JP4861732B2 - Image processing apparatus, image reading apparatus, and mobile phone - Google Patents

Description

  The present invention relates to an image processing technique for performing edge enhancement processing on an image obtained by photographing.

Mobile phones having an image sensor such as a CCD (Charge Coupled Device) and having an OCR (Optical Character Recognition) function and a BCR (Bar Code Reader) function are becoming widespread.
When such an image sensor becomes high in temperature, dark current increases and noise increases, so that good image quality cannot be obtained.

Therefore, in Patent Document 1, since the logarithmic value of the dark current of the solid-state image sensor is proportional to the temperature, the delay unit and the subtractor using the output of the solid-state image sensor subjected to signal processing and digital conversion, By measuring the dark current, correcting the data corresponding to the maximum accumulative charge amount stored in the storage means based on the measured value, and correcting the output by the noise removing means using the corrected data, Even when using a solid-state image sensor whose fixed pattern noise changes with temperature, the fixed pattern noise of the solid-state image sensor can be removed according to the exact temperature of the solid-state image sensor itself. The technique which can obtain is disclosed.
Japanese Patent Laid-Open No. 9-181977

However, according to the technique disclosed in Patent Literature 1, although the fixed pattern noise of the solid-state imaging device is removed, it is not always guaranteed that other noise that cannot be captured as a fixed pattern is generated. If such other noise occurs, there is a problem that character recognition by the OCR function or the BCR function is hindered.
The present invention provides an image processing apparatus and image processing capable of performing appropriate edge enhancement so as not to hinder image recognition by the OCR function or the BCR function even when the periphery of the photographing unit becomes high temperature. It is an object to provide a method, a computer program, an image reading apparatus, and a mobile phone.

In order to achieve the above object, the present invention provides an image processing apparatus that performs at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens, and relates to an ambient temperature of the photographing means. An acquisition unit that acquires a temperature index, a setting unit that sets an edge enhancement level of the edge enhancement process based on the acquired temperature index, and an edge enhancement unit that performs an edge enhancement process according to the set edge enhancement level e Bei the door, the setting means, the temperature of the temperature index obtained by the obtaining means, when present within a predetermined first temperature range, to set the first edge emphasis degree, the first When it exists in the 2nd temperature range higher than a temperature range, the 2nd edge enhancement degree higher than the 1st edge enhancement degree is set up, and it exists in the 3rd temperature range higher than the 2nd temperature range. When, and sets the lower third edge enhancement degree than the first edge enhancement degree.

According to the configuration of the present invention, edge enhancement is performed according to the degree of edge enhancement set based on the temperature index related to the ambient temperature of the imaging unit, so that the dark current increases when the imaging unit becomes high temperature. Even in the case where noise is generated, an excellent effect is obtained in that an image that is appropriately edge-enhanced can be obtained so as not to hinder image recognition or the like.
In addition, since the second edge enhancement degree higher than the first edge enhancement degree is set when the acquired temperature related to the temperature index is within the second temperature range, the lens included in the photographing unit Even when the focus is shifted due to the above, it is possible to set the edge enhancement degree that sharpens the edge in the captured image. In addition, when the temperature related to the acquired temperature index is within the third temperature range, the third edge enhancement degree lower than the first edge enhancement degree is set, so that noise generated by dark current is set. The edge emphasis degree that can suppress the influence of can be set.
Here, the acquisition unit is a temperature sensor that measures and acquires the temperature inside the apparatus as the temperature index, and the setting unit sets the degree of edge enhancement using the measured temperature. You may do that.

According to this configuration, an accurate temperature index can be obtained by measuring the temperature with the temperature sensor .

The present invention also relates to an image processing method used in an image processing apparatus that performs at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens, and relates to an ambient temperature of the photographing means. An acquisition step of acquiring a temperature index, a setting step of setting an edge enhancement degree of the edge enhancement process based on the acquired temperature index, and an edge enhancement step of performing an edge enhancement process according to the set edge enhancement degree look including the door, in the setting step, the temperature of the temperature index obtained in the obtaining step, when present within a predetermined first temperature range, to set the first edge emphasis degree, the first A second edge enhancement degree higher than the first edge enhancement degree is set when the second edge temperature is within a second temperature range higher than the temperature range; When present in higher than the temperature range within the third temperature range, and sets the lower third edge enhancement degree than the first edge enhancement degree.

By using this method, edge enhancement according to the degree of edge enhancement set based on the temperature index related to the ambient temperature of the imaging unit is performed, so that when the imaging unit becomes high temperature, dark current increases and noise increases. Even if this occurs, an excellent effect is obtained in that an image that is appropriately edge-enhanced can be obtained so as not to hinder image recognition or the like.
In addition, since the second edge enhancement degree higher than the first edge enhancement degree is set when the acquired temperature related to the temperature index is within the second temperature range, the lens included in the photographing unit Even when the focus is shifted due to the above, it is possible to set the edge enhancement degree that sharpens the edge in the captured image. In addition, when the temperature related to the acquired temperature index is within the third temperature range, the third edge enhancement degree lower than the first edge enhancement degree is set, so that noise generated by dark current is set. The edge emphasis degree that can suppress the influence of can be set.
The present invention is also used in an image processing computer that performs at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens, and causes the computer to perform image processing. a program in the computer, an acquisition step of acquiring a temperature index of the ambient temperature of the imaging unit, a setting step of, based on the acquired temperature index, sets edge emphasis degree of the edge enhancement processing, the setting An edge emphasizing step for performing an edge emphasizing process in accordance with the degree of edge emphasis performed, and in the setting step, the temperature related to the temperature index acquired in the acquiring step is within a predetermined first temperature range And setting a first edge enhancement degree within a second temperature range higher than the first temperature range. If present, a second edge enhancement degree higher than the first edge enhancement degree is set, and when the second edge enhancement degree exists within a third temperature range higher than the second temperature range, the second edge enhancement degree is higher than the first edge enhancement degree. A low third edge enhancement degree is set .

