KR101000714B1 - Optical sensor module - Google Patents

Abstract

The present invention relates to an optical sensor module, in particular by calculating the intensity of the external light using the light sensing data output from the readout driving unit, by calculating the optimum bias voltage from the calculated intensity of the external light and applying it to the light sensing element, The present invention relates to an optical sensor module capable of controlling photocurrent generation according to the intensity of external light and consequently increasing sensing efficiency.

The constituent means of the optical sensor module according to the present invention includes a sensor array unit including pixels including a photosensitive device, a power supply unit for applying a bias voltage to the photosensitive device, and a charge output from the sensor array unit. An optical sensor module comprising a readout driver for converting and outputting data, the bias sensor outputting the corrected bias voltage using the photosensitive data output from the readout driver and outputting the corrected bias voltage to the power supply unit. It further comprises an adjustment unit.

Optical sensor, bias voltage

Description

Optical sensor module

The present invention relates to an optical sensor module, in particular by calculating the intensity of the external light using the light sensing data output from the readout driving unit, by calculating the optimum bias voltage from the calculated intensity of the external light and applying it to the light sensing element, The present invention relates to an optical sensor module capable of controlling photocurrent generation according to the intensity of external light and consequently increasing sensing efficiency.

In general, the optical sensor module stores the photocurrent generated in the photosensitive device according to the amount of light in a capacitor in response to light input from the outside, and then converts the stored charge into data and outputs it.

In particular, as the liquid crystal display panel employing the optical sensor module has been published as a "Active Matrix LCD with Integrated Optical Touch Screen" in a paper published in the 2003 SID conference paper by Willem den Boer et al. The optical sensors of the are arranged in a matrix type, and are used for an operation such as a fingerprint recognition function or a touch panel function by generating position information corresponding to the position of external light.

The optical sensor module used as described above includes various elements and drive drives, and FIG. 1 illustrates a configuration of a conventional optical sensor module.

As shown in FIG. 1, the conventional optical sensor module includes a sensor array unit 10, a scan driver 20, a readout driver 30, a power supply unit 40, and a controller unit 50.

As illustrated in FIG. 1, the sensor array unit 10 includes a plurality of pixels divided into scan lines SL continuously formed in the horizontal direction and lead-out lines ROL continuously formed in the vertical direction. It is composed. Each pixel consists of a plurality of elements, specifically, the light sensing element 12, the storage capacitor 13, and the switching transistor 14.

The photosensitive device 12 generates a photocurrent by the external light 11. The photosensitive device 12 is a device capable of generating a light induction current by external light.

As described above, the photocurrent generated in the photosensitive device flows to the storage capacitor 13 as the bias voltage is applied to the photosensitive device 12. As a result, electric charge is charged in the storage capacitor 13 by the photocurrent.

A bias voltage is applied to one end of the photosensitive device 12 so that charge can be charged to the storage capacitor 13 by the photocurrent. As a result, as the bias voltage is applied, photocurrent flows to the storage capacitor 13 connected to the other end of the photosensitive device 12, and the charge may be charged.

The bias voltage is generated by the power supply 40 and applied to the photosensitive device 12 through the bias voltage line VL. The power supply 40 generates a bias voltage at a preset level, and always applies the same bias voltage to the photosensitive device 12.

The charge charged in the storage capacitor 13 is output to the readout line ROL when the switching transistor 14 is turned on. That is, the switching transistor 14 outputs the charge charged in the storage capacitor 13 to the readout line ROL under the control of the scan driver 20.

The switching transistor 13 is turned on or turned off by a driving signal of the scan driver 20. Therefore, the gate terminal of the switching transistor 14 is connected to the scan line SL to receive the driving signal provided from the scan driver 20.

The drain terminal of the switching transistor 14 is connected to the other end of the photosensitive device 12 and the storage capacitor 13, and the source terminal is connected to the readout line ROL. Therefore, the switching transistor 14 is turned on as the scan driving signal is applied to a gate terminal, and the charge charged in the storage capacitor 13 passes through the switching transistor 14 to the lead-out line ROL. )

The sensor array unit 10 configured as described above is driven by the scan driver 20, the readout driver 30, and the power supply 40. The scan driver 20 drives the gate terminal of the switching transistor 14 of the sensor array unit 10. That is, the scan driver 20 drives the gate terminal so that the charge charged in the storage capacitor 13 is output to the readout line ROL through the switching transistor 14 so that the switching transistor ( 14) can be turned on.

