide a vein recognition imaging module for mobile terminal security identity authentication and a control method thereof.
为了解决上述技术问题,本发明提供一种用于移动终端安全认证的静脉识别成像装置,包括设置在移动终端上的静脉识别成像装置;该移动终端包括移动终端主板、处理器芯片、内存、存储器、电源管理模块以及无线基带模块;所述静脉识别成像装置由近红外LED照明光源和静脉识别成像模组光学部件构成;所述近红外LED照明光源通过近红外LED电流驱动器驱动;所述静脉识别成像模组光学部件包括对近红外LED照明光源照射光源散射、反射后的光线进行过滤的近红外光学滤光器,对近红外光学滤光器过滤后的光线进行聚焦的光学成像透镜、对通过光学成像透镜聚焦的光线成像的图像成像传感器,以及将图像成像传感器的图像进行信号传输的静脉识别成像模组基板;所述处理器芯片分别与近红外LED电流驱动器和静脉识别成像模组基板信号连接。In order to solve the above technical problem, the present invention provides a vein recognition imaging apparatus for mobile terminal security authentication, comprising a vein recognition imaging apparatus disposed on a mobile terminal; the mobile terminal includes a mobile terminal motherboard, a processor chip, a memory, and a memory a power management module and a wireless baseband module; the vein recognition imaging device is composed of a near-infrared LED illumination source and a vein recognition imaging module optical component; the near-infrared LED illumination source is driven by a near-infrared LED current driver; the vein recognition The imaging module optical component comprises a near-infrared optical filter for filtering the reflected light of the near-infrared LED illumination source and filtering the reflected light, and an optical imaging lens for focusing the filtered light of the near-infrared optical filter, An image imaging sensor for focusing an optical imaging lens, and a vein recognition imaging module substrate for transmitting an image of the image imaging sensor; the processor chip and the near-infrared LED current driver and the vein recognition imaging module substrate signal respectively connection.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的改进:所述近红外LED照明光源为表面贴片封装;所述近红外LED电流驱动器驱动近红外LED照明光源输出最高辐射强度I短时间T脉冲周期时序发射光;所述近红外LED照明光源输出最高辐射强度I短时间T脉冲周期时序同步图像成像传感器帧像素全局触发曝光的周期时序;所述近红外LED照明光源的发射光的半峰值辐射或发散角度大于等于光学成 像透镜的成像视场角FOV;所述光学成像透镜固定聚焦透镜、液体驱动透镜、液晶驱动透镜、VCM音圈驱动透镜、MEMS驱动透镜、EDOF相位波前编码透镜、WLA晶圆级透镜阵列中的任意一种;所述近红外光学滤光器的半峰值透射波长带宽FWHM有效匹配或覆盖近红外LED照明光源发射光的半峰值辐射波长带宽FWHM;所述近红外光学滤光器包括前焦近红外光学滤光器和/或后焦近红外光学滤光器;所述处理器芯片为配置安全模式的处理器芯片。An improvement of the vein recognition imaging device for mobile terminal security authentication according to the present invention: the near-infrared LED illumination source is a surface patch package; and the near-infrared LED current driver drives a near-infrared LED illumination source to output a maximum radiation intensity I short-time T-pulse periodic timing emission light; the near-infrared LED illumination source outputs the highest radiation intensity I short time T pulse period timing synchronization image imaging sensor frame pixel global trigger exposure cycle timing; the near-infrared LED illumination source emission The half-peak radiation or divergence angle of light is greater than or equal to optical Imaging angle of view FOV of the lens; the optical imaging lens fixed focus lens, liquid drive lens, liquid crystal drive lens, VCM voice coil drive lens, MEMS drive lens, EDOF phase wavefront coding lens, WLA wafer level lens array Any one of the half-peak transmission wavelength bandwidths FWHM of the near-infrared optical filter effectively matching or covering a half-peak radiation wavelength bandwidth FWHM of the light emitted by the near-infrared LED illumination source; the near-infrared optical filter including the front focus a near-infrared optical filter and/or a back-focus near-infrared optical filter; the processor chip is a processor chip configured in a secure mode.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的进一步改进:所述的近红外LED照明光源中心峰值波长范围750-880nm,FWHM为30-60nm;所述近红外光学滤光器中心峰值波长范围750-880nm,FWHM为10-60nm;所述近红外光学滤光器为窄带近红外光学滤光器或者带通近红外光学滤光器中的任意一种;所述光学成像透镜的视场角FOV具有如下的取值范围:FOV≥2*arctan((DOI*SOP)/(2*EFL));所述DOI为图像成像传感器的对角线像素数量;SOP为图像成像传感器单位像素的物理尺度;EFL为光学成像透镜的等效焦距值。Further improvement of the vein recognition imaging device for mobile terminal safety authentication according to the present invention: the near-infrared LED illumination source has a center peak wavelength range of 750-880 nm and a FWHM of 30-60 nm; the near-infrared optical filter The center of the device has a peak wavelength range of 750-880 nm and a FWHM of 10-60 nm; the near-infrared optical filter is any one of a narrow-band near-infrared optical filter or a band-pass near-infrared optical filter; the optical imaging The field of view FOV of the lens has the following range of values: FOV ≥ 2 * arctan ((DOI * SOP) / (2 * EFL)); the DOI is the number of diagonal pixels of the image imaging sensor; SOP is image imaging The physical scale of the sensor unit pixel; EFL is the equivalent focal length value of the optical imaging lens.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的进一步改进:所述近红外LED照明光源上设置有用于提供均匀的发射或辐射照明光场的光学漫射散射器。A further improvement of the vein recognition imaging apparatus for mobile terminal security authentication according to the present invention is that the near-infrared LED illumination source is provided with an optical diffusing diffuser for providing a uniform emission or radiation illumination light field.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的进一步改进:所述光学漫射散射器为光学发散镜。A further improvement of the vein recognition imaging apparatus for mobile terminal security authentication according to the present invention is that the optical diffusing diffuser is an optical diverging mirror.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的进一步改进:所述近红外LED照明光源设置光学线偏振器;对应于该光学线偏振器,在成像光路中设置对应的正交态90度光学线偏振器。A further improvement of the vein recognition imaging device for mobile terminal security authentication according to the present invention: the near-infrared LED illumination source is provided with an optical linear polarizer; corresponding to the optical linear polarizer, a corresponding positive is set in the imaging optical path A 90 degree optical linear polarizer.
作为对本发明所述的用于移动终端安全认证的静脉识别成像装置的进一步改进:所述移动终端上设置有使用状态引导提示装置;所述使用状态引导提示装置包括语音装置、指示灯和液晶屏;所述语音装置、指示灯和液晶屏与处理器芯片信号连接。Further improvement of the vein recognition imaging device for mobile terminal security authentication according to the present invention: the mobile terminal is provided with a use state guiding prompt device; the use state guiding prompt device includes a voice device, an indicator light, and a liquid crystal screen The voice device, the indicator light, and the liquid crystal screen are connected to the processor chip signal.
利用移动终端的静脉识别成像模组进行安全认证的方法:包括如下的步骤:1)、处理器芯片获取图像成像传感器输出的数字化静脉图像;2)、处理器芯片进行静脉识别算法执行提取静脉特征信息;3)、处理器芯片通过静脉特征信息生成静脉特征模板;4)、通过循环步骤1)至3)获得至少2个或以上的静脉特征模板,进行静脉特征模板间交叉认证比对,以交叉认证比对后最佳结果的特定静脉特征模板为标准静脉特征模板;5)、该标准静脉特征模板采用密码学体系加密后存储在配置处理器芯片内做为密钥,并保证从不被导出和访问;6)、静脉特征模板的身份认证比对都在处理器芯片内部进行,确保移动终端在身份认证整个过程安全不被外部攻击。 The method for performing safety authentication using the vein recognition imaging module of the mobile terminal comprises the following steps: 1) the processor chip acquires a digital vein image output by the image imaging sensor; 2) the processor chip performs a vein recognition algorithm to perform extraction of the vein feature 3), the processor chip generates a vein feature template through the vein feature information; 4) obtains at least 2 or more vein feature templates through the cycle steps 1) to 3), and performs cross-certification comparison between the vein feature templates to The specific vein feature template of the best result after the cross-certification comparison is a standard vein feature template; 5) the standard vein feature template is encrypted by the cryptographic system and stored in the configuration processor chip as a key, and is guaranteed to be never Export and access; 6), the identity authentication of the vein feature template is performed inside the processor chip, ensuring that the mobile terminal is safe from external attacks during the entire identity authentication process.
