Many modern cell phone operating systems, including Apple iOS and Android, are configurable to use biometrics, such as fingerprints, as an alternative to user entry of unlock codes to validate user identity. A prior optical sensor for reading fingerprints used an electronic camera equipped with a single lens and an image sensor with a single array of photosensors to image a fingerprint surface of a finger through an OLED cell-phone display. To image a reasonable area of the finger, the lens and array of photosensors were large and required considerable space between lens and the array of photosensors—posing issues in the limited space available in a cell phone.
In an embodiment, a multiple-lens optical fingerprint reader adaptable to read fingerprints through a display has an image sensor integrated circuit comprising at least one photosensor array; a spacer; and a plurality of lenses organized in a microlens array, each lens of the plurality of lenses being configured to focus light arriving at that lens from a portion of a fingerprint region of a finger adjacent a surface of the display through the spacer to form an image on a plurality of photosensors associated with that lens, the photosensors being of a photosensor array of the at least one photosensor array, the image being formed independently of other lenses of the plurality of lenses.
In another embodiment, a method of verifying identity of a user includes illuminating a fingerprint region of a finger of the user with an organic light emitting diode display; focusing light from the fingerprint region through an array of microlenses onto at least one photosensor array of an integrated circuit, each microlens focusing light from a portion of the fingerprint region onto multiple photosensors of the at least one photosensor arrays; reading the at least one photosensor array to form overlapping electronic fingerprint images; extracting features by a method selected from extracting features from the overlapping electronic fingerprint images and extracting features from a stitched image formed from the overlapping electronic fingerprint images; and comparing the features to features of at least one user in a library of features associated with one or more fingers of one or more authorized users.
In an embodiment, the fingerprint s reader is made by forming an infrared filter on a bottom side of a thin glass substrate, the glass substrate being from 0.1 mm and 0.15 mm in thickness; depositing a light-absorbing coating on the infrared filter; masking and etching the light absorbing coating to form openings; forming an array of microlenses by reflowing reflowable optical material onto a top side of the glass substrate and shaping the optical material with a preformed wafer-sized stamp; aligning, and bonding the substrate to a wafer of integrated circuits, each of the integrated circuits having at least one array of photosensors; dicing the wafer of integrated circuits; and bonding the integrated circuits to a flexible printed circuit.
A fingerprint sensor module 100 (
Under the spacer 208, in infrared-sensing embodiments, there may be an infrared filter 210, which is omitted in other embodiments that image fingerprints with visible light. There is also an opaque, black, mask 212 with openings 214 that align with photosensor arrays 216 of integrated circuit 108
In a typical application, the optical fingerprint sensor module 100 is positioned under an organic light-emitting diode (OLED) display panel 220 of the cell phone, the OLED display panel 220 being of a known thickness and at least semitransparent to light at infrared wavelengths if infrared filter 210 is present, or semitransparent to some visible light wavelengths if infrared filter 210 is absent.
The optical fingerprint sensor module 100 is also typically positioned in front of a battery 222 that is positioned in front of a back plate 224 of the cell phone, the distance from a back side of back plate 224 to a front side of the OLED display panel 220 defining thickness of the cell phone.
When a finger 226 of a user is positioned in contact with the front of the OLED display panel 220, some light reflected from a fingerprint region 228 of the finger 226 passes through OLED display panel 220 and is focused by microlenses 102 onto photosensor arrays 216.
In an embodiment, each microlens 102 of the lens array as an aspheric single-element lens with distance from a front surface of the lens between 1.5 mm and 2.1 mm, Fstop of 1.0, a field of view FOV=23°, and an effective focal length EFFL=0.113 mm. Each lens is 0.09935 mm in diameter and 0.0526 mm tall.
As illustrated in
The fingerprint sensor module 100 is produced by a process 400 according to
The microlens array 104 is formed 406 as a wafer level lens array by reflowing reflowable optical material onto a top side of the glass substrate or spacer 208 and the reflowable optical material is shaped with a preformed wafer-sized stamp. The alignment marks are used to align the stamp and optical material with the previously formed openings 214, 215 in the light absorbing coating. The bottom side of the glass substrate or spacer 208 with light absorbing coating 212 is then aligned, and bonded 408, to a wafer of integrated circuits 108. The assembled wafer with microlenses 102, glass substrate serving a spacer 208, and integrated circuits 108 may be tested and defective circuits inked. The assembled wafer is then diced, typically by sawing, and individual microlens array 104, substrate or spacer 208, light absorbing coatings 106, 212, and integrated circuit 108 assemblies bonded 410 using a ball-bond reflow technique to flexible printed circuit 110.
The fingerprint sensor module 100, 206 is used in a cellular telephone 600 (
The fingerprint sensor is operated by a method 500 (
Changes may be made in the above methods and systems without departing from the scope hereof. It should thus be noted that the matter contained in the above description or shown in the accompanying drawings should be interpreted as illustrative and not in a limiting sense. The following claims are intended to cover all generic and specific features described herein, as well as all statements of the scope of the present method and system, which, as a matter of language, might be said to fall therebetween.