As described above, the charge output to the readout line ROL is read by the readout driver 30. In detail, the readout driver 30 reads the charge output through the readout line ROL, converts the data, and outputs the converted data as light sensing data.

The scan driver 20 and the readout driver 30 are controlled by the controller 50. That is, the scan driver 20 sequentially applies a driving signal of a switching transistor to the scan lines SL under the control of the controller 50, and the readout driver 30 is the controller. Under the control of 50, the charges output to the readout line ROL are sequentially read.

Meanwhile, a bias voltage is applied to the photosensitive device 12 so that the photocurrent generated in the photosensitive device 12 flows to the storage capacitor 13, and the bias voltage is generated by the power supply unit 40. Is authorized. That is, the power supply 40 generates a predetermined bias voltage and applies it to the photosensitive device so that the storage capacitor 13 can be charged by the current generated by the photosensitive device 12.

The bias voltage generated by the power supply 40 is a preset level voltage. Therefore, the same bias voltage is always generated and applied to the photosensitive element 12.

As described above, the conventional power supply 40 always generates and applies the same bias voltage. That is, the same bias voltage is always applied to the photosensitive device 12 regardless of the intensity of external light.

However, when the intensity of external light is weak, the photocurrent generated by the photosensitive device 12 is minute, and as a result, even when there is external light, the lead-out driver 30 cannot recognize the photocurrent change. .

On the contrary, when the intensity of external light is too strong, excessive photocurrent occurs, and as a result, a problem of exceeding the maximum amount of charge recognizable by the readout driver 30 occurs.

The present invention was devised to solve the above problems of the prior art, and calculates the intensity of the external light using the light sensing data output from the readout driver, and calculates the optimum bias voltage from the calculated intensity of the external light. By applying to the photosensitive device, it is possible to control the photocurrent generation by using the bias voltage adjusted according to the intensity of the external light, and consequently to increase the sensing efficiency. It is an object of the present invention to provide an optical sensor module that can minimize power.

The construction means constituting the optical sensor module of the present invention proposed to solve the above problems, the sensor array unit consisting of pixels including a photosensitive device, a power supply for applying a bias voltage to the photosensitive device and the An optical sensor module comprising a readout driver converting a charge output from a sensor array unit into photosensitive data and outputting the same, wherein the corrected bias voltage is calculated using the photosensitive data output from the readout driver. The apparatus may further include a bias voltage adjusting unit outputting the same to the power supply unit.

Here, the photosensitive device is characterized in that the photodiode or phototransistor.

The bias voltage adjusting unit may include an optical sensing data input unit configured to receive the optical sensing data output from the readout driver, an optical intensity calculator configured to calculate the intensity of the external light using the optical sensing data, and an intensity range of the external light. And a bias voltage calculator configured to extract a bias voltage matched to the intensity range of the external light including the calculated intensity of the external light with reference to the matching table with which the bias voltage is matched.

According to the optical sensor module of the present invention having the above-described problems and solving means, the intensity of the external light is calculated using the light sensing data output from the readout driver, and the optimum bias voltage is calculated from the calculated intensity of the external light Since it can be applied to the sensing element, it is possible to adjust the photocurrent generation by using the bias voltage adjusted according to the intensity of the external light, consequently to increase the sensing efficiency, and to adjust the bias voltage low when the intensity of the external light is strong. This has the advantage of minimizing power consumption.

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the optical sensor module of the present invention having the above problems, means and effects.

The present invention is different from the conventional art of generating the same bias voltage at all times regardless of the intensity of external light and applying it to the photosensitive device. It features.

Therefore, before describing the structural features of the present invention, the photocurrent characteristics of the photosensitive device according to the bias voltage will be first described with reference to FIG.