作为对本发明所述的利用移动终端的静脉识别成像模组进行安全认证的方法的改进:所述图像成像传感器输出的数字化静脉图像通过如下步骤获取:1.1)、定义静脉识别成像模组原始的单位像素亮度值Yraw的光电信号;1.2)、定义静脉区域像素亮度统计评估值Ysp;1.3)、实现静脉区域像素亮度统计评估值Ysp在预设的[Yll,Yhl]亮度范围。An improvement of the method for performing safety authentication on the vein recognition imaging module using the mobile terminal according to the present invention: the digitized vein image output by the image imaging sensor is obtained by the following steps: 1.1) defining the original unit of the vein recognition imaging module The photoelectric signal of the pixel brightness value Yraw; 1.2) defines the pixel area luminance statistical evaluation value Ysp; 1.3), and realizes the vein area pixel brightness statistical evaluation value Ysp in the preset [Yll, Yhl] brightness range.
作为对本发明所述的利用移动终端的静脉识别成像模组进行安全认证的方法的进一步改进:步骤1.1)中,通过周期时序同步于近红外LED照明光源短时间T脉冲周期时序的图像成像传感器的帧像素全局触发曝光时间或积分时间T、近红外照明光源最高辐射强度I、图像成像传感器的模拟增益GAIN、光学成像透镜固定光圈或相对孔径倒数的常数F以及固定光电信号转化率常数C确定Yraw;Yraw=C*T*GAIN*I*(1/F)2;所述T≤3.33ms;所述I≥10mW/sr;所述GAIN的最大值产生的图像成像传感器信噪比SNR≥38db;所述F的取值范围为:F=EFL/D或者0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ),所述D为光学成像透镜的光瞳或通光孔径的直径,FEL为光学成像透镜的等效焦距值,SOP为图像成像传感器单位像素的物理尺度,λ为近红外LED照明光源等效峰值波长;步骤1.2)中,所述Ysp=S(Yraw);所述的S(Yraw)为静脉区域像素亮度统计评估函数,所述像素亮度统计评估函数采用的方法包括像素亮度直方图统计、像素亮度频谱统计、像素亮度平均值、像素亮度加权平均值或者像素亮度中值等;步骤1.3)中,所述通过T、I和GAIN的光电信号处理控制,静脉区域像素亮度统计评估值Ysp预设的[Yll,Yhl]亮度范围为:Yll≤Ysp≤Yhl;所述Yll为静脉区域像素亮度下限,Yhl为静脉区域像素亮度上限;所述的光电信号处理控制为根据步骤1中的公式线性乘积控制关系,改变光电信号,实现原始的单位像素亮度值Yraw改变,使相应的静脉区域像素亮度统计评估值Ysp满足Yll≤Ysp≤Yhl的预设条件。Further improvement of the method for performing safety authentication on the vein recognition imaging module using the mobile terminal according to the present invention: in step 1.1), the image imaging sensor is synchronized with the near-infrared LED illumination source by the cycle timing for a short time T pulse period timing Frame pixel global trigger exposure time or integration time T, near-infrared illumination source maximum radiation intensity I, image imaging sensor analog gain GAIN, optical imaging lens fixed aperture or relative aperture reciprocal constant F and fixed photoelectric signal conversion rate constant C determine Yraw ; Yraw=C*T*GAIN*I*(1/F) 2 ; the T≤3.33ms; the I≥10mW/sr; the image imaging sensor SNR≥38db generated by the maximum value of the GAIN The value range of F is: F=EFL/D or 0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ), which is the aperture or pass of the optical imaging lens The diameter of the optical aperture, FEL is the equivalent focal length value of the optical imaging lens, SOP is the physical scale of the image imaging sensor unit pixel, and λ is the equivalent peak wavelength of the near-infrared LED illumination source; in step 1.2), the Ysp=S ( Yraw); the S (Yraw) is static The area pixel brightness statistical evaluation function, the method used by the pixel brightness statistical evaluation function includes pixel brightness histogram statistics, pixel brightness spectrum statistics, pixel brightness average, pixel brightness weighted average or pixel brightness median, etc.; in step 1.3) The photoelectric signal processing control by T, I, and GAIN, the [Yll, Yhl] luminance range preset by the venous region pixel luminance statistical evaluation value Ysp is: Yll ≤ Ysp ≤ Yhl; the Yll is the lower limit of the pixel region radiance Yhl is the upper limit of the pixel brightness of the venous region; the photoelectric signal processing control is based on the linear product control relationship of the formula in step 1, changing the photoelectric signal, realizing the original unit pixel brightness value Yraw change, so that the corresponding venous area pixel brightness statistics The evaluation value Ysp satisfies the preset condition of Yll ≤ Ysp ≤ Yhl.
总结上述描述,本发明的实现了以下的移动终端使用场景要求达到的效果:Summarizing the above description, the present invention achieves the following effects required by the mobile terminal usage scenario:
1、能够在用户以自主每秒0-1米(m/s)的移动速度中识别。1. It can be identified by the user at a moving speed of 0-1 m (s/s) per second.
2、用户识别时使用环境光照度要求满足从室内完全黑暗0Lux到室外太阳直射100,000Lux。2. The ambient light level required for user identification is required to satisfy 100,000 Lux from the indoor complete dark 0Lux to the outdoor direct sunlight.
3、静脉识别成像模组实现非接触式的采集使用,无需附加固定接触式结构来使用。3. The vein recognition imaging module realizes non-contact collection and use, and does not need to be attached with a fixed contact structure.
4、静脉识别成像模组的光源功耗消耗低。4. The power consumption of the light source of the vein recognition imaging module is low.
5、静脉识别成像模组的体积小型化。5. The volume of the vein recognition imaging module is miniaturized.
6、安全的身份认证流程。 6, a secure identity authentication process.
附图说明DRAWINGS
下面结合附图对本发明的具体实施方式作进一步详细说明。The specific embodiments of the present invention are further described in detail below with reference to the accompanying drawings.
图1为本发明具体实施例1静脉识别成像模组总体结构图;1 is a general structural diagram of a vein recognition imaging module according to a specific embodiment of the present invention;
图2为本发明具体实施例1静脉识别成像模组光学部件结构图;2 is a structural diagram of an optical component of a vein recognition imaging module according to a specific embodiment of the present invention;
图3为本发明具体实施例1静脉识别成像模组安装在移动智能手机背面示意图;3 is a schematic diagram of a vein identification imaging module mounted on the back of a mobile smart phone according to a specific embodiment of the present invention;
图4为本发明具体实施例1红外LED照明光源产生的最高辐射强度短时间脉冲周期时序同步成像传感器帧像素全局触发曝光(积分)的周期时序原理图。4 is a timing sequence diagram of a frame pixel global trigger exposure (integration) of a maximum radiation intensity short-time pulse period timing synchronization imaging sensor generated by an infrared LED illumination source according to a specific embodiment of the present invention.