By causing the computer to execute this computer program, edge enhancement is performed according to the degree of edge enhancement set based on the temperature index related to the ambient temperature of the imaging unit. Even when noise increases due to an increase in image quality, an excellent effect is obtained in that an image that is appropriately edge-enhanced can be obtained so as not to hinder image recognition and the like.
In addition, since the second edge enhancement degree higher than the first edge enhancement degree is set when the acquired temperature related to the temperature index is within the second temperature range, the lens included in the photographing unit Even when the focus is shifted due to the above, it is possible to set the edge enhancement degree that sharpens the edge in the captured image. In addition, when the temperature related to the acquired temperature index is within the third temperature range, the third edge enhancement degree lower than the first edge enhancement degree is set, so that noise generated by dark current is set. The edge emphasis degree that can suppress the influence of can be set.

Here, the computer program may be recorded on a computer-readable recording medium.
With this configuration, the computer program is reliably recorded so as to be readable by a computer, and the computer program can be easily transferred.

Further, the present invention is an image reading apparatus including the image processing apparatus and a photographing unit having the lens, and the image reading apparatus further includes an image recognition unit that recognizes an image after edge enhancement processing. It is characterized by including.
According to this configuration, an image with edge enhancement appropriately obtained so as not to hinder image recognition or the like can be obtained and obtained even when a dark current increases and noise occurs due to a high temperature of the photographing unit. An excellent effect is achieved in that good image recognition can be performed on the obtained image.

Here, the lens may be made of resin.
When the lens becomes hot, the refractive index of the lens changes, and the focus of the lens shifts. Due to such a cause, even when the image obtained by the photographing means is deteriorated, it is possible to obtain an image with appropriate edge emphasis and to perform good image recognition on the obtained image. Has an effect.

In particular, since a resin (plastic) lens has a larger change in refractive index with respect to temperature conversion than a glass lens, the image reading provided with a resin lens that is lighter than a glass lens. The apparatus has an effect of improving the reading accuracy and reducing the weight of the image reading apparatus.
According to another aspect of the present invention, there is provided a mobile phone comprising the image reading device.

  According to this configuration, as in the case of the image reading apparatus, edge enhancement is appropriately performed so that image recognition or the like is not hindered even when a dark current increases and noise occurs due to a high temperature of the photographing unit. The obtained image is obtained, and an excellent effect that the obtained image can be favorably recognized is obtained.

1. Embodiment A mobile phone 10 as one embodiment according to the present invention will be described.
1.1 Configuration of Mobile Phone 10 As shown in FIG. 1, the mobile phone 10 includes a camera sensor unit 101, an AD conversion unit 114, a DSP (Digital Signal Processor) unit 102, a CPU (Central Processing Unit) 103, and a display unit 104. A memory unit 105 including a RAM and a ROM, a key input circuit unit 106, a temperature sensor 107, a speaker 108, a microphone 109, an AD / DA conversion unit 110, a communication control unit 111, a communication unit 112, and an antenna 113. Yes.

The CPU 103 functionally includes an image recognition unit 121. That is, the memory unit 105 stores a computer program for image recognition, and the image recognition unit 121 achieves its function by the CPU 103 operating according to the computer program for image recognition.
The memory unit 105 stores other computer programs and various data, and the mobile phone 10 achieves a part of its functions by the CPU 103 operating according to the computer programs.

The DSP unit 102 includes a line memory 133, an edge enhancement unit 131, and a setting unit 132.
The CPU 103 and the memory unit 105 are connected by a 16-bit bus 115 as an example, the CPU 103 and the edge enhancement unit 131 are connected by an 8-bit bus 116 as an example, and the CPU 103 and the setting unit 132 are connected by an IIC bus 117 as an example. Has been.

  In each of the claims, the photographing unit corresponds to the camera sensor unit 101 included in the mobile phone 10 according to the embodiment, the acquisition unit corresponds to the temperature sensor 107, and the setting unit includes the setting unit. The edge enhancement unit corresponds to the edge enhancement unit 131. The image recognition means corresponds to the image recognition unit 121 included in the mobile phone 10 according to the embodiment.

(1) Memory unit 105
The memory unit 105 includes an area for storing a recognition flag, an emphasized image, a plurality of code information, and other information. The memory unit 105 stores a computer program for image recognition and other computer programs in advance.
(2) Camera sensor unit 101 and AD conversion unit 114
The camera sensor unit 101 includes a lens unit in which one or more lenses are combined and a photoelectric conversion unit.

At least one of the one or more lenses constituting the lens unit is made of resin (Plastec).
Since the resin lens is lighter than the glass lens, adopting the resin lens can contribute to the weight reduction of the mobile phone 10.
In addition, a resin (plastic) lens has a larger change in refractive index with respect to temperature conversion than a glass lens. For this reason, when the temperature around the camera sensor unit 101 increases, the refractive index of the resin lens changes, and the focus by the lens may shift.

The camera sensor unit 101 receives a shooting start signal from the DSP unit 102.
As an example, the photoelectric conversion unit is composed of a CCD in which at least 240 optical elements are arranged horizontally, 320 optical elements are arranged vertically, and a total of 76800 optical elements are arranged in a matrix, and the imaging starts. When a signal is received, an electric signal generated according to the light that passes through the lens unit and received by each optical element is output to the AD conversion unit 114.

