CN105554419B - Imaging sensor and there is its terminal - Google Patents

Abstract

The invention discloses a kind of imaging sensor, the imaging sensor includes pixel unit array, amplification converting unit and filter array, and pixel unit array includes multiple pixel cells；Amplification converting unit is used to photogenerated charge caused by pixel cell being converted to analog signal；Filter array is arranged in pixel unit array, and filter array includes multiple optical filters, and the optical filter of same color corresponds to multiple pixel cells；Wherein, an amplification converting unit is shared after photogenerated charge caused by a part of pixel cell is cumulative in multiple pixel cells corresponding to the optical filter of same color and exports the first analog signal, sharing an amplification converting unit after photogenerated charge caused by the pixel cell of remainder is cumulative in multiple pixel cells corresponding to the optical filter of same color exports the second analog signal.The imaging sensor, sensitivity and signal to noise ratio are improved.Invention additionally discloses a kind of terminal with the imaging sensor.

Description

Imaging sensor and there is its terminal

Technical field

The invention belongs to technical field of image processing, more particularly to a kind of imaging sensor, and there is the image sensing The terminal of device.

Background technology

With the popularization of mobile phone, the hobby with mobile phone photograph as more and more people.But as people are required taking pictures Raising, outstanding dark-state take pictures effect turn into consumer active demand, and then require sensor have higher sensitivity and Preferable signal to noise ratio, still, the sensitivity of current imaging sensor, signal to noise ratio need further to be improved.

The content of the invention

It is contemplated that at least solves one of technical problem in correlation technique to a certain extent.Therefore, the present invention needs A kind of imaging sensor is proposed, the imaging sensor, sensitivity improves.

The present invention also proposes a kind of terminal using the imaging sensor in addition.

In order to solve the above problems, one aspect of the present invention proposes a kind of imaging sensor, and the imaging sensor includes：Pixel Cell array, including multiple pixel cells；Amplification converting unit, for photogenerated charge caused by pixel cell to be converted into simulation Signal；The filter array being arranged in the pixel unit array, filter array include multiple optical filters, same color it is described Optical filter corresponds to multiple pixel cells；Wherein, caused by multiple pixel cells corresponding to the optical filter of the same color First analog signal and second analog signal, first mould are exported after the amplified converting unit conversion of photogenerated charge It is identical with second analog signal to intend signal.

The imaging sensor of the present invention, the optical filter based on same color correspond to multiple pixel cells, and same color Two identical analog signals are exported after multiple amplified converting unit conversions of pixel cell corresponding to optical filter, compared to single Pixel cell exports, and can obtain more light induced electrons, sensitivity and signal to noise ratio are improved by hardware modifications.

It is used to export all of the first analog signal in multiple pixel cells corresponding to the optical filter of the same color An amplification converting unit is shared after the photogenerated charge of pixel cell is cumulative to export, corresponding to the optical filter of the same color The photogenerated charge of all pixels unit in multiple pixel cells for exporting the second analog signal shares an amplification after adding up Converting unit exports.

In some embodiments of the invention, described image sensor also includes：AD conversion unit (ADC, Analog- To-Digital Converter), for the first analog signal and the second analog signal to be respectively converted into the first data signal With the second data signal.

In some embodiments of the invention, multiple pixel cells corresponding to the optical filter of same color are located at pixel list Element array is not gone together.

In some embodiments of the invention, corresponding 2 rows 2 row of the optical filter of the same color amount to 4 pixel cells, After photogenerated charge caused by 2 pixel cells in the first row is cumulative the first simulation letter is converted to by amplification converting unit Number, change list by amplification after photogenerated charge caused by 2 pixel cells in 2 pixel cells in the second row is cumulative Member is converted to the second analog signal, and first analog signal and the second analog signal are distinguished by an AD conversion unit again Be converted to first data signal and the second data signal.

In some embodiments of the invention, above-mentioned imaging sensor also includes：It is arranged on micro- on the filter array Lens array, each micro mirror in the micro mirror array are corresponding with a pixel cell.

In some embodiments of the invention, above-mentioned imaging sensor also includes control module and image processing module, institute Control module is stated to be used to control multiple pixel cells corresponding to the optical filter of the same color according to row while expose, it is described Output of the image processing module to the AD conversion unit is synthesized to obtain high dynamic range images.

In order to solve the above problems, another aspect of the present invention proposes a kind of terminal, and the terminal is included described in above-mentioned aspect Imaging sensor.