具体实施方式detailed description
实施例1、图1给出了一种用于移动终端安全认证的静脉识别成像装置,包括设置在移动终端上的静脉识别成像模组光学部件1、近红外LED电流驱动器2、近红外LED照明光源3和静脉识别成像模组连接线4;移动终端包括移动终端主板10、处理器芯片5、内存6、存储器7、电源管理8以及无线基带模块9。处理器芯片5为配置TrustZone的安全隔离模式的ARM CORTEX—A处理器芯片;内存6为DDR内存;存储器7为NAND FLASH存储器;电源管理8为PMIC电源管理模块。以上的移动终端主板10、处理器芯片5、内存6、存储器7、电源管理8以及无线基带模块9均可以通过市场购置并组装。 Embodiment 1, FIG. 1 shows a vein recognition imaging device for mobile terminal security authentication, comprising a vein recognition imaging module optical component 1, a near-infrared LED current driver 2, and a near-infrared LED illumination disposed on the mobile terminal. The light source 3 and the vein recognition imaging module connection line 4; the mobile terminal comprises a mobile terminal motherboard 10, a processor chip 5, a memory 6, a memory 7, a power management 8 and a wireless baseband module 9. The processor chip 5 is an ARM CORTEX-A processor chip configured with TrustZone's secure isolation mode; the memory 6 is DDR memory; the memory 7 is NAND FLASH memory; and the power management 8 is a PMIC power management module. The above mobile terminal motherboard 10, processor chip 5, memory 6, memory 7, power management 8 and wireless baseband module 9 can all be purchased and assembled by the market.
近红外LED照明光源3连接近红外LED电流驱动器2,通过近红外LED电流驱动器2驱动近红外LED照明光源3产生输出最高辐射强度I短时间T的脉冲周期时序发射光;此处,在选择近红外LED照明光源3的时候,采用表面贴片封装(SMD)形式以减小体积【采用的是表面贴片封装(SMD)近红外LED照明光源】。The near-infrared LED illumination source 3 is connected to the near-infrared LED current driver 2, and the near-infrared LED illumination source 2 is driven by the near-infrared LED current driver 2 to generate a pulse period-time emission light that outputs the highest radiation intensity I for a short time T; here, in the selection In the case of infrared LED illumination source 3, the surface mount package (SMD) is used to reduce the volume [using a surface mount package (SMD) near-infrared LED illumination source].
移动终端主板10与静脉识别成像模组光学部件1和近红外LED电流驱动器2之间通过静脉识别成像模组连接线4相互信号连接;实现包括像素时钟、像素数据、像素数据同步信号、I2C通讯、近红外LED电流驱动器2驱动近红外LED照明光源3的控制信号传输等。The mobile terminal board 10 and the vein recognition imaging module optical component 1 and the near-infrared LED current driver 2 are mutually connected by a vein identification imaging module connection line 4; the implementation includes a pixel clock, pixel data, pixel data synchronization signal, and I2C communication. The near-infrared LED current driver 2 drives the control signal transmission of the near-infrared LED illumination source 3.
移动终端主板10集成配置TrustZone的安全隔离模式ARM CORTEX—A处理器芯片5(用于执行所有控制、识别、应用的数据处理计算)、DDR内存6(用于提供处理器芯片5处理计算所需的内存)、NAND FLASH存储器7(用于存储所有必需的断电可保存数据)、PMIC电源管理8(提供对移动终端主板10的各级电源供电)以及无线基带模块9(用于无线通讯应用);通过如上的设置,移动终端主板10实现对本发明所述静脉识别成像模组的控制和安全身份认证。Mobile terminal board 10 integrated configuration TrustZone security isolation mode ARM CORTEX-A processor chip 5 (for performing all control, identification, application data processing calculation), DDR memory 6 (used to provide processor chip 5 processing calculations required Memory), NAND FLASH memory 7 (for storing all necessary power-down saveable data), PMIC power management 8 (providing power to all levels of the mobile terminal board 10) and wireless baseband module 9 (for wireless communication applications) By setting as above, the mobile terminal motherboard 10 implements control and secure identity authentication of the vein recognition imaging module of the present invention.
静脉识别成像模组光学部件1用于非接触式的物理成像以采集手指 手掌手背静脉图像。如图2所示,静脉识别成像模组光学部件1的具体结构包括以下部分组成:前焦近红外光学滤光器11、固定焦距的光学成像透镜12、光学成像透镜的固定安装座13、后焦近红外光学滤光器14、图像成像传感器15和静脉识别成像模组基板16。静脉识别成像模组基板16上从下至上依次设置图像成像传感器15、后焦近红外光学滤光器14、光学成像透镜的固定安装座13、固定焦距的光学成像透镜12以及前焦近红外光学滤光器11。Vein recognition imaging module optical component 1 for non-contact physical imaging to collect fingers The back vein image of the palm of the hand. As shown in FIG. 2, the specific structure of the vein identification imaging module optical component 1 comprises the following components: a front focus near-infrared optical filter 11, a fixed focal length optical imaging lens 12, a fixed mount of the optical imaging lens 13, and a rear. A focal near infrared optical filter 14, an image imaging sensor 15, and a vein recognition imaging module substrate 16. The image recognition sensor 15 , the back focus near-infrared optical filter 14 , the fixed mount 13 of the optical imaging lens, the optical imaging lens 12 with a fixed focal length, and the front focal near infrared optics are sequentially disposed from the bottom to the top of the vein recognition imaging module substrate 16 . Filter 11.
静脉识别成像模组基板16为印刷线路板、柔性线路板或软硬结合板构成,用于提供静脉识别成像模组光学部件1整体安装的固定结构载体。光学成像透镜的固定安装座13用于安装固定焦距的光学成像透镜12。The vein recognition imaging module substrate 16 is composed of a printed circuit board, a flexible circuit board or a soft and hard bonding board, and is used for providing a fixed structure carrier in which the optical component 1 of the vein recognition imaging module is integrally mounted. The fixed mount 13 of the optical imaging lens is used to mount a fixed focal length optical imaging lens 12.
目前高度成熟的移动终端部件设计生产制造工艺已经能实现静脉识别成像模组光学部件1中的各个光学部件微型化,采用成熟的本专业技术领域设计生产制造工艺静脉识别成像模组完全能满足移动终端8mm*8mm*6mm的通用标准尺寸。At present, the highly mature mobile terminal component design and manufacturing process can realize the miniaturization of each optical component in the optical component 1 of the vein recognition imaging module, and adopts the mature technical field of the art to design and manufacture the vein identification imaging module to fully satisfy the movement. Universal standard size of terminal 8mm*8mm*6mm.
近红外LED照明光源3辐射的近红外光在物方静脉进行吸收、散射、反射的光学生物效应后,进入前焦近红外光学滤光器11和/或后焦近红外光学滤光器14(此处,包括前焦近红外光学滤光器11和/或后焦近红外光学滤光器14同时存在、前焦近红外光学滤光器11单独存在或者后焦近红外光学滤光器14单独存在的三种可能,这三种近红外光学滤光器的设置方式均可以为本发明的最佳案例)进行非成像干扰光过滤,然后进入固定焦距的光学成像透镜12;固定焦距的光学成像透镜12为自动聚焦AF光学成像透镜或固定聚焦光学成像透镜,用于实现非接触式的光学物理聚焦到位于像方的图像成像传感器15,使图像光信号转换图像电信号输出,最后通过静脉识别成像模组连接线4连接移动终端主板10,实现通过处理器芯片5控制本发明所述的静脉识别成像模组。The near-infrared light radiated by the near-infrared LED illumination source 3 enters the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 after the optical biological effect of absorption, scattering, and reflection of the object square vein ( Here, the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are simultaneously present, the front focus near-infrared optical filter 11 is alone or the back focus near-infrared optical filter 14 is separate. There are three possibilities, the three NIR optical filters can be set in the best case of the invention for non-imaging interference light filtering, then enter the fixed focal length optical imaging lens 12; fixed focal length optical imaging The lens 12 is an autofocus AF optical imaging lens or a fixed focus optical imaging lens for realizing non-contact optical physical focusing to the image imaging sensor 15 located at the image side, causing the image optical signal to be converted into an image electrical signal output, and finally by vein recognition. The imaging module connection line 4 is connected to the mobile terminal motherboard 10, and the vein recognition imaging module of the present invention is controlled by the processor chip 5.