The AD converter 114 receives each electrical signal, converts the received electrical signal into a digital signal having an 8-bit gradation value, and sequentially converts each digital signal for each line of the CCD formed in the matrix. , Write to the line memory 133 of the DSP unit 102.
As described above, the CCD is formed by arranging 240 optical elements horizontally and 320 optical elements vertically, so that 240 pixels horizontally, 320 pixels vertically, A photographed image formed by arranging a total of 76800 pixels in a matrix is obtained. Each pixel has an 8-bit gradation value.

(3) DSP unit 102
As described above, the DSP unit 102 includes the line memory 133, the edge enhancement unit 131, and the setting unit 132.
The DSP unit 102 receives a shooting start signal from the CPU 103 and outputs the same shooting start signal to the camera sensor unit 101.

(Line memory 133)
The line memory 133 includes a memory area for storing pixels for a plurality of lines, and sequentially stores pixels for a plurality of lines output from the AD conversion unit 114.
(Setting unit 132)
The setting unit 132 receives an activation signal from the CPU 103.

When receiving the activation signal, the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement to “strong” as an initial value. The degree of enhancement will be described later.
The setting unit 132 always outputs the set enhancement degree to the edge enhancement unit 131.
The setting unit 132 receives the temperature inside the mobile phone 10 from the temperature sensor 107. When the temperature is received, the threshold value a held inside is compared with the received temperature. When the received temperature is higher than the threshold value a, the setting unit 132 sets the enhancement degree of the setting unit 132 to “weak”. When the received temperature is not higher than the threshold value a, the setting unit 132 does not change the enhancement degree.

  Here, the threshold value a includes a first temperature range (for example, a temperature range of 15 degrees c or more and less than 30 degrees c) around the camera sensor unit 101 and a second temperature range (for example, 30 degrees higher than the first temperature range). A threshold value (for example, 30 degrees c). In the first temperature range, the photoelectric conversion unit of the camera sensor unit 101 operates normally without increasing dark current. On the other hand, in the second temperature range, dark current increases and noise is generated in the photoelectric conversion unit of the camera sensor unit 101.

(Edge enhancement unit 131)
The edge enhancement unit 131 receives the enhancement degree set from the setting unit 132.
Further, the edge enhancement unit 131 receives a captured image generation signal from the DSP unit 102. When the captured image generation signal is received, edge enhancement that sequentially enhances the outline of the target image included in the line is performed on the pixels for the plurality of lines written in the line memory 133 using the set enhancement degree. Then, the enhanced images for a plurality of lines are generated, and the enhanced images for the plurality of lines are sequentially output to the CPU 103.

Further, when edge enhancement for all lines corresponding to the captured image is completed, the edge enhancement unit 131 outputs an enhanced image generation signal indicating completion of generation of the enhanced image to the CPU 103.
Note that edge enhancement is a known technique, and therefore the description thereof is omitted here.
(4) CPU103
As described above, the CPU 103 includes the image recognition unit 121 as a functional configuration. That is, the memory unit 105 stores a computer program for image recognition, and the image recognition unit 121 achieves its function by the CPU 103 operating according to the computer program for image recognition.

  An example of an image recognition target is a barcode. Another example of the target is a two-dimensional code. As two-dimensional codes, QR code, DataMatrix, VeriCode (registered trademark), CP code (registered trademark), and the like are known. These bar codes and two-dimensional codes are associated in advance with predetermined information, for example, code information such as product codes and URLs. Note that image recognition, barcodes, and these two-dimensional codes are well-known techniques, and therefore the description thereof is omitted here.

The image recognition unit 121 performs image recognition processing on a barcode or two-dimensional code that is a target of image recognition, and extracts predetermined information associated with the barcode or two-dimensional code.
The CPU 103 receives from the key input circuit unit 106 a shooting start signal indicating the start of shooting, a start signal indicating the start of recognition processing, a recognition start signal indicating the start of recognition of the emphasized image, and a recognition end indicating the end of recognition of the highlighted image. A signal, a code information editing signal indicating editing of code information, a determination signal indicating determination of code information, and other signals are received.

Upon receiving the activation signal, the CPU 103 outputs the same activation signal to the DSP unit 102, and secures an area for the recognition flag in the memory unit 105, and sets the recognition flag to “OFF” to recognize it. Initialize the flag.
In addition, when receiving the shooting start signal, the CPU 103 outputs the same shooting start signal to the DSP unit 102.

  The CPU 103 sequentially receives the enhanced images for a plurality of lines from the DSP unit 102 and writes the received enhanced images for the plurality of lines to the memory unit 105. When reception of the enhanced image for all lines corresponding to the photographed image is completed, the enhanced image generation signal is received from the DSP unit 102. When the enhanced image generation signal is received, the enhanced image is read from the memory unit 105, and the read enhanced image is output to the display unit 104.

The CPU 103 determines whether the recognition flag is “ON” or “OFF”.
When the recognition flag is “ON”, the image recognition unit 121 of the CPU 103 performs image recognition processing on the emphasized image stored in the memory unit 105, generates code information as a recognition result, and generates The generated code information is output to the display unit 104, and the generated code information is written to the memory unit 105.

When the recognition flag is “OFF”, the CPU 103 determines whether a recognition start signal is received from the key input circuit unit 106. If the recognition start signal is received, the CPU 103 sets the recognition flag to “ON”. If the recognition start signal is not received, the CPU 103 sets the recognition flag to “OFF”.
Further, the CPU 103 determines whether a recognition end signal has been received from the key input circuit unit 106. If the recognition end signal has not been received, the camera sensor unit 101 is again instructed to generate a captured image.

If a recognition end signal has been received, the CPU 103 determines whether a code information editing signal has been received from the key input circuit unit 106. When the code information editing signal is received, the CPU 103 reads a plurality of pieces of code information from the memory unit 105 and outputs the read pieces of code information to the display unit 104.
The CPU 103 determines whether a code information confirmation signal is received from the key input circuit unit 106. When the code information confirmation signal is received, the CPU 103 ends the recognition process.