In FIG. 2, graph 1 shows photocurrent characteristics of the photosensitive device in a dark environment without external light, and graphs 2 to 5 show an intensity of 1000 lux of external light and a bias voltage of 0.1 V, respectively. The photocurrent characteristics of the photosensitive device at 1V, 5V, and 10V are shown.

As shown in FIG. 2, the photosensitive device generates a photocurrent that increases as the bias voltage applied in the same external light intensity environment increases. That is, as the bias voltage applied to the photosensitive device increases in the same external light intensity environment, the photocurrent generated in the photosensitive device also increases.

As a result of the photocurrent characteristic, the present invention aims to increase the efficiency of the optical sensor module by adjusting the bias voltage to adjust the photocurrent amount. That is, when it is determined that the intensity of external light is too small to recognize the charge in the readout driver, the bias voltage is increased to further increase the photocurrent, and consequently, the readout driver can recognize the charge.

On the contrary, if the intensity of external light is large and a charge enough to be recognized by the readout driver is generated, the bias voltage may be reduced to minimize power consumption.

In summary, the present invention uses the photocurrent characteristic shown in FIG. 2 to improve the efficiency of power consumption by using a low bias voltage when the intensity of external light is sufficiently strong, and to reduce the bias voltage when the intensity of external light is weak. By using high, the photocurrent generation amount of the photosensitive device is improved to reduce the sensing capability of the optical sensor module according to the intensity of external light, thereby making it possible to use the optical sensor module in a wide range of external light intensity.

As described above, the configuration of the optical sensor module of the present invention that can improve the power consumption and the sensing capability is as shown in FIG.

As shown in FIG. 3, the optical sensor module according to the present invention includes a sensor array unit 110, a scan driver 120, a readout driver 130, a power supply unit 140, a controller unit 150, and a bias voltage. It includes an adjusting unit 160.

As illustrated in FIG. 3, the sensor array unit 110 includes a plurality of pixels divided into scan lines SL continuously formed in the horizontal direction and lead-out lines ROL continuously formed in the vertical direction. It is composed. Each pixel includes a plurality of devices, and specifically, includes a photosensitive device 112, a storage capacitor 113, and a switching transistor 114.

The photosensitive device 112 generates a photocurrent by the external light 111. The photosensitive device 112 is a device capable of generating a photo induced current by external light, and may be configured as a photo diode or a photo transistor.

As described above, the photocurrent generated in the photosensitive device flows to the storage capacitor 113 as the bias voltage is applied to the photosensitive device 112. As a result, charge is charged to the storage capacitor 113 by the photocurrent.

A bias voltage is applied to one end of the photosensitive device 112 so that charge can be charged in the storage capacitor 113 by the photocurrent. As a result, as the bias voltage is applied, photocurrent flows to the storage capacitor 113 connected to the other end of the photosensitive device 112, and the charge may be charged.

The bias voltage is generated by the power supply 140 and applied to the photosensitive device 112 through the bias voltage line VL. The power supply unit 140 generates a bias voltage under the control of the bias voltage adjusting unit 160 to be described later, and applies the bias voltage to the photosensitive device 112. In other words, rather than generating and applying the same bias voltage at all times, a bias voltage adjusted from time to time (according to the intensity of external light) is generated and applied to the photosensitive device 112.

The charge charged in the storage capacitor 113 is output to the readout line ROL when the switching transistor 114 is turned on. That is, the switching transistor 114 outputs the charge charged in the storage capacitor 113 to the readout line ROL under the control of the scan driver 120.

The switching transistor 113 is turned on or turned off by a driving signal of the scan driver 120. Thus, the gate terminal of the switching transistor 114 is connected to the scan line SL to receive the driving signal provided from the scan driver 120.

The drain terminal of the switching transistor 114 is connected to the other end of the photosensitive device 112 and the storage capacitor 113, and the source terminal is connected to a readout line ROL. Accordingly, the switching transistor 114 is turned on as the scan driving signal is applied to a gate terminal, and the charge charged in the storage capacitor 113 passes through the switching transistor 114 to lead to the readout line ROL. )

The sensor array unit 110 configured as described above is driven by the scan driver 120, the readout driver 130, and the power supply unit 140. The scan driver 120 drives the gate terminal of the switching transistor 114 of the sensor array unit 110. That is, the scan driver 120 drives the gate terminal so that the charges charged in the storage capacitor 113 are output to the readout line ROL through the switching transistor 114 to control the switching transistor 114. ) Can be turned on.