本发明的静脉识别成像模组还设置有使用状态引导提示装置。使用状态引导提示装置包括语音提示装置(扬声器)、指示灯以及液晶屏,用于指示用户使用时状态引导,如手指手掌手背放置位置和距离、识别结果反馈等。The vein recognition imaging module of the present invention is further provided with a use state guiding prompting device. The use state guiding prompting device includes a voice prompting device (speaker), an indicator light, and a liquid crystal screen for indicating a state guiding when the user uses, such as a finger palm back placement position and distance, recognition result feedback, and the like.
以上所述的近红外LED照明光源3的中心峰值波长范围为750-880nm,FWHM为30-60nm;前焦近红外光学滤光器11和/或后焦近红外光学滤光器14的中心峰值波长范围750-880nm,FWHM为10-60nm;包括窄带近红外光学滤光器,带通近红外光学滤光器(即,前焦近红外光学滤光器11和/或后焦近红外光学滤光器14可以为窄带近红外光学滤光器或者带通近红外光学滤光器)。前焦近红外光学滤光器11和/或后焦近红外光学滤光器14采用光学透明玻璃,如BK7或有色玻璃或光学树脂等光学材料进行表面镀膜,目前的镀膜工艺和技术能实现背景深度截止率或 信噪比SNR(SNR:signal-to-noise ratio)≥60dB(1000:1)。前焦近红外光学滤光器11和/或后焦近红外光学滤光器14过滤用于成像的波长,使成像波长与非成像的背景干扰杂散光的信噪比SNR(SNR:signal-to-noise ratio)满足:≥60dB(1000:1)。The near-infrared LED illumination source 3 described above has a center peak wavelength range of 750-880 nm, a FWHM of 30-60 nm, and a center peak of the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14. Wavelength range 750-880nm, FWHM 10-60nm; including narrow-band near-infrared optical filter, band-pass near-infrared optical filter (ie, front focus near-infrared optical filter 11 and / or back focus near-infrared optical filter The lighter 14 can be a narrowband near-infrared optical filter or a bandpass near-infrared optical filter). The front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are coated with an optically transparent glass such as BK7 or an optical material such as colored glass or optical resin, and the current coating process and technology can achieve the background. Depth cutoff rate or Signal-to-noise ratio SNR (SNR: signal-to-noise ratio) ≥ 60 dB (1000: 1). The front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 filters the wavelength used for imaging such that the imaging wavelength interferes with the non-imaged background by the signal-to-noise ratio SNR of the stray light (SNR: signal-to -noise ratio) Satisfaction: ≥60dB (1000:1).
在使用的过程中,环境非成像干扰光和运动干扰是现有技术中的静脉识别技术无法运用到移动终端的上的一个技术难题。环境非成像干扰光(即是非成像的背景干扰杂散光)是指:用户识别时使用环境光照度要求满足从室内完全黑暗(0Lux)到室外太阳直射(100,000Lux)所说的自然光。使用环境中不同光照度的非成像的干扰杂散光严重影响静脉图像质量;光照度越大静脉图像质量影响越大。使用者操作使用时不同移动速度会引起运动模糊,会严重影响静脉图像质量;移动速度越大静脉图像质量影响越大。In the process of use, environmental non-imaging interference light and motion interference is a technical problem that the vein identification technology in the prior art cannot be applied to the mobile terminal. Ambient non-imaging interference light (ie, non-imaging background interference stray light) means that the ambient light used by the user to identify the natural light from the complete darkness (0Lux) to the outdoor direct sunlight (100,000Lux). Non-imaging interference stray light with different illumination levels in the environment seriously affects the quality of vein image; the greater the illumination, the greater the influence of vein image quality. When the user operates, different moving speeds will cause motion blur, which will seriously affect the quality of the vein image; the greater the moving speed, the greater the influence of the vein image quality.
为克服以上的技术难题,本发明采用以下的设计:To overcome the above technical problems, the present invention adopts the following design:
近红外LED照明光源3与图像成像传感器15被组合配置如下:The near-infrared LED illumination source 3 and the image imaging sensor 15 are combined and configured as follows:
近红外LED照明光源3产生的最高辐射强度I短时间T脉冲周期时序同步图像成像传感器15帧像素全局触发曝光(积分)的周期时序;The highest radiation intensity generated by the near-infrared LED illumination source 3 is short time T pulse period timing synchronization image imaging sensor 15 frame pixel global trigger exposure (integration) cycle timing;
其中:among them:
T≤3.33ms(毫秒);T ≤ 3.33 ms (milliseconds);
I≥10mW/sr(毫瓦每球面度)。I ≥ 10 mW / sr (milliwatts per sphericity).
通过图4进一步解释了本发明中,具体实施例1近红外LED照明光源3产生的最高辐射强度短时间脉冲周期时序同步图像成像传感器15帧像素全局触发曝光(积分)的周期时序原理。The periodic timing principle of the frame-pixel global trigger exposure (integration) of the highest radiation intensity short-time pulse period timing synchronization image imaging sensor 15 produced by the near-infrared LED illumination source 3 of the specific embodiment 1 is further explained by FIG.
本发明的图像成像传感器15的同步周期时序帧像素全局触发曝光(积分)的方法,采用了仅在成像波长范围内和最高辐射强度短时间周期时序内对图像成像传感器15所有帧像素同步进行触发曝光(积分)。The method for synchronizing periodic timing frame pixel global trigger exposure (integration) of the image imaging sensor 15 of the present invention employs triggering all frame pixel synchronization of the image imaging sensor 15 only in the imaging wavelength range and the highest radiation intensity short time period sequence. Exposure (integration).
即使如电子滚动快门(ERS),其不同行的曝光周期时序是不一致的,但满足在成像波长范围内和最高辐射强度短时间周期时序内所有帧像素同步进行全局触发曝光(积分)的条件下,最高辐射强度短时间周期时序内与最高辐射强度短时间周期时序外的曝光(积分)光子信号累积量之比远大于1000:1,这样对于一般成像传感器ADC最有效分辨率仅为8位或10位,可以忽略。因此本方法适用于各类型成像传感器,如全局快门(global shutter),电子滚动快门(ERS)或全局释放快门GRS等,各种各类型成像传感器。Even if the electronic rolling shutter (ERS), the exposure cycle timing of different rows is inconsistent, but under the condition that the imaging triggers (integration) of all the frame pixels in the imaging wavelength range and the highest radiation intensity short time period timing are synchronized. The ratio of exposure (integral) photon signal accumulation outside the shortest time period of the highest radiation intensity to the highest radiation intensity is much greater than 1000:1, so that the most effective resolution for a typical imaging sensor ADC is only 8 bits or 10 digits can be ignored. Therefore, the method is applicable to various types of imaging sensors, such as a global shutter, an electronic rolling shutter (ERS) or a global release shutter GRS, and various types of imaging sensors.
采用近红外LED照明光源3产生的最高辐射强度I短时间T脉冲周期时序与图像成像传感器15帧像素全局触发曝光(积分)的周期时序同步的方法,这种同步脉冲周期时序的辐射和曝光方法是本发明重要优点特性。 The method of synchronizing the highest radiation intensity I generated by the near-infrared LED illumination source 3 with the short-time T-pulse period timing and the period timing of the image-imaging sensor 15 frame pixel global trigger exposure (integration), the synchronization pulse period timing radiation and exposure method It is an important advantage of the present invention.
由于是采用同步脉冲周期时序的辐射和曝光方法,按照其在1秒内产生(10次)每次3.33ms时间周期时序的辐射也只有不到10*(3.33ms/1s)=1/30的等效辐射量,所以如此设计的静脉识别光学成像模组其光源功耗消耗低,与传统连续辐射光源相比只有1/30的等效辐射量。Since it is a radiation and exposure method using synchronous pulse period timing, the radiation generated in accordance with its time period of 3.33 ms per time (10 times) is less than 10*(3.33ms/1s)=1/30. Equivalent radiation, so the vein recognition optical imaging module designed in this way has low power consumption of the light source and only 1/30 equivalent radiation compared with the conventional continuous radiation source.