The terminal of the present invention, by using described imaging sensor, the hardware configuration based on imaging sensor can be real Existing HDR functions, lift HDR image effect.

In some embodiments of the invention, the imaging terminal includes mobile phone.

In some embodiments of the invention, the imaging terminal also includes the centre being connected with described image sensor Device and display device are managed, the central processing unit is used for the figure for controlling the display device to show described image sensor output Picture.

In some embodiments of the invention, the terminal include the central processing unit that is connected with described image sensor and External memory, the central processing unit are used for the image for controlling the external memory storage described image sensor output.

Brief description of the drawings

Fig. 1 is the schematic diagram of imaging sensor according to an embodiment of the invention；

Fig. 2 is the schematic diagram of imaging sensor according to another embodiment of the invention；

Fig. 3 is the distribution schematic diagram according to the filter plate of the specific embodiment of the present invention；

Fig. 4 is the circuit diagram of imaging sensor according to an embodiment of the invention；

Fig. 5 is the block diagram of imaging sensor according to still another embodiment of the invention；

Fig. 6 is the block diagram of terminal according to an embodiment of the invention；

Fig. 7 is the block diagram of terminal according to another embodiment of the invention；And

Fig. 8 is the block diagram of terminal according to still a further embodiment.

Embodiment

Embodiments of the invention are described below in detail, the example of the embodiment is shown in the drawings, wherein from beginning to end Same or similar label represents same or similar element or the element with same or like function.Below with reference to attached The embodiment of figure description is exemplary, it is intended to for explaining the present invention, and is not considered as limiting the invention.

Imaging sensor according to embodiments of the present invention and the terminal with the imaging sensor are described with reference to the accompanying drawings.

First, the imaging sensor of the embodiment of the present invention is illustrated.Fig. 1 is according to an embodiment of the invention The block diagram of imaging sensor.

As shown in figure 1, the imaging sensor 100 includes pixel unit array 10, amplification converting unit 20 and filter array 30。

Pixel unit array 10 includes multiple pixel cells 11；Amplification converting unit 20 is used for caused by pixel cell 11 Photogenerated charge is converted to analog signal；Filter array 30 is arranged in pixel unit array 10, and each filter array 30 includes more Individual optical filter 31, the optical filter 31 of same color correspond to multiple pixel cells 11.

Wherein, the amplified conversion of photogenerated charge caused by multiple pixel cells corresponding to the optical filter 31 of same color is single A first analog signal D1 and one second analog signal D2, the first analog signal D1 and the second simulation are exported after the conversion of member 20 Signal D2 is identical.

The imaging sensor of the present invention, the corresponding multiple pixel cells 11 of the optical filter 31 based on same color, and same face Multiple amplified converting units 20 of pixel cell 11 export two identical analog signals after changing corresponding to the optical filter 31 of color, Exported compared to single pixel unit 11, more light induced electrons can be obtained, sensitivity and letter are improved by hardware modifications Make an uproar ratio.

In some embodiments of the invention, it is used in multiple pixel cells corresponding to the optical filter 31 of same color defeated Go out the first analog signal A1 all pixels unit 11 photogenerated charge it is cumulative after share an amplification converting unit 20 and export, together It is used for all pixels unit 11 for exporting the second analog signal A2 in multiple pixel cells corresponding to the optical filter 31 of one color Photogenerated charge it is cumulative after share an amplification converting unit 20 and export.Equivalent to the photogenerated charge that output is multiple pixel cells And value, more light induced electrons can be obtained.

As shown in Fig. 2 imaging sensor 100 also includes AD conversion unit 40, AD conversion unit 40 is simulated first Signal A1 and the second analog signal A2 are respectively converted into the first data signal D1 and the second data signal D2, are provided for image procossing Data.

In some embodiments of the invention, multiple pixel cells 11 corresponding to the optical filter 31 of same color are located at picture Plain cell array 10 is not gone together.

For example, corresponding 2 rows 2 row of the optical filter 31 of same color amount to 4 pixel cells, 2 pictures in the first row The first analog signal A1 is converted to by amplification converting unit 20 after photogenerated charge caused by plain unit 11 is cumulative, positioned at the second row In 2 pixel cells in be converted to the by amplification converting unit 20 after photogenerated charge is cumulative caused by each pixel cell 11 Two analog signal A2, the first analog signal A1 and the second analog signal A2 are respectively converted into by an AD conversion unit 40 again One the first data signal D1 and the second data signal D2.