(5) Temperature sensor 107
The temperature sensor 107 is disposed inside the mobile phone 10, measures the temperature inside the mobile phone 10, and outputs the measured temperature to the DSP unit 102.
Note that the temperature sensor 107 may be disposed inside the mobile phone 10 so as to be close to the camera sensor unit 101, and measure the temperature around the camera sensor unit 101.

(6) Key input circuit unit 106
The key input circuit unit 106 includes numeric keys, left / right / up / down movement keys, a determination key, a power ON key, a power OFF key, and other keys. The operator of the mobile phone 10 receives these keys or a combination of these keys. Accepts input.
When receiving the input of these keys or a combination thereof, the key input circuit unit 106 responds to the input of these keys or the combination thereof, a shooting start signal indicating the start of shooting by the camera sensor unit 101, and activation of the recognition process. A start signal indicating the start of recognition of the emphasized image, a recognition end signal indicating the end of recognition of the emphasized image, a code information editing signal indicating the editing of the code information, a determination signal indicating the determination of the code information, and others These signals are output to the CPU 103.

(7) Display unit 104
The display unit 104 receives the enhanced image from the CPU 103, and displays the received enhanced image in the preview display area.
The display unit 104 receives one or more pieces of code information from the CPU 103, and displays the received one or more pieces of code information in the code information display area. When a plurality of pieces of code information are received, the plurality of pieces of code information are displayed in a list.

(8) Speaker 108, microphone 109, AD / DA conversion unit 110, communication control unit 111, communication unit 112, and antenna 113
The communication unit 112 amplifies the radio frequency signal received by the antenna 113, converts the output signal into an IF signal, amplifies the IF signal, demodulates the amplified IF signal into a baseband signal, and also generates a baseband signal. To modulate a high frequency signal, convert the output to a radio frequency, amplify the radio frequency, and output to the antenna 113. The communication control unit 111 generates a baseband signal and outputs it to the communication unit 112, and receives a baseband signal from the communication unit 112.

In this way, the communication control unit 111, the communication unit 112, and the antenna 113 transmit and receive information to and from other mobile phones connected via the radio base station and the mobile phone network.
The microphone 109 converts sound into an analog electric signal, and the speaker 108 converts the analog sound electric signal into sound and outputs the sound. The AD / DA conversion unit 110 receives digital audio information from the communication control unit 111, converts it into an analog audio electrical signal, and outputs it to the speaker 108. In addition, an analog audio electrical signal is received from the microphone 109, and the received electrical signal is converted into digital audio information and output to the communication control unit 111.

1.2 Operation of Mobile Phone 10 The operations of generating a captured image, generating an emphasized image, and generating code information in the mobile phone 10 will be described with reference to the flowcharts shown in FIGS.
When receiving the activation signal indicating the activation of the recognition process from the key input circuit unit 106, the CPU 103 sets “OFF” in the recognition flag (step S101), and the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement. As an initial value, “strong” is set (step S102).

  Next, when receiving the imaging start signal, the CPU 103 outputs the same imaging start signal to the camera sensor unit 101 via the DSP unit 102, and the photoelectric conversion unit passes through the lens unit and is received by each optical element. The AD converter 114 generates an electrical signal according to the light, converts the electrical signal into a digital signal, and sequentially writes each digital signal as a pixel to the line memory 133 of the DSP unit 102 (step S103). The edge emphasizing unit 131 performs edge emphasis on the pixels for a plurality of lines written in the line memory 133 using the set emphasis degree to emphasize the outline of the target image included in the image. Are generated (step S104), and the CPU 103 writes the emphasized images for a plurality of lines to the memory unit 105 (step S105).

Next, the display unit 104 receives the enhanced image from the CPU 103 and displays the received enhanced image in the preview display area (step S106).
Next, the setting unit 132 receives the temperature inside the mobile phone 10 from the temperature sensor 107 and compares the threshold value a held inside with the received temperature. When the received temperature is higher than the threshold value a (step S107), the setting unit 132 sets the enhancement degree to “weak” (step S109). When the received temperature is not higher than the threshold value a (step S107), the setting unit 132 does not change the enhancement degree (step S108).

  Next, the CPU 103 determines whether the recognition flag is “ON” or “OFF”. If the recognition flag is “ON” (step S110), the image recognition unit 121 of the CPU 103 stores the information in the memory unit 105. The highlighted image is subjected to image recognition processing to generate code information as a recognition result (step S114), the display unit 104 displays the code information (step S115), and the CPU 103 generates the generated code information. Is written into the memory unit 105 (step S116).

  When the recognition flag is “OFF” (step S110), the CPU 103 determines whether or not a recognition start signal is received from the key input circuit unit 106, and if the recognition start signal is received (step S111). If the recognition flag is set to “ON” (step S113) and no recognition start signal is received (step S111), the CPU 103 sets the recognition flag to “OFF” (step S112).

Next, the CPU 103 determines whether or not a recognition end signal has been received from the key input circuit unit 106. If no recognition end signal has been received (step S117), the CPU 103 returns to step S103 and repeats the process.
If a recognition end signal has been received (step S117), the CPU 103 determines whether a code information editing signal has been received from the key input circuit unit 106, and if a code information editing signal has been received (step S118). ), Read a plurality of code information from the memory unit 105, and output the read plurality of code information to the display unit 104. The display unit 104 displays a list of the received plurality of code information in the code information display area ( Step S119).