特别强调传统连续周期时序的辐射和曝光方法只是本发明同步脉冲周期时序的辐射和曝光方法的特例,当其脉冲周期时序为100%占空比周期时序时的辐射和曝光等于连续周期时序辐射和曝光。如此设计能提高至少10倍的成像波长与非成像的干扰杂散光的信噪比SNR(SNR:signal-to-noise ratio)满足:≥80dB(10000:1)。使得本发明的静脉识别光学成像模组的使用环境光照度要求满足从室内完全黑暗(0Lux)到室外太阳直射(100,000Lux)。最高辐射强度短时间周期时序的帧像素同步全局触发曝光(积分)能完全消除最高1m/s的运动模糊,使静脉图像成像的移动速度要求满足从移动速度1m/s到完全静止的移动速度0cm/s。The radiation and exposure methods that emphasize the traditional continuous cycle timing are only a special case of the radiation and exposure methods of the synchronous pulse period timing of the present invention. When the pulse period is 100% duty cycle timing, the radiation and exposure are equal to the continuous period timing radiation and exposure. The SNR (SNR: signal-to-noise ratio) that is designed to increase the imaging wavelength by at least 10 times and the non-imaging interference stray light satisfies: ≥ 80 dB (10000: 1). The ambient illuminance requirements of the vein recognition optical imaging module of the present invention are such that it is from indoor complete darkness (0 Lux) to outdoor direct sunlight (100,000 Lux). High-radiation intensity short-time periodic timing frame pixel synchronization global trigger exposure (integration) can completely eliminate motion blur up to 1m/s, so that the moving speed of vein image imaging needs to meet the moving speed from moving speed 1m/s to completely static moving speed 0cm /s.
为实现获取亮度均衡的高质量静脉成像图像,除来自手指手掌手背表面的全反射光,近红外LED照明光源3与光学成像透镜12被组合配置如下:In order to achieve a high-quality vein image obtained by brightness equalization, in addition to the total reflected light from the back surface of the palm of the finger, the near-infrared LED illumination source 3 and the optical imaging lens 12 are combined and configured as follows:
近红外LED照明光源3的半峰值辐射或发散角度大于等于光学成像透镜12的成像视场角FOV。其中:光学成像透镜的视场角FOV具有如下的取值:The half-peak radiation or divergence angle of the near-infrared LED illumination source 3 is greater than or equal to the imaging field of view angle FOV of the optical imaging lens 12. Wherein: the field of view angle FOV of the optical imaging lens has the following values:
FOV≥2*arctan((DOI*SOP)/(2*EFL))FOV ≥ 2 * arctan ((DOI * SOP) / (2 * EFL))
以上公式内所述的DOI为图像成像传感器的对角线像素数量;SOP为图像成像传感器单位像素的物理尺度;FEL为光学成像透镜的等效焦距值。The DOI described in the above formula is the number of diagonal pixels of the image imaging sensor; the SOP is the physical scale of the image imaging sensor unit pixel; and the FEL is the equivalent focal length value of the optical imaging lens.
近红外LED照明光源3配置光学漫射散射器,用于提供均匀的发射或辐射照明光场,形成亮度分布均衡的静脉图像,有效减少来自手指手掌手背表面的全反射光。为了更进一步为减小体积,光学漫射散射器可配置为光学发散镜。The near-infrared LED illumination source 3 is provided with an optical diffusing diffuser for providing a uniform emission or radiation illumination field to form a vein image with a balanced brightness distribution, which effectively reduces total reflected light from the back surface of the palm of the hand. In order to further reduce the volume, the optical diffusing diffuser can be configured as an optical diverging mirror.
近红外LED照明光3源配置光学线偏振器,和成像光路中(光学成像透镜12前或后)配置对应的正交态90度光学线偏振器,通过发射和接收端形成正交态的线偏振器,能完全去除来自手指手掌手背表面的全反射光。The near-infrared LED illumination light source 3 is configured with an optical linear polarizer, and an orthogonal state 90-degree optical linear polarizer is disposed in the imaging optical path (front or rear of the optical imaging lens 12), and an orthogonal state line is formed through the transmitting and receiving ends. The polarizer completely removes the total reflected light from the back surface of the palm of the hand.
近红外LED照明光源3与前焦近红外光学滤光器11和/或后焦近红外光学滤光器14被配置如下:The near-infrared LED illumination source 3 and the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 are configured as follows:
前焦近红外光学滤光器11和/或后焦近红外光学滤光器14的半峰值透射波长带宽FWHM有效匹配或覆盖近红外LED照明光源3的半峰值辐射 波长带宽FWHM。如此设计可以获得最大限度的成像波长利用率,成像高质量的静脉图像。近红外LED照明光源中心峰值波长范围750-880nm,FWHM为30-60nm;近红外光学滤光器中心峰值波长范围750-880nm,FWHM为10-60nm。The half-peak transmission wavelength bandwidth FWHM of the front focus near-infrared optical filter 11 and/or the back focus near-infrared optical filter 14 effectively matches or covers the half-peak radiation of the near-infrared LED illumination source 3 Wavelength bandwidth FWHM. This design allows for maximum imaging wavelength utilization and imaging of high quality vein images. The near-infrared LED illumination source has a peak wavelength range of 750-880 nm and a FWHM of 30-60 nm; a near-infrared optical filter has a peak wavelength range of 750-880 nm and a FWHM of 10-60 nm.
所述固定焦距的光学成像透镜12选用固定聚焦透镜、液体驱动透镜、液晶驱动透镜、VCM音圈电机驱动透镜、MEMS微电机械***驱动透镜、EDOF波前编码透镜或者WLA晶圆级透镜阵列中任意一种。液体驱动透镜、液晶驱动透镜、VCM音圈驱动透镜、MEMS驱动透镜、EDOF相位波前编码透镜、WLA晶圆级透镜阵列被配置用于实现光学成像透镜的自动聚焦AF,自动聚焦能更进一步增加非接触式采集的工作距离和范围,使更易于使用操作。The fixed focal length optical imaging lens 12 is selected from the group consisting of a fixed focus lens, a liquid drive lens, a liquid crystal drive lens, a VCM voice coil motor drive lens, a MEMS microelectromechanical system drive lens, an EDOF wavefront code lens or a WLA wafer level lens array. Any one. Liquid drive lens, liquid crystal drive lens, VCM voice coil drive lens, MEMS drive lens, EDOF phase wavefront code lens, WLA wafer level lens array are configured to achieve autofocus AF of optical imaging lens, auto focus can be further increased The working distance and range of non-contact acquisition make it easier to use.
以上所述的具体实施列1的静脉识别成像模组安装在移动智能手机上,用户在使用时的状态如图3:移动智能手机背面100设置静脉识别成像模组光学部件1和表面贴片封装(SMD)近红外LED照明光源3。The vein identification imaging module of the specific implementation column 1 described above is installed on the mobile smart phone, and the state of the user in use is as shown in FIG. 3: the mobile phone back side 100 is provided with the vein recognition imaging module optical component 1 and the surface patch package. (SMD) near-infrared LED illumination source 3.