It is the optical filter distribution schematic diagram according to one embodiment of the present of invention shown in reference picture 3, filter array 30 uses Bayer array color modes, wherein, identical characters represent the optical filter (such as Gr, Gb, R, B) of same color, after character Numeral represents the row number of pixel cell corresponding to the filter plate of same color, and the optical filter of different colours only allows corresponding wavelength Light passes through.

Fig. 4 is the equivalent circuit diagram of imaging sensor according to an embodiment of the invention, as shown in figure 4, including：The One pixel cell PD1 and the first transmitting switch TG1, the second pixel cell PD2 and the second transmitting switch TG2, the 3rd pixel cell PD3 and the 3rd transmitting switch TG3, the 4th pixel cell PD4 and the 4th transmitting switch TG4, the first amplification converting unit SF1, Two amplification converting unit SF2, AD conversion unit 40.Wherein, pixel cell, such as photodiode, it is saturating to receive optical filter 31 The light crossed and generate electric charge, transmitting switch opens the electric charge output that then corresponding pixel cell 11 generates, and then is changed in amplification Unit 20 is coupled and is converted to voltage signal, and being converted to data signal by analog-to-digital conversion 40 is exported, and number is provided for image procossing According to basis.

Wherein, the first pixel cell PD1, the second pixel cell PD2, the 3rd pixel cell PD3 and the 4th pixel cell PD4 For the pixel cell of the optical filter of corresponding same color adjacent respectively, that is, the pixel cell reception phase that four difference are adjacent With the light of color, briefly, i.e., four pixel cells form a big pixel (pixel).And first pixel cell PD1 and Second pixel cell PD2 is located at same a line, and the 3rd pixel cell PD3 and the 4th pixel cell PD4 are located at same a line.

Specifically, the first pixel cell PD1 passes through the first of the first transmitting switch TG1 and the first amplification converting unit SF1 End connection, the second pixel cell PD2 are connected by the second transmitting switch TG2 with the first amplification converting unit SF1 first end, the The one amplification converting unit SF1 default power supply of the second end connection such as Vdd；3rd pixel cell PD3 passes through the 3rd transmitting switch TG3 is connected with the second amplification converting unit SF2 first end, and the 4th pixel cell PD4 passes through the 4th transmitting switch TG4 and the 3rd Amplification converting unit SF3 first end connection, the second amplification converting unit SF2 default power supply of the second end connection；First transmission Switch TG1 control terminal, the second transmitting switch TG2 control terminal, the 3rd transmitting switch TG3 control terminal and the 4th transmitting switch TG4 control terminal is connected with control module, and control module controls the switch of four transmitting switches, when transmitting switch is opened, The corresponding outgoing signal of pixel cell 11.

The input of AD conversion unit 40 is changed with the first amplification converting unit SF1 the 3rd end and the second amplification respectively Cell S F2 three-terminal link.

In order to realize the control of exposure, as shown in figure 4, imaging sensor 100 also include control module, image processor, First reset unit RST1, first choice cell S EL1, the second reset unit RET2 and the second selecting unit SEL2.

Wherein, the first reset unit RST1 first end respectively with the first transmitting switch TG1, the second transmitting switch TG2 and First amplification converting unit SF1 first end connection, the first reset unit RST1 default power supply of the second end connection, first choice Cell S EL1 first end and the first amplification converting unit SF1 three-terminal link, first choice cell S EL1 the second end with The input connection of AD conversion unit 40.Second reset unit RET2 first end respectively with the 3rd transmitting switch TG3, the 4th Transmitting switch TG4 and the second amplification converting unit SF2 first end connect, and the second reset unit RET2 the second end connection is default Power supply；Second selecting unit SEL2 first end and the second amplification converting unit SF2 three-terminal link, the second selecting unit SEL2 the second end is connected with the input of AD conversion unit 40.Specifically, as shown in Figure 4, first choice cell S EL1 The second end sense line (READOUT COLUMN) is connected with the second selecting unit SEL2 the second end, AD conversion unit 40 Input connects the READOUT COLUMN.

Wherein, the first reset unit RST1 the 3rd end, first choice cell S EL1 the 3rd end, the second reset unit RET2 the 3rd end and the second selecting unit SEL2 the 3rd end receive control signal, and control module controls the optical filtering of same color Multiple pixel cells 11 corresponding to piece 31 expose simultaneously according to row, and control the time for exposure, that is, realize spectrum assignment, Jin Ertu As output of the sensing module to AD conversion unit 40 is synthesized to obtain image.Based on said structure, both ensure normal field The definition that scape is taken pictures, the effect of taking pictures under night scene can be lifted again.