Next, the CPU 103 determines whether or not a code information confirmation signal is received from the key input circuit unit 106. When the code information confirmation signal is received (step S120), the CPU 103 ends the recognition process. . If the code information confirmation signal has not been received (step S120), the process returns to step S118 to repeat the process.
1.3 Summary When the user performs an operation for starting the recognition function, the camera sensor unit 101 and the AD conversion unit 144 generate a captured image, and the DSP unit 102 generates a plurality of lines for the generated captured image. The edge enhancement signal processing is performed, and the CPU 103 temporarily stores the generated enhanced image in the memory unit 105. The initial edge enhancement of the recognition function is set to strong. The enhanced image stored in the memory unit 105 is displayed on the display unit 104, and the user visually recognizes the enhanced image displayed on the display unit 104. After the enhanced image is displayed, the temperature sensor 107 measures the temperature, and when the measured temperature is higher than the set threshold, the setting unit 132 sets the edge enhancement to be weak. When the measured temperature is lower than or equal to the set threshold value, the setting unit 132 does not change the edge enhancement. After the threshold value is determined, edge enhancement is performed on the regenerated image to generate an emphasized image, and if there is a recognition start instruction from the user, the generated image is recognized. Processing is performed to extract code information. If there is no recognition start instruction from the user, the display of the subject is repeated. The extracted code information is displayed on the display unit 104, and the user determines the displayed code information by visual recognition, and stores it in the memory unit 105 according to the result. The stored code information is then used by the user.

As described above, when the measured temperature is higher than the set threshold value, the setting unit 132 sets edge enhancement to weak. In this case, since the dark current of the photoelectric conversion unit of the camera sensor unit 101 increases, noise increases, and the captured image deteriorates. By setting the deterioration of the image to the enhancement degree “edge” of edge enhancement, Can make up.
2. Modification (1)
A mobile phone 10a as a modification of the above embodiment will be described with reference to the flowchart shown in FIG.

The mobile phone 10 a has the same configuration as the mobile phone 10 and operates in the same manner as the mobile phone 10. Here, the description will focus on differences from the mobile phone 10.
In the mobile phone 10 of the above embodiment, as shown in FIG. 2, the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement to “strong” as an initial value (step S102). The setting unit 132 compares the temperature inside the mobile phone 10 received from the temperature sensor 107 with the threshold value a held inside. When the received temperature is higher than the threshold value a (step S107), the setting unit 132 sets the degree of enhancement to “weak” (step S109), and when the received temperature is not higher than the threshold value a ( In step S107, the setting unit 132 does not change the enhancement degree (step S108).

On the other hand, in the mobile phone 10a, as shown in FIG. 4, the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement to “medium” as an initial value (step S102a).
In addition, the setting unit 132 receives the temperature from the temperature sensor 107 and the temperature inside the mobile phone 10 is less than 30 degrees c (first temperature range), or more than 30 degrees c and less than 40 degrees c (second temperature). Range) or 40 degrees c or more and less than 50 degrees c (third temperature range) (step S107a).

When it is determined that the received temperature is less than 30 degrees c (step S107a), the setting unit 132 does not change the enhancement degree (step S108a). This is because the temperature around the camera sensor unit 101 does not affect the operation of the camera sensor unit 101 in this case.
If it is determined that the received temperature is not less than 30 degrees c and less than 40 degrees c (step S107a), the setting unit 132 sets the enhancement degree to “strong” (step S131). In this case, the temperature around the camera sensor unit 101 is considered to affect the lens unit of the camera sensor unit 101. That is, when the temperature around the lens portion is within the above temperature range (30 degrees c or more and less than 40 degrees c), the refractive index of the lens changes, and thereby the focus by the lens section shifts. A photographed image out of focus is generated. In such a case, the setting unit 132 can compensate for the focus shift by setting the enhancement degree of edge enhancement to “strong”.

  Further, when it is determined that the received temperature is not less than 40 degrees c and less than 50 degrees c (step S107a), the setting unit 132 sets the enhancement degree to “weak” (step S109a). In this case, as described in the above embodiment, the dark current of the photoelectric conversion unit of the camera sensor unit 101 increases, noise increases, and the captured image deteriorates. By setting the degree of emphasis to “weak”, it can be compensated.

  In the above, the setting unit 132 receives the temperature from the temperature sensor 107 and the temperature inside the mobile phone 10 is less than 30 degrees c, 30 degrees c or more and less than 40 degrees c, or 40 degrees c or more. Although it is assumed that it is less than 50 degrees c, these temperature ranges are not limited to this example. Different temperature ranges may be set depending on the arrangement of components in the mobile phone 10 and their characteristics.

3. Modification (2)
A mobile phone 10c as a modification of the above embodiment will be described.
The mobile phone 10 c has the same configuration as the mobile phone 10 and operates in the same manner as the mobile phone 10. The cellular phone 10 c does not have the temperature sensor 107, and uses a timer built in the CPU 103 instead of the temperature sensor 107. The timer keeps track of time.

Here, the operation of the mobile phone 10c will be described with reference to the flowcharts shown in FIGS. 5 to 6, but only the differences from FIGS. 2 to 3 showing the operation of the mobile phone 10 are shown for the sake of simplification. explain.
When receiving the activation signal indicating the activation of the recognition process from the key input circuit unit 106, the CPU 103 sets the timer to “0” (step S151). Thereafter, in step S101, the CPU 103 sets “OFF” in the recognition flag.

  In step S106, after displaying the emphasized image received by the display unit 104, the CPU 103 compares the timer value counted by the timer with the threshold value N held therein. When the timer value is higher than the threshold value N (step S152), the setting unit 132 sets the enhancement degree to “weak” (step S109). When the timer value is not higher than the threshold value N (step S152), the setting unit 132 does not change the enhancement degree (step S108).