用户使用时,非接触方式放置其手指手掌手背在静脉识别成像模组光学部件1前方,近红外LED照明光源3提供对前方手指手掌手背的照明,近红外LED照明光源3辐射的近红外光在物方静脉进行吸收、散射,反射的光学生物效应后,进入静脉识别成像模组光学部件1实现非接触的光学物理聚焦到位于像方的图像成像传感器15使图像光信号转换图像电信号输出,过程如下:When the user uses the non-contact way, the palm of the hand is placed in front of the vein recognition imaging module optical component 1. The near-infrared LED illumination source 3 provides illumination to the front finger palm back, and the near-infrared LED illumination source 3 radiates near-infrared light. After the absorption and scattering of the object vein, and the optical biological effect of the reflection, the optical component 1 entering the vein recognition imaging module realizes non-contact optical physical focusing to the image imaging sensor 15 located at the image side to convert the image light signal into an image electrical signal output. The process is as follows:
一、定义静脉识别成像模组原始的单位像素亮度值Yraw的光电信号产生Yraw=C*T*GAIN*I*(1/F)2First, define the original unit pixel brightness value Yraw photoelectric signal of the vein recognition imaging module to generate Yraw=C*T*GAIN*I*(1/F) 2 ;
以上所述的T为图像成像传感器的帧像素全局触发曝光时间exposure time或积分时间integrationtime,其周期时序同步于近红外照明光源短时间T脉冲周期时序;T≤3.33ms(毫秒);The T described above is the frame pixel global trigger exposure time exposure time or integral time integrationtime of the image imaging sensor, and the cycle timing is synchronized with the short-time T pulse period timing of the near-infrared illumination source; T≤3.33ms (milliseconds);
以上所述的I为近红外照明光源最高辐射强度;I≥10mW/sr(毫瓦每球面度);The above I is the highest radiation intensity of the near-infrared illumination source; I≥10mW/sr (milliwatts per sphericity);
以上所述的GAIN为图像成像传感器的模拟增益;最大GAIN值产生的图像成像传感器信噪比SNR≥38db;The GAIN described above is the analog gain of the image imaging sensor; the image-to-noise ratio SNR of the image imaging sensor generated by the maximum GAIN value is ≥ 38db;
以上所述的F为光学成像透镜固定光圈或相对孔径倒数的常数;F=EFL/D0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ)The above F is the constant of the fixed aperture of the optical imaging lens or the reciprocal of the relative aperture; F=EFL/D0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ)
其中D为光学成像透镜的光瞳或通光孔径的直径,FEL为光学成像透镜的等效焦距值,SOP为图像成像传感器单位像素的物理尺度,λ为近红外LED照明光源等效峰值波长;Where D is the diameter of the aperture or clear aperture of the optical imaging lens, FEL is the equivalent focal length of the optical imaging lens, SOP is the physical scale of the image imaging sensor unit pixel, and λ is the equivalent peak wavelength of the near-infrared LED illumination source;
以上所述的C为静脉识别成像模组的固定光电信号转化率常数;The above C is the fixed photoelectric signal conversion rate constant of the vein recognition imaging module;
二、定义静脉区域像素亮度统计评估值Ysp,Ysp=S(Yraw);Second, define the statistical evaluation value of the pixel brightness of the vein area Ysp, Ysp = S (Yraw);
以上所述的S为静脉区域像素亮度统计评估函数,所述像素亮度统 计评估函数采用的方法包括:像素亮度直方图统计、像素亮度频谱统计、像素亮度平均值、像素亮度加权平均值或者像素亮度中值等;The S described above is a venous region pixel brightness statistical evaluation function, and the pixel brightness system The method used by the evaluation function includes: pixel luminance histogram statistics, pixel luminance spectrum statistics, pixel luminance average, pixel luminance weighted average, or pixel luminance median value;
三、通过T,I,GAIN光电信号处理控制,实现静脉区域像素亮度统计评估值Ysp在预设的[Yll,Yhl]亮度范围:Yll≤Ysp≤Yhl;Third, through the T, I, GAIN photoelectric signal processing control, to achieve the venous area pixel brightness statistical evaluation value Ysp in the preset [Yll, Yhl] brightness range: Yll ≤ Ysp ≤ Yhl;
以上所述的Yll为静脉区域像素亮度下限,Yhl为静脉区域像素亮度上限;Yll described above is the lower limit of the pixel brightness of the vein region, and Yhl is the upper limit of the pixel brightness of the vein region;
以上所述的光电信号处理控制为根据步骤一中定义的公式线性乘积控制关系,改变光电信号实现原始的单位像素亮度值Yraw改变,使相应的静脉区域像素亮度统计评估值Ysp满足Yll≤Ysp≤Yhl的预设条件。The photoelectric signal processing control described above is based on the linear product control relationship defined in the first step, and the photoelectric signal is changed to realize the original unit pixel luminance value Yraw, so that the corresponding vein region pixel luminance evaluation value Ysp satisfies Yll ≤ Ysp ≤ Yhl's preset conditions.
本发明还同时提供了一种利用上述用于移动终端的静脉识别成像模组进行安全认证的方法,包括以下步骤:The present invention also provides a method for performing security authentication using the above-described vein recognition imaging module for a mobile terminal, comprising the following steps:
1)、配置安全模式的处理器芯片5连接获取图像成像传感器15输出的数字化静脉图像(通过以上的步骤一、二、三获取该静脉图像,并转换成数字化静脉图像);1) The processor chip 5 configured with the security mode is connected to acquire the digitized vein image output by the image imaging sensor 15 (the vein image is acquired through the above steps 1, 2, and 3, and converted into a digitized vein image);
2)、配置安全模式的处理器芯片5进行静脉识别算法,并提取静脉特征信息;2) The processor chip 5 configured with the security mode performs a vein recognition algorithm and extracts vein characteristic information;
3)、配置安全模式的处理器芯片5通过静脉特征信息生成静脉特征模板;3) The processor chip 5 configuring the security mode generates a vein feature template by using the vein feature information;
4)、通过循环步骤1)至3)获得至少2个或以上的静脉特征模板,进行静脉特征模板间交叉认证比对,以交叉认证比对后最佳结果的特定静脉特征模板为标准静脉特征模板;4) obtaining at least two or more venous feature templates through the cyclic steps 1) to 3), performing cross-certification comparison between the venous feature templates, and using the specific venous feature template of the best result after cross-certification comparison as the standard venous feature template;
举例获得3个静脉特征模板进行交叉认证比对分别为1-2,1-3,2-3;如2-3认证比对结果最差,则1为最佳结果的特定静脉特征模板,为标准静脉特征模板;For example, the three vein feature templates are obtained for cross-certification comparisons of 1-2, 1-3, and 2-3, respectively; if the 2-3 authentication comparison results are the worst, then 1 is the best result for the specific vein feature template. Standard vein feature template;
如1-3认证比对结果最差,则2为最佳结果的特定静脉特征模板,为标准静脉特征模板;If the 1-3 authentication comparison result is the worst, then 2 is the best result of the specific vein feature template, which is the standard vein feature template;
如1-2认证比对结果最差,则3为最佳结果的特定静脉特征模板,为标准静脉特征模板;If the 1-2 authentication comparison result is the worst, then 3 is the best result of the specific vein feature template, which is the standard vein feature template;
5)、该标准静脉特征模板采用密码学体系加密后存储在配置安全模式的处理器芯片内做为密钥,并保证从不被导出和访问;5) The standard vein feature template is encrypted by a cryptographic system and stored in a processor chip configured in a secure mode as a key, and is guaranteed to be never exported and accessed;
6)、静脉特征模板的身份认证比对都在配置安全模式的处理器芯片5内部进行,确保移动终端在身份认证整个过程安全不被外部攻击。6) The identity authentication comparison of the vein feature template is performed inside the processor chip 5 configured with the security mode, ensuring that the mobile terminal is safe from external attacks during the entire process of identity authentication.
以上所述的静脉识别算法,密码学体系属于已知技术。作为移动终端的安全认证整体目的,上述方法不可或缺。The vein recognition algorithm described above, the cryptography system is a known technique. As a whole purpose of the security authentication of the mobile terminal, the above method is indispensable.
本发明描述的具体实施例内容和技术特征,可以在相同或等同理解的范围内被实施,如图像成像传感器类型,光学成像透镜类型,光路变换也应被等同理解的。 The specific embodiments and technical features of the present invention can be implemented within the scope of the same or equivalent understanding, such as image imaging sensor type, optical imaging lens type, and optical path transformation, which should be equally understood.