As an example, each optical filter 31 of 2i+1 (i=0,1,2,3,4 ...) rows is right in pixel unit array 10 Two pixel cells (such as pixel cell corresponding to optical filter Gr1, Gr2) answered, i.e. the first pixel cell PD1 and the second picture Plain unit PD2, it is the first amplification converting unit SF1, the first pixel cell PD1 and the second pixel to share an amplification converting unit Charge integration caused by unit PD2, by the first amplification converting unit SF1 by the first pixel cell PD1 and the second pixel cell PD2 Electric charge after collecting is converted to voltage signal, and is further converted to data signal by AD conversion unit 40 and exports, if this When the output valve of AD conversion unit 40 be ADC1；In addition, in pixel unit array 10 neighbouring 2i+1 rows 2i+2 (i=0, 1,2,3,4 ...) two pixel cells (such as pixel cell corresponding to optical filter Gr3, Gr4) of each optical filter 31 of row, That is it is the second amplification converting unit SF2 that the 3rd pixel cell PD3 and the 4th pixel cell PD4, which shares an amplification converting unit, Charge integration caused by 3rd pixel cell PD3 and the 4th pixel cell PD4, by the second amplification converting unit SF2 by the 3rd picture Electric charge after plain unit PD3 and the 4th pixel cell PD4 collect is converted to voltage signal, and further passes through AD conversion unit 40 are converted to data signal output, if now the output valve of AD conversion unit 40 is ADC2.

Specifically, so that corresponding 2 rows 2 of the optical filter 31 of same color arrange 4 adjacent pixel cells as an example, based on above-mentioned Circuit structure, shown in reference picture 4, when being taken pictures, the pixel cell 22 of the same color of control module control adjacent rows Expose simultaneously, for example, 2i+1 and 2i+2 rows expose simultaneously, wherein, i=0,1,2,3....., and the time for exposure is controlled, avoid Share the output saturation of two pixel cells 11 of same amplification converting unit.In an embodiment of the present invention, amplification conversion is single The electric charge that member 20 can export to pixel cell plays a part of collecting coupling, it is to be understood that now the first amplification is changed Cell S F1 or the second amplification converting unit SF2 quantities of electric charge collected or the magnitude of voltage changed is light caused by two pixel cells The sum of electronics, about single pixel unit produce photoelectronic twice, so four pictures of the optical filter 31 of corresponding same color Photoelectron caused by plain unit 11 increases compared to single pixel cell, substantially increases the sensitivity of imaging sensor 100 (being about twice).

As shown in figure 5, imaging sensor 100 also includes the micro mirror array 50 being arranged on filter array 30, micro mirror array Each micro mirror 51 in 50 is corresponding with a pixel cell 11, including formation, size, position correspondence.Micro mirror 51 can assemble light To the photosensitive part of pixel cell 11, the light reception intensity of lifting pixel cell 11, so as to improve imaging image quality.

Based on the imaging sensor of above-mentioned aspect embodiment, describe to implement according to a further aspect of the invention with reference to the accompanying drawings The terminal that example proposes.

Fig. 6 is the block diagram of terminal according to an embodiment of the invention, as shown in fig. 6, the terminal 1000 is including above-mentioned The imaging sensor 100 of aspect.Specifically, terminal 1000 can include mobile phone.

In certain embodiments, as shown in fig. 7, terminal 1000 also includes the central processing being connected with imaging sensor 100 Device 200 and display device 300, central processing unit 200 are used for the figure for controlling the image sensor 100 of display device 300 to export Picture.So, the image that terminal 1000 is shot can be shown in display device 300 so that user checks.Display device 300 includes Light-emitting diode display etc..

In certain embodiments, as shown in figure 8, terminal 1000 includes the central processing unit being connected with imaging sensor 100 200 and external memory 400, central processing unit 200 is used for the image for controlling the storage image sensor 100 of external memory 400 to export.

So, the image of generation can be stored, and be checked after convenient, use or transfer.External memory 400 includes SM (Smart Media) card and CF (Compact Flash) cards etc..

The terminal 1000, by using described imaging sensor 100, the hardware configuration based on imaging sensor 100 can To improve sensitivity of taking pictures, reduce signal to noise ratio.