As described above, the mobile phone 10 c uses a timer value measured by the timer built in the CPU 103 instead of using the temperature sensor 107. This is because the amount of heat generated from the camera sensor unit 101 or the DSP unit 102 is considered to increase as the processing time elapses.
4). Modification (3)
A mobile phone 10d as a further modification of the modification (2) will be described with reference to the flowchart shown in FIG.

The mobile phone 10d has the same configuration as the mobile phone 10c and operates in the same manner as the mobile phone 10c. Here, it demonstrates centering on difference with the mobile telephone 10c.
In the mobile phone 10c of the above modification, as shown in FIGS. 5 to 6, the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement to “strong” as an initial value (step S102). Further, the CPU 103 compares the timer value counted by the timer with the threshold value N held inside. When the timer value is higher than the threshold value N (step S152), the setting unit 132 sets the enhancement degree to “weak” (step S109). When the timer value is not higher than the threshold value N (step S152), the setting unit 132 does not change the enhancement degree (step S108).

On the other hand, in the mobile phone 10d, as illustrated in FIG. 7, the setting unit 132 sets the enhancement degree indicating the degree of edge enhancement to “medium” as an initial value (step S102b).
Further, the CPU 103 determines whether the timer value is less than 30 seconds, 30 seconds or more and less than 60 seconds, or 60 seconds or more (step S152b).
When determining that the timer value is less than 30 seconds (step S152b), the setting unit 132 does not change the enhancement degree (step S108b). This is because the temperature around the camera sensor unit 101 does not affect the operation of the camera sensor unit 101 in this case.

  If it is determined that the received temperature is not less than 30 seconds and less than 60 seconds (step S152b), the setting unit 132 sets the enhancement degree to “strong” (step S153). In this case, the temperature around the camera sensor unit 101 is considered to affect the lens unit of the camera sensor unit 101. That is, when the elapsed time is 30 seconds or more and less than 60 seconds, the temperature around the lens unit is within a certain temperature range, the refractive index of the lens changes, and thereby the focus by the lens unit is shifted. Therefore, a photographed image with a focus error is generated. In such a case, the setting unit 132 can compensate for the focus shift by setting the enhancement degree of edge enhancement to “strong”.

  Furthermore, when it is determined that the received temperature is 60 seconds or longer (step S150b), the setting unit 132 sets the enhancement degree to “weak” (step S109b). In this case, as described in the above embodiment, the dark current of the photoelectric conversion unit of the camera sensor unit 101 increases, noise increases, and the captured image deteriorates. By setting the degree of emphasis to “weak”, it can be compensated.

In the above description, the CPU 103 determines whether the timer value is less than 30 seconds, 30 seconds or more and less than 60 seconds, or 60 seconds or more. It is not limited to examples. Different time ranges may be set depending on the arrangement of components in the mobile phone 10 and the characteristics thereof.
5. Other Modifications Although the present invention has been described based on the above-described embodiment, it is needless to say that the present invention is not limited to the above-described embodiment. The following cases are also included in the present invention.

(1) The present invention performs character recognition or code recognition of a photographed image with a sensor capable of photographing an image using a photographing element such as a CCD or CMOS, and a DSP or signal processing software for processing a signal from the photographing element. It is an electronic device having a function, a display for displaying an image, a ROM for storing a program, a RAM for a work buffer, and a temperature sensor.
In addition, the present invention provides a sensor that can capture an image using a photographing element such as a CCD or CMOS, a DSP that processes a signal from the photographing element or a signal processing software, and a function that performs character recognition or code recognition of the photographed image. An electronic device including a display for displaying an image, a ROM for storing a program, and a RAM for a work buffer.

(2) In the above embodiment and a plurality of modifications, the degree of edge enhancement is changed depending on the temperature range measured by the temperature sensor or the timer value range measured by the timer. At the same time, the degree of noise removal may be changed.
(3) In the above embodiment and a plurality of modifications, the temperature sensor 107 is connected to the DSP unit 107, and the setting unit 132 of the DSP unit 107 receives the threshold value a and the temperature sensor 107 held therein. When the received temperature is higher than the threshold value a, the setting unit 132 sets the enhancement degree of the setting unit 132 to “weak” and the received temperature is not higher than the threshold value a. Although the setting unit 132 does not change the degree of emphasis, the present invention is not limited to this configuration.

You may comprise as shown below.
The temperature sensor 107 is connected to the CPU 103 instead of being connected to the DSP unit 107, and the memory unit 105 stores the following computer program for temperature comparison.
The computer program for temperature comparison holds a threshold value a inside, a command for receiving the temperature from the temperature sensor 107, and a command for comparing the threshold value a held inside with the temperature received from the temperature sensor 107. When the received temperature is higher than the threshold value a, a command to output an instruction to the setting unit 132 of the DSP 102 to set the enhancement degree of the setting unit 132 to “weak” is included. If the received temperature is not higher than the threshold value a, the instruction to the setting unit 132 is not output.

  The CPU 103 operates according to the computer program for temperature comparison, receives the temperature from the temperature sensor 107, compares the threshold value a held inside with the temperature received from the temperature sensor 107, and the received temperature is If it is higher than the threshold value a, an instruction is output to the setting unit 132 of the DSP 102 so as to set the enhancement degree of the setting unit 132 to “weak”. If the received temperature is not higher than the threshold value a, the instruction to the setting unit 132 is not output.

  (4) The present invention may be the method described above. Further, the present invention may be a computer program that realizes these methods by a computer, or may be a digital signal composed of the computer program. Here, the computer program is configured by combining a plurality of instruction codes indicating instructions for the computer in order to achieve a predetermined function.