最后,还需要注意的是,以上列举的仅是本发明的一个具体实施例。显然,本发明不限于以上实施例,还可以有许多变形。本领域的普通技术人员能从本发明公开的内容直接导出或联想到的所有变形,均应认为是本发明的保护范围。 Finally, it should also be noted that the above list is only one specific embodiment of the invention. It is apparent that the present invention is not limited to the above embodiment, and many variations are possible. All modifications that can be directly derived or conceived by those of ordinary skill in the art from the disclosure of the present invention are considered to be the scope of the present invention.

Claims (16)

  1. 一种用于移动终端的静脉识别成像模组进行安全认证的方法,所述静脉识别成像模组包括设置在移动终端上的静脉识别成像装置,所述静脉识别成像装置包括通过近红外LED电流驱动器(2)驱动的近红外LED照明光源(3)和静脉识别成像模组光学部件(1);所述静脉识别成像模组光学部件(1)包括对近红外LED照明光源(3)照射光源散射、反射后的光线进行过滤的近红外光学滤光器,对近红外光学滤光器过滤后的光线进行聚焦的光学成像透镜(12)、对通过光学成像透镜(12)聚焦的光线成像的图像成像传感器(15),以及将图像成像传感器(15)的图像进行信号传输的静脉识别成像模组基板(16),所述近红外LED照明光源(3)上设置有用于提供均匀的发射或辐射照明光场的光学漫射散射器,并且/或者设置光学线偏振器,以及对应于所述光学线偏振器,在成像光路中对应设置的正交态90度光学线偏振器,A method for performing safety authentication for a vein recognition imaging module of a mobile terminal, the vein recognition imaging module comprising a vein recognition imaging device disposed on a mobile terminal, the vein recognition imaging device including a near-infrared LED current driver (2) a driving near-infrared LED illumination source (3) and a vein recognition imaging module optical component (1); the vein recognition imaging module optical component (1) includes scattering of a near-infrared LED illumination source (3) a near-infrared optical filter that filters the reflected light, an optical imaging lens that focuses the light filtered by the near-infrared optical filter (12), and an image that images the light that is focused by the optical imaging lens (12) An imaging sensor (15), and a vein recognition imaging module substrate (16) for transmitting an image of the image imaging sensor (15), the near-infrared LED illumination source (3) being provided with means for providing uniform emission or radiation An optical diffusing diffuser that illuminates the light field, and/or an optical linear polarizer, and an orthogonal state corresponding to the optical linear polarizer in the imaging optical path 0 degree optical linear polarizer,
    所述方法包括如下的步骤:The method includes the following steps:
    1)、获取所述图像成像传感器(15)输出的数字化静脉图像;1) acquiring a digitized vein image output by the image imaging sensor (15);
    2)、进行静脉识别算法执行提取静脉特征信息;2) performing a vein recognition algorithm to perform extraction of vein characteristic information;
    3)、通过静脉特征信息生成静脉特征模板;3) generating a vein feature template by using vein characteristic information;
    4)、通过循环步骤1)至3)获得至少2个或以上的静脉特征模板,进行静脉特征模板间交叉认证比对,以交叉认证比对后最佳结果的特定静脉特征模板为标准静脉特征模板;4) obtaining at least two or more venous feature templates through the cyclic steps 1) to 3), performing cross-certification comparison between the venous feature templates, and using the specific venous feature template of the best result after cross-certification comparison as the standard venous feature template;
    5)、该标准静脉特征模板采用密码学体系加密后存储做为密钥,并保证从不被导出和访问,其中所述静脉特征模板的身份认证比对在所述移动终端中的处理器芯片(5)内部进行,确保移动终端在身份认证整个过程安全不被外部攻击。5) The standard vein feature template is encrypted by a cryptographic system and stored as a key, and is guaranteed to be never exported and accessed, wherein the identity authentication of the vein feature template is compared to the processor chip in the mobile terminal. (5) Internally, to ensure that the mobile terminal is secure from external attacks during the entire process of identity authentication.
  2. 根据权利要求1所述的安全认证的方法,其特征是:所述图像成像传感器(15)输出的数字化静脉图像通过如下步骤获取:The method of secure authentication according to claim 1, wherein the digitized vein image output by the image imaging sensor (15) is obtained by the following steps:
    1.1)、定义静脉识别成像模组原始的单位像素亮度值Yraw的光电信号;1.1) defining a photoelectric signal of the original unit pixel luminance value Yraw of the vein recognition imaging module;
    1.2)、定义静脉区域像素亮度统计评估值Ysp;1.2), defining a statistical evaluation value Ysp of the pixel area pixel brightness;
    1.3)、实现静脉区域像素亮度统计评估值Ysp在预设的[Yll,Yhl]亮 度范围。1.3), to achieve the vein area pixel brightness evaluation value Ysp in the preset [Yll, Yhl] bright Degree range.
  3. 根据权利要求2所述的安全认证的方法,其特征是:The method of secure authentication according to claim 2, wherein:
    步骤1.1)中,图像成像传感器(15)的帧像素全局触发曝光时间或积分时间T、近红外照明光源(3)最高辐射强度I、图像成像传感器(15)的模拟增益GAIN、光学成像透镜(12)固定光圈或相对孔径倒数的常数F以及固定光电信号转化率常数C确定Yraw;In step 1.1), the frame pixel of the image imaging sensor (15) globally triggers the exposure time or integration time T, the near-infrared illumination source (3) the highest radiation intensity I, the analog gain GAIN of the image imaging sensor (15), the optical imaging lens ( 12) fixed aperture or relative aperture reciprocal constant F and fixed photoelectric signal conversion rate constant C to determine Yraw;
    Yraw=C*T*GAIN*I*(1/F)2Yraw=C*T*GAIN*I*(1/F) 2 ;
    所述T≤3.33ms;The T≤3.33ms;
    所述I≥10mW/sr;The I≥10mW/sr;
    所述GAIN的最大值产生的图像成像传感器信噪比SNR≥38db;The image imaging sensor with a maximum value of GAIN produces a signal-to-noise ratio SNR ≥ 38db;
    所述F的取值范围为:F=EFL/D或者0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ),The value range of F is: F=EFL/D or 0.5*SOP/(1.22*λ)≤F≤2.0*SOP/(1.22*λ),
    所述D为光学成像透镜(12)的光瞳或通光孔径的直径,FEL为光学成像透镜(12)的等效焦距值,SOP为图像成像传感器(15)单位像素的物理尺度,λ为近红外LED照明光源等效峰值波长。The D is the diameter of the pupil or clear aperture of the optical imaging lens (12), the FEL is the equivalent focal length value of the optical imaging lens (12), and the SOP is the physical scale of the unit imaging pixel of the image imaging sensor (15), λ is The near-infrared LED illumination source has an equivalent peak wavelength.
  4. 根据权利要求2所述的利用移动终端的静脉识别成像模组进行安全认证的方法,其特征是:步骤1.2)中,所述Ysp=S(Yraw);The method for performing security authentication using the vein recognition imaging module of the mobile terminal according to claim 2, wherein in step 1.2), the Ysp=S(Yraw);
    所述的S(Yraw)为静脉区域像素亮度统计评估函数,所述像素亮度统计评估函数采用的方法包括像素亮度直方图统计、像素亮度频谱统计、像素亮度平均值、像素亮度加权平均值或者像素亮度中值等。The S (Yraw) is a venous region pixel brightness statistical evaluation function, and the pixel brightness statistical evaluation function adopts a method including pixel brightness histogram statistics, pixel brightness spectrum statistics, pixel brightness average value, pixel brightness weighted average value or pixels. The median of brightness, etc.