As described above, the charge output to the readout line ROL is read by the readout driver 130. In detail, the readout driver 130 reads out the charges output to the readout line ROL, converts the data, and outputs the converted data as light sensing data. The readout driver 130 may measure the amount of change of the photocurrent from the photosensitive data and extract the position information corresponding to the corresponding pixel from the photosensitive data.

The scan driver 120 and the readout driver 130 are controlled by the controller 150. That is, the scan driver 120 sequentially applies a driving signal of a switching transistor to the scan lines SL under the control of the controller unit 150, and the readout driver 130 is the controller unit. According to the control of 150, the charges output to the readout line ROL are sequentially read.

On the other hand, the light sensing data output from the readout driver 130 is input to the bias voltage adjuster 160. Then, the bias voltage adjuster 160 calculates the corrected bias voltage by using the light sensing data output from the readout driver 130 and outputs the corrected bias voltage to the power supply 140. Then, the power supply unit 140 generates the corrected bias voltage and applies it to the photosensitive device.

The bias voltage adjusting unit 160 analyzes the input light sensing data to calculate an optimum corrected bias voltage and provides the bias voltage to the power supply 140. For example, as a result of analyzing the light sensing data, the intensity of external light is measured. Is large enough to control the power supply unit 140 to generate a bias voltage that is relatively lower than the initial bias voltage when the charge corresponding to a large photocurrent is recognized by the readout driver 130 to reduce power consumption. When the charge corresponding to the minute photo current is not recognized by the readout driver 130 because the intensity of external light is small, the power supply unit 140 may generate a bias voltage relatively higher than the initial bias voltage in order to improve sensing efficiency. ).

Specifically, the bias voltage adjusting unit 160 includes the detailed components shown in FIG. 4. That is, the bias voltage adjusting unit 160 includes a light sensing data input unit 161, a light intensity calculating unit 163, a matching table 165, and a bias voltage calculating unit 167.

The light sensing data input unit 161 receives the light sensing data output from the readout driver 130 and outputs the light sensing data to the light intensity calculator 163. Then, the light intensity calculator 163 calculates the intensity of the external light using the light detection data.

Since the photo-sensing data is a value obtained by converting the read-out electric charges, when the characteristics of the photo-sensing element used (the relationship between the intensity of external light and the generated photocurrent or charge amount) are used, the photo-sensing data is used to You can calculate the intensity.

On the other hand, in the other method, the intensity of the various external light is given to the light sensing element used, and after calculating the light sensing data corresponding to the intensity of each external light, the intensity of the various external light and the light sensing data respectively The matched data table may be prepared and used in advance. Therefore, when light sensing data is input, the light intensity calculator 163 may calculate the intensity of the external light by extracting the intensity of the external light matched with the input light sensing data.

When the light intensity calculator 163 calculates the light intensity in detail, the light intensity calculator receives light sensing data output during one frame or several frames. Then, the average value of the received light sensing data is calculated, and corresponding to the average value with reference to a previously prepared data table (a table in which the light sensing data is matched with various external light intensities). Calculate the intensity of external light. The average value of the photosensitive data may be calculated using a sensing value of the entire photosensitive device, or may be calculated using a sensing value of the photosensitive device included in an area not touched.

The external light intensity calculated by the light intensity calculator 163 is input to the bias voltage calculator 167. Then, the bias voltage calculator 167 calculates and transmits the corrected bias voltage to the power supply 140 using the calculated external light intensity and the matching table 165 prepared in advance.

The matching table 165 is a table in which the intensity range of the external light and the bias voltage are matched and stored. The matching table 165 is a connection relationship between the intensity range of the external light and the bias voltage obtained by a repetitive experiment in advance. Table 1 below shows an example of the matching table.