It should be noted that in the description of this specification, " multiple " are meant that at least two, such as two, three Deng unless otherwise specifically defined.Reference term " one embodiment ", " some embodiments ", " example ", " specifically show The description of example " or " some examples " etc. means specific features, structure, material or the spy for combining the embodiment or example description Point is contained at least one embodiment or example of the present invention.In this manual, to the schematic representation of above-mentioned term not Identical embodiment or example must be directed to.Moreover, specific features, structure, material or the feature of description can be with office Combined in an appropriate manner in one or more embodiments or example.In addition, in the case of not conflicting, the skill of this area Art personnel can be tied the different embodiments or example and the feature of different embodiments or example described in this specification Close and combine.

In the description of the invention, it is to be understood that the orientation or position relationship of the instruction such as term " on ", " under " are base In orientation shown in the drawings or position relationship, description description of the invention and simplified, rather than instruction or hint are for only for ease of Signified device or element must have specific orientation, with specific azimuth configuration and operation, therefore it is not intended that to this The limitation of invention.

Although embodiments of the invention have been shown and described above, it is to be understood that above-described embodiment is example Property, it is impossible to limitation of the present invention is interpreted as, one of ordinary skill in the art within the scope of the invention can be to above-mentioned Embodiment is changed, changed, replacing and modification.

Claims (7)

1. A kind of 1. imaging sensor, it is characterised in that including：

   Pixel unit array, including multiple pixel cells；

   Amplification converting unit, for photogenerated charge caused by pixel cell to be converted into analog signal；And

   The filter array being arranged in the pixel unit array, filter array include multiple optical filters, same color it is described Optical filter corresponds to 4 pixel cells of 2 rows 2 row；

   Wherein, the amplified converting unit of photogenerated charge caused by 4 pixel cells corresponding to the optical filter of the same color First analog signal and second analog signal, first analog signal and the second simulation letter are exported after conversion It is number identical, wherein, in 4 pixel cells with photogenerated charge caused by 2 pixel cells of a line it is cumulative after by amplification Converting unit is converted to the first analog signal, photogenerated charge caused by 2 pixel cells of another row in 4 pixel cells The second analog signal is converted to by amplification converting unit after cumulative, wherein, 4 pixel cells are respectively the first pixel list Member, the second pixel cell, the 3rd pixel cell and the 4th pixel cell, first pixel cell by the first transmitting switch with The first end connection of first amplification converting unit, second pixel cell are turned by the second transmitting switch and first amplification The first end connection of unit is changed, the second end of the first amplification converting unit is connected with default power supply, the 3rd pixel list Member is connected by the 3rd transmitting switch with the first end of the second amplification converting unit, and the 4th pixel cell passes through the 4th transmission Switch is connected with the first end of the second amplification converting unit, and the second end of the second amplification converting unit is preset with described Power supply connects；

   AD conversion unit, believe for first analog signal and second analog signal to be respectively converted into the first numeral Number and the second data signal；

   Control module, image processing module and reset unit, the control module are used for by described in reset unit control Multiple pixel cells corresponding to the optical filter of same color expose simultaneously according to row, and described image processing module is to the modulus The output of converting unit is synthesized to obtain image.
2. 2. imaging sensor as claimed in claim 1, it is characterised in that multiple corresponding to the optical filter of the same color The photogenerated charge of all pixels unit in pixel cell for exporting the first analog signal shares an amplification conversion after adding up Unit exports, and is used to export all of the second analog signal in multiple pixel cells corresponding to the optical filter of the same color An amplification converting unit output is shared after the photogenerated charge of pixel cell is cumulative.
3. 3. imaging sensor as claimed in claim 2, it is characterised in that multiple corresponding to the optical filter of the same color Pixel cell is located at not going together for pixel unit array.
4. 4. imaging sensor as claimed in claim 1, it is characterised in that also include：

   The micro mirror array being arranged on the filter array, each micro mirror and a pixel cell in the micro mirror array It is corresponding.
5. 5. a kind of terminal, it is characterised in that including the imaging sensor as described in claim any one of 1-4.
6. 6. terminal as claimed in claim 5, it is characterised in that the terminal includes mobile phone.
7. 7. terminal as claimed in claim 5, it is characterised in that the terminal is also included in being connected with described image sensor Central processor and display device, the central processing unit are used to control the display device to show described image sensor output Image.