  5. 根据权利要求2所述的利用移动终端的静脉识别成像模组进行安全认证的方法,其特征是:步骤1.3)中,所述通过T、I和GAIN的光电信号处理控制,静脉区域像素亮度统计评估值Ysp预设的[Yll,Yhl]亮度范围为:Yll≤Ysp≤Yhl;所述Yll为静脉区域像素亮度下限,Yhl为静脉区域像素亮度上限;The method for performing security authentication by using a vein recognition imaging module of a mobile terminal according to claim 2, wherein in step 1.3), the photoelectric signal processing control by T, I, and GAIN, and the pixel brightness statistics of the vein region are performed. The [Yll, Yhl] brightness range preset by the evaluation value Ysp is: Yll ≤ Ysp ≤ Yhl; the Yll is the lower limit of the pixel brightness of the venous area, and Yhl is the upper limit of the pixel brightness of the venous area;
    所述的光电信号处理控制为根据步骤1.1)中的公式线性乘积控制关系,改变光电信号,实现原始的单位像素亮度值Yraw改变,使相应的静脉区域像素亮度统计评估值Ysp满足Yll≤Ysp≤Yhl的预设条件。 The photoelectric signal processing control is controlled according to the linear product control relationship in the step 1.1), and the photoelectric signal is changed to realize the original unit pixel luminance value Yraw change, so that the corresponding vein region pixel luminance statistical evaluation value Ysp satisfies Yll≤Ysp≤ Yhl's preset conditions.
  6. 一种用于移动终端安全认证的静脉识别成像装置,包括设置在移动终端上的静脉识别成像装置,所述移动终端包括处理器芯片(5),所述静脉识别成像装置包括近红外LED照明光源(3)和静脉识别成像模组光学部件(1);A vein recognition imaging device for mobile terminal security authentication, comprising a vein recognition imaging device disposed on a mobile terminal, the mobile terminal comprising a processor chip (5), the vein recognition imaging device comprising a near-infrared LED illumination source (3) and vein recognition imaging module optical components (1);
    所述近红外LED照明光源(3)通过近红外LED电流驱动器(2)驱动;The near-infrared LED illumination source (3) is driven by a near-infrared LED current driver (2);
    所述静脉识别成像模组光学部件(1)包括对近红外LED照明光源(3)照射光源散射、反射后的光线进行过滤的近红外光学滤光器,对近红外光学滤光器过滤后的光线进行聚焦的光学成像透镜(12)、对通过光学成像透镜(12)聚焦的光线成像的图像成像传感器(15),以及将图像成像传感器(15)的图像进行信号传输的静脉识别成像模组基板(16);The vein identification imaging module optical component (1) comprises a near-infrared optical filter for filtering the reflected light from the near-infrared LED illumination source (3), and filtering the near-infrared optical filter. An optical imaging lens (12) that focuses light, an image imaging sensor (15) that images light focused by the optical imaging lens (12), and a vein recognition imaging module that transmits an image of the image imaging sensor (15) Substrate (16);
    所述处理器芯片(5)分别与近红外LED电流驱动器(2)和静脉识别成像模组基板(16)信号连接,The processor chip (5) is respectively connected to the near-infrared LED current driver (2) and the vein recognition imaging module substrate (16),
    其中所述近红外LED照明光源(3)上设置有用于提供均匀的发射或辐射照明光场的光学漫射散射器,并且/或者设置光学线偏振器,以及对应于所述光学线偏振器,在成像光路中对应设置的正交态90度光学线偏振器。Wherein the near-infrared LED illumination source (3) is provided with an optical diffusing diffuser for providing a uniform emission or radiation illumination light field, and/or an optical linear polarizer is provided, and corresponding to the optical linear polarizer, An orthogonal state 90 degree optical linear polarizer disposed correspondingly in the imaging optical path.
  7. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述近红外LED照明光源(3)为表面贴片封装。The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the near-infrared LED illumination source (3) is a surface patch package.
  8. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述近红外LED电流驱动器(2)驱动近红外LED照明光源(3)输出最高辐射强度I短时间T脉冲周期时序发射光;The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the near-infrared LED current driver (2) drives the near-infrared LED illumination source (3) to output the highest radiation intensity I for a short time T Pulse period timing emission light;
    所述近红外LED照明光源(3)的发射光的半峰值辐射或发散角度大于等于光学成像透镜(12)的成像视场角FOV。The half-peak radiation or divergence angle of the emitted light of the near-infrared LED illumination source (3) is greater than or equal to the imaging field of view angle FOV of the optical imaging lens (12).
  9. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述光学成像透镜(12)固定聚焦透镜、液体驱动透镜、液晶驱动透镜、VCM音圈驱动透镜、MEMS驱动透镜、EDOF相位波前编码透镜、WLA晶圆级透镜阵列中的任意一种。The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the optical imaging lens (12) fixed focus lens, liquid drive lens, liquid crystal drive lens, VCM voice coil drive lens, MEMS Any of a drive lens, an EDOF phase wavefront coded lens, and a WLA wafer level lens array.
  10. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像 装置,其特征是:所述近红外光学滤光器的半峰值透射波长带宽FWHM有效匹配或覆盖近红外LED照明光源(3)发射光的半峰值辐射波长带宽FWHM;所述近红外光学滤光器包括前焦近红外光学滤光器(11)和/或后焦近红外光学滤光器(14)。The vein recognition imaging for mobile terminal security authentication according to claim 6 The device is characterized in that: the half-peak transmission wavelength bandwidth FWHM of the near-infrared optical filter effectively matches or covers the half-peak radiation wavelength bandwidth FWHM of the emitted light of the near-infrared LED illumination source (3); the near-infrared optical filter The device includes a front focus near infrared optical filter (11) and/or a back focus near infrared optical filter (14).
  11. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述处理器芯片(5)为配置安全模式的处理器芯片。The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the processor chip (5) is a processor chip configured with a security mode.
  12. 根据权利要求6或8所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述的近红外LED照明光源中心峰值波长范围750-880nm,FWHM为30-60nm;The vein recognition imaging device for mobile terminal security authentication according to claim 6 or 8, wherein the near-infrared LED illumination source has a center peak wavelength range of 750-880 nm and a FWHM of 30-60 nm;
    所述近红外光学滤光器中心峰值波长范围750-880nm,FWHM为10-60nm;The near-infrared optical filter has a center peak wavelength range of 750-880 nm and a FWHM of 10-60 nm;
    所述近红外光学滤光器为窄带近红外光学滤光器或者带通近红外光学滤光器中的任意一种。The near-infrared optical filter is any one of a narrowband near-infrared optical filter or a bandpass near-infrared optical filter.
  13. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein:
    所述光学成像透镜(12)的视场角FOV具有如下的取值范围:The field of view angle FOV of the optical imaging lens (12) has the following range of values:
    FOV≥2*arctan((DOI*SOP)/(2*EFL))FOV ≥ 2 * arctan ((DOI * SOP) / (2 * EFL))
    所述DOI为图像成像传感器的对角线像素数量;SOP为图像成像传感器单位像素的物理尺度;EFL为光学成像透镜的等效焦距值。The DOI is the number of diagonal pixels of the image imaging sensor; the SOP is the physical scale of the image imaging sensor unit pixel; and the EFL is the equivalent focal length value of the optical imaging lens.
  14. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述光学漫射散射器为光学发散镜。The vein recognition imaging apparatus for mobile terminal security authentication according to claim 6, wherein the optical diffusing diffuser is an optical diverging mirror.
  15. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:所述移动终端上设置有使用状态引导提示装置;The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the mobile terminal is provided with a use state guiding prompting device;
    所述使用状态引导提示装置包括语音装置、指示灯和液晶屏;The usage state guiding prompting device comprises a voice device, an indicator light, and a liquid crystal screen;
    所述语音装置、指示灯和液晶屏与处理器芯片(5)信号连接。The voice device, the indicator light and the liquid crystal screen are connected to the processor chip (5).
  16. 根据权利要求6所述的用于移动终端安全认证的静脉识别成像装置,其特征是:该移动终端包括移动终端主板(10)、处理器芯片(5)、内存(6)、存储器(7)、电源管理模块(8)以及无线基带模块(9)。 The vein recognition imaging device for mobile terminal security authentication according to claim 6, wherein the mobile terminal comprises a mobile terminal motherboard (10), a processor chip (5), a memory (6), and a memory (7). , power management module (8) and wireless baseband module (9).
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