  The present invention also provides a computer-readable recording medium such as a flexible disk, hard disk, CD-ROM, MO, DVD, DVD-ROM, DVD-RAM, BD (Blu-ray Disc). ), Recorded in a semiconductor memory or the like. Further, the present invention may be the computer program or the digital signal recorded on these recording media.

Further, the present invention may transmit the computer program or the digital signal via an electric communication line, a wireless or wired communication line, a network represented by the Internet, a data broadcast, or the like.
The present invention may be a computer system including a microprocessor and a memory, wherein the memory stores the computer program, and the microprocessor operates according to the computer program.

In addition, the program or the digital signal is recorded on the recording medium and transferred, or the program or the digital signal is transferred via the network or the like, and is executed by another independent computer system. It is good.
(5) The above embodiment and the above modifications may be combined.
One aspect of the present invention is an image processing apparatus that performs at least edge enhancement processing on an image obtained by photographing with a photographing unit, and obtains a temperature index related to the ambient temperature of the photographing unit. A setting unit that sets an edge enhancement degree of the edge enhancement process based on the acquired temperature index, and an edge enhancement unit that performs an edge enhancement process according to the set edge enhancement degree. .
According to the above aspect, the edge enhancement is performed according to the edge enhancement degree set based on the temperature index related to the ambient temperature of the photographing unit. Therefore, when the photographing unit becomes high temperature, dark current increases and noise is generated. Even in such a case, there is an excellent effect that an image with appropriate edge enhancement can be obtained so as not to hinder image recognition or the like.
Here, the acquisition unit is a temperature sensor that measures and acquires the temperature inside the apparatus as the temperature index, and the setting unit sets the degree of edge enhancement using the measured temperature. You may do that.
According to this configuration, an accurate temperature index can be obtained by measuring the temperature with the temperature sensor.
Here, the acquisition unit is a timer that measures and acquires an elapsed time after the start of imaging by the imaging unit as the temperature index, and the setting unit uses the measured elapsed time to perform the edge enhancement. The degree may be set.
According to this configuration, since the elapsed time after the start of photographing is measured and acquired as the temperature index, the temperature index can be easily obtained.
Here, the setting unit holds an imaging threshold indicating a boundary between a first temperature range around the imaging unit and a second temperature range higher than the first temperature range, and the acquired temperature index The edge enhancement degree may be set based on the shooting threshold.
According to this configuration, an optimum edge enhancement degree can be set based on the acquired temperature index and a predetermined photographing threshold.
Here, the setting means sets a first edge enhancement degree when the temperature related to the acquired temperature index is lower than or equal to the imaging threshold, and the temperature related to the temperature index is higher than the imaging threshold. In this case, a second edge enhancement degree lower than the first edge enhancement degree may be set.
According to this configuration, when the temperature related to the temperature index is higher than the shooting threshold, the second edge enhancement degree lower than the first edge enhancement degree is set, so that edge enhancement that can suppress the influence of noise caused by dark current is set. You can set the degree.
Here, the setting means includes a first temperature range index related to a first temperature range around the photographing means, a second temperature range index related to a second temperature range higher than the first temperature range, and the second temperature range index. A third temperature range index related to the third temperature range higher than the temperature range is held, and the acquired temperature related to the temperature index exists in the first temperature range related to the first temperature range index In the case where the first edge enhancement degree is set and the temperature related to the acquired temperature index exists within the second temperature range related to the second temperature range index, the first edge enhancement degree When a high second edge enhancement degree is set and the acquired temperature index is within the third temperature range of the third temperature range index, the second edge enhancement degree is lower than the first edge enhancement degree You may set the third edge enhancement level .
According to this configuration, when the acquired temperature index is within the second temperature range of the second temperature range index, the second edge enhancement degree is higher than the first edge enhancement degree. Therefore, even when there is a shift in focus due to the lens provided in the photographing unit, it is possible to set the edge enhancement degree that sharpens the edge in the photographed image. Further, when the acquired temperature related to the temperature index exists within the third temperature range related to the third temperature range index, a third edge enhancement degree lower than the first edge enhancement degree is set. Therefore, it is possible to set an edge enhancement degree that can suppress the influence of noise caused by dark current.
According to another aspect of the present invention, there is provided an image processing method used in an image processing apparatus that performs at least edge enhancement processing on an image obtained by photographing with a photographing unit, wherein An acquisition step for acquiring the temperature index, a setting step for setting an edge enhancement degree of the edge enhancement process based on the acquired temperature index, and an edge enhancement for performing an edge enhancement process according to the set edge enhancement degree And a step.
By using this method, edge enhancement according to the degree of edge enhancement set based on the temperature index related to the ambient temperature of the imaging unit is performed, so that when the imaging unit becomes high temperature, dark current increases and noise increases. Even if this occurs, an excellent effect is obtained in that an image that is appropriately edge-enhanced can be obtained so as not to hinder image recognition or the like.
Another aspect of the present invention is used in an image processing computer that performs at least edge enhancement processing on an image obtained by photographing with a photographing means, and causes the computer to perform image processing. An acquisition step for acquiring a temperature index related to the ambient temperature of the photographing means, a setting step for setting an edge enhancement degree of the edge enhancement processing based on the acquired temperature index, and the set And an edge emphasizing step for performing edge emphasis processing according to the degree of edge emphasis.
By causing the computer to execute this computer program, edge enhancement is performed according to the degree of edge enhancement set based on the temperature index related to the ambient temperature of the imaging unit. Even when noise increases due to an increase in image quality, an excellent effect is obtained in that an image that is appropriately edge-enhanced can be obtained so as not to hinder image recognition and the like.
Here, the computer program may be recorded on a computer-readable recording medium.
With this configuration, the computer program is reliably recorded so as to be readable by a computer, and the computer program can be easily transferred.
According to another aspect of the present invention, there is provided an image reading apparatus including the image processing apparatus and the photographing unit, and the image reading apparatus further recognizes an image after edge enhancement processing. It is characterized by including.
According to this configuration, an image with edge enhancement appropriately obtained so as not to hinder image recognition or the like can be obtained and obtained even when a dark current increases and noise occurs due to a high temperature of the photographing unit. An excellent effect is achieved in that good image recognition can be performed on the obtained image.
Here, the photographing unit may include a lens unit including one or more lenses, and at least one of the lenses may be made of resin.
When the lens portion becomes high temperature, the refractive index of the lens changes and the focus by the lens shifts. Due to such a cause, even when the image obtained by the photographing means is deteriorated, it is possible to obtain an image with appropriate edge emphasis and to perform good image recognition on the obtained image. Has an effect.
In particular, since a resin (plastic) lens has a larger change in refractive index with respect to temperature conversion than a glass lens, the image reading provided with a resin lens that is lighter than a glass lens. The apparatus has an effect of improving the reading accuracy and reducing the weight of the image reading apparatus.
Another embodiment of the present invention is a mobile phone including the image reading device.
According to this configuration, as in the case of the image reading apparatus, edge enhancement is appropriately performed so that image recognition or the like is not hindered even when a dark current increases and noise occurs due to a high temperature of the photographing unit. The obtained image is obtained, and an excellent effect that the obtained image can be favorably recognized is obtained.