Intensity range of external light Bias voltage 1 to 100 LUX 10 V 101 to 1000 LUX 5 V .
.
. .
.
. 5000 LUX or more 1 V

Table 1

The matching table shown in Table 1 is merely an example, but a relatively high bias voltage is matched when the intensity of the external light is low, and a relatively low bias voltage is matched when the intensity of the external light is high.

That is, when the intensity of the external light is high, the bias voltage is lowered to reduce power consumption (in this case, the bias voltage is a voltage capable of generating a photocurrent sufficient to recognize the charge in the readout driver). When the intensity of the external light is low, it can be seen that the bias voltage is set relatively high so as to increase the photocurrent generation of the photosensitive device so that the charge can be sufficiently recognized by the readout driver.

Since the matching table 165 is provided as described above, the bias voltage calculator 167 includes the calculated calculated intensity of the external light with reference to the matching table in which the intensity range of the external light is matched with the bias voltage. A bias voltage matched to an intensity range of external light on the matching table may be extracted. For example, when the input calculated intensity of the external light is 500 LUX, the bias voltage calculator 167 is 5V matched to the intensity range 101-1000 LUX of the external light on the matching table including the 500 LUX. Is extracted as a corrected bias voltage and transferred to the power supply 140.

Meanwhile, a bias voltage is applied to the photosensitive device 112 so that the photocurrent generated in the photosensitive device 112 flows to the storage capacitor 113. The bias voltage is generated by the power supply unit 140. Is authorized. That is, the power supply unit 140 generates a predetermined bias voltage and applies it to the photosensitive device so that the storage capacitor 113 can be charged by the current generated by the photosensitive device 112.

The bias voltage generated by the power supply unit 140 is controlled by the bias voltage adjusting unit 160 described above. That is, the power supply unit 140 generates a corrected bias voltage calculated and provided by the bias voltage adjusting unit 160 and applies it to the photosensitive device.

For example, the power supply unit 140 generates a bias voltage set as an initial value and applies it to the photosensitive device. When the corrected bias voltage value is input from the bias voltage adjusting unit 160, the power supply unit 140 applies the corrected bias voltage. Is generated and applied to the photosensitive device.

The above-described optical sensor module detects a corresponding position in response to light input from the outside. In particular, in the liquid crystal display panel employing the optical sensor module, a plurality of light sensing elements are arranged in a matrix type, and used for operation of a fingerprint recognition function or a touch panel function by generating position information corresponding to the position of external light. do.

Therefore, each photosensitive device constituting the optical sensor module is further configured to each pixel of the liquid crystal display panel to perform a photosensitive function. In detail, the liquid crystal display panel used as the touch panel using the light sensing module may display an image on the screen according to the light sensing data for each pixel detected by the light sensor module.

1 is a block diagram of a conventional optical sensor module.

2 is a graph showing photocurrent characteristics of a photosensitive device according to a bias voltage.

3 is a block diagram of an optical sensor module according to an embodiment of the present invention.

4 is a detailed configuration diagram of a bias voltage adjusting unit that is a component of the present invention.

Explanation of symbols on the main parts of the drawings

10, 110: sensor array unit 11, 111: external light

12, 112: photosensitive device 13, 113: storage capacitor

14, 114: switching transistor 20, 120: scan driver

30, 130: lead-out drive unit 40, 140: power supply unit

50, 150: controller 160: bias voltage adjusting unit

161: light sensing data input unit 163: light intensity calculator

165: matching table 167: bias voltage calculation unit

Claims (3)

delete delete A sensor array unit including pixels including a photosensitive device, a power supply unit applying a bias voltage to the photosensitive device, and a readout driver for converting and outputting charges output from the sensor array unit into photosensitive data; In the optical sensor module made of, Comprising a bias voltage adjusting unit for calculating the corrected bias voltage by using the light detection data output from the readout driver, and outputs it to the power supply, The bias voltage adjusting unit may include an optical sensing data input unit configured to receive optical sensing data output from the readout driver, an optical intensity calculator configured to calculate the intensity of external light using the optical sensing data, and an intensity range of the external light and a bias voltage. And a bias voltage calculator configured to extract a bias voltage matched to the intensity range of the external light including the calculated intensity of the external light with reference to the matching table.

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