  Each device constituting the present invention can be manufactured and sold in the electric appliance manufacturing industry in a management manner, continuously and repeatedly.

1 is a block diagram showing a configuration of a mobile phone 10. FIG. 3 is a flowchart showing operations of generating a captured image, generating an emphasized image, and generating code information in the mobile phone 10 Continue to FIG. 3 is a flowchart showing operations of generating a captured image, generating an emphasized image, and generating code information in the mobile phone 10 Continuing from FIG. It is a flowchart which shows operation | movement of the mobile telephone 10a as a modification of embodiment. It is a flowchart which shows operation | movement of the mobile telephone 10c as a modification of embodiment. Continue to FIG. It is a flowchart which shows operation | movement of the mobile telephone 10c as a modification of embodiment. Continue from FIG. It is a flowchart which shows operation | movement of the mobile telephone 10d as a modification.

Explanation of symbols

10 cellular phone 10a cellular phone 10c cellular phone 10d cellular phone 101 camera sensor unit 102 DSP unit 103 CPU
DESCRIPTION OF SYMBOLS 104 Display part 105 Memory part 106 Key input circuit part 107 Temperature sensor 108 Speaker 109 Microphone 110 AD / DA conversion part 111 Communication control part 112 Communication part 113 Antenna 121 Image recognition part 131 Edge emphasis part 132 Setting part

Claims (8)

An image processing apparatus that performs at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens ,
Obtaining means for obtaining a temperature index related to the ambient temperature of the photographing means;
Setting means for setting the edge enhancement degree of the edge enhancement processing based on the acquired temperature index;
Edge enhancement means for performing edge enhancement processing according to the set edge enhancement degree, and
The setting means sets a first edge enhancement degree when the temperature related to the temperature index acquired by the acquisition means is within a predetermined first temperature range, and is set to a first level higher than the first temperature range. A second edge enhancement degree higher than the first edge enhancement degree is set when the temperature is within the second temperature range, and the first edge enhancement degree is set within the third temperature range higher than the second temperature range. An image processing apparatus characterized by setting a third edge enhancement degree lower than the edge enhancement degree . The acquisition means is a temperature sensor that measures and acquires the temperature inside the device as the temperature index,
The image processing apparatus according to claim 1, wherein the setting unit sets the edge enhancement degree using the measured temperature. An image processing method used in an image processing apparatus for performing at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens ,
An acquisition step of acquiring a temperature index related to the ambient temperature of the imaging means;
A setting step for setting an edge enhancement degree of the edge enhancement processing based on the acquired temperature index;
An edge enhancement step for performing an edge enhancement process according to the set edge enhancement degree, and
In the setting step, when the temperature related to the temperature index acquired in the acquisition step is within a predetermined first temperature range, a first edge enhancement degree is set, and a first level higher than the first temperature range is set. A second edge enhancement degree higher than the first edge enhancement degree is set when the temperature is within the second temperature range, and the first edge enhancement degree is set within the third temperature range higher than the second temperature range. And setting a third edge enhancement degree lower than the edge enhancement degree . A computer program used in an image processing computer for performing at least edge enhancement processing on an image obtained by photographing with a photographing means having a lens, and causing the computer to perform image processing,
On the computer,
An acquisition step of acquiring a temperature index related to the ambient temperature of the imaging means;
A setting step for setting an edge enhancement degree of the edge enhancement processing based on the acquired temperature index;
An edge enhancement step for performing an edge enhancement process in accordance with the set edge enhancement degree;
And execute
In the setting step, when the temperature related to the temperature index acquired in the acquisition step is within a predetermined first temperature range, a first edge enhancement degree is set, and a first level higher than the first temperature range is set. A second edge enhancement degree higher than the first edge enhancement degree is set when the temperature is within the second temperature range, and the first edge enhancement degree is set within the third temperature range higher than the second temperature range. A computer program characterized by setting a third edge enhancement degree lower than the edge enhancement degree . The computer program according to claim 4 , wherein the computer program is recorded on a computer-readable recording medium. An image reading apparatus comprising: the image processing apparatus according to claim 1; and an imaging unit having the lens .
The image reading apparatus further includes image recognition means for recognizing an image after edge enhancement processing. The image reading apparatus according to claim 6 , wherein the lens is made of resin. A mobile phone comprising the image reading device according to claim 7 .

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