JP2009141543A - Cellular phone terminal and cellular phone terminal control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cellular phone terminal which prevents frequent setting change of a frame rate for transmitting video images in videophone communication of a cellular phone. <P>SOLUTION: The cellular phone terminal includes: a camera part which generates video data based on either a high speed frame rate or a low speed frame rate among two selectable frame rates; a radio part which transmits the video data as a wireless signal of the video telephone communication; a received signal intensity calculation part which calculates received signal intensity in the videophone communication; and a determination part which uses a high level threshold among two thresholds to the received signal intensity when a low speed frame rate is set in the camera part, when the received signal intensity exceeds a high level threshold, outputs a setting instruction of the high speed frame rate to the camera part, when the high speed frame rate is set in the camera part, uses a low level threshold lower than the high level threshold, and when the received signal intensity becomes less than the low level threshold, outputs a setting instruction of the low speed frame rate. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to video frame rate control in videophone communication using a mobile phone.

  Mobile phone terminals are becoming more multifunctional. Along with this, the power consumption of mobile phone terminals is on an increasing trend. There is also a demand for extending the usable time of the mobile phone terminal.

  At the same time, however, there is a strong demand for miniaturization of mobile phone terminals from users. For this reason, even if measures are taken such as increasing the battery capacity mounted on the mobile phone terminal and extending the usable time, it is not allowed for the mobile phone terminal to increase in size. As described above, the mobile phone terminals are exposed to conflicting demands for multi-function or a longer usable time associated with multi-function and miniaturization.

  An example of a function of a mobile phone terminal that is becoming multifunctional is a videophone function. The videophone function is realized by transmitting together with audio data video data shot by a camera installed in a mobile phone terminal. Therefore, the videophone function is a function that consumes a large amount of power among the functions of the mobile phone terminal. In particular, mobile phone communication requires an increase in radio transmission output in a weak electric field, and the power consumption is the largest.

  Opportunities for using the videophone function are increasing with the recent trend toward broadband communication. There is a need to reduce power consumption in videophone functions and to enable use of mobile phone terminals for a longer time. The following techniques are disclosed as means for suppressing the usable time of the mobile phone terminal in the videophone function.

  Patent Document 1 discloses a mobile phone terminal device that can continue communication with an image even when the line quality deteriorates. The mobile phone terminal device disclosed in Patent Document 1 includes an imaging unit that captures an image, a received electric field strength detection unit that detects a state of the received electric field strength of the local station, and the received electric field strength. An image data conversion means for changing the amount of image data, and an image data conversion means for changing the amount of image data, comprising a pixel number setting means for changing the number of constituent pixels of an image taken by the imaging means based on the received electric field strength information detected by the detection means And communication means for transmitting the image data generated by the means to the communication destination.

  Patent Document 2 discloses a portable information terminal capable of suppressing power consumption required for image display when the battery remaining amount is low. The portable information terminal of Patent Document 2 is a portable information terminal that operates using a battery as a power source, and includes image display means for displaying an image, and remaining amount information indicating the remaining amount of the battery by detecting the remaining amount of the battery. The remaining amount detection means to output and the remaining amount information output by the remaining amount detection means are received, and the frame rate indicating the frequency of updating the image displayed on the image display means is set and set according to the remaining amount information Display control means for displaying an image on the image display means at a frame rate.

  Patent Document 3 discloses a moving picture transmission apparatus that can reduce power consumption and perform longer communication. The video transmission device of Patent Document 3 is a video transmission device in which power is supplied by an internal battery, and includes a remaining amount detection unit that detects a remaining amount of power in the battery, and a remaining power level detected by the remaining amount detection unit. The frame rate calculating means for calculating the frame rate, the moving picture encoding means for encoding the moving picture signal at the frame rate calculated by the frame rate calculating means, and the moving picture encoding means. Transmitting means for transmitting a moving image signal.

In these inventions, the frame rate for image transmission in videophone communication is lowered when the reference threshold value is interrupted, and the frame rate for image transmission in videophone communication is increased when the reference threshold value is restored. However, when the reference value fluctuates significantly, the frame rate also fluctuates frequently in conjunction with this. This impairs smooth display of video output for videophone communications. In addition, there is a problem that the processing load of the CPU of the mobile phone terminal increases due to frequent frame rate change processing, and extra power consumption occurs.
JP 2003-188801 A JP 2007-036702 A JP-A-8-009347

  An object of the present invention is to provide a mobile phone terminal that does not frequently change setting of a frame rate for transmitting video in videophone communication of a mobile phone.

  The mobile phone terminal of the present invention is a frame rate of video to be transmitted to the opposite terminal of videophone communication, and is either a high-speed frame rate or a low-speed frame rate that is lower than the high-speed frame rate. A camera unit that generates video data based on the above, a wireless unit that transmits video data as a radio signal for videophone communication, a received signal strength calculation unit that calculates received signal strength in videophone communication, and a low-speed camera unit When the frame rate is set, the high level threshold is used out of the two thresholds for the received signal strength, and when the received signal strength exceeds the high level threshold, a high-speed frame rate setting command is output to the camera unit. However, when a high frame rate is set for the camera unit, a low level threshold lower than the high level threshold is used. Mobile phone terminals but which when interrupted the low level threshold, and a determination unit for outputting a setting command of the low-speed frame rate to the camera unit.

  The mobile phone terminal control method according to the present invention is a frame rate of a video transmitted to a terminal on the opposite side of a videophone communication, and is a high-speed frame rate of two selectable frame rates or a low-speed frame rate lower than the high-speed frame rate. A step of generating video data based on any one of the above, a step of transmitting the video data as a radio signal for videophone communication, a step of calculating a received signal strength in videophone communication, and a camera unit setting a low-speed frame rate When the received signal strength exceeds the high level threshold value, the high speed frame rate setting command is output to the camera unit when the received signal strength exceeds the high level threshold value. When a high frame rate is set, the received signal strength is reduced by using a low level threshold lower than the high level threshold. There when falling below the low level threshold, and a step of outputting a setting command of the low-speed frame rate to the camera unit.

  According to the present invention, since the setting of the frame rate for transmitting video does not frequently occur in the videophone communication of a mobile phone, it is possible to provide stable videophone communication and increase the number of processing times. Therefore, it is possible to provide a mobile phone terminal that can suppress unnecessary power consumption due to.

  With reference to the accompanying drawings, an embodiment as the best mode for carrying out a mobile phone terminal according to the present invention will be described below.

(First embodiment)
First, the first embodiment will be described. In the first embodiment, the received signal strength is used as a reference value for determination for changing the setting of a frame rate for transmitting an image in videophone communication.

[Description of configuration]
First, the configuration in the present embodiment will be described. FIG. 1 is a functional block diagram showing the configuration of the mobile phone terminal in this embodiment. The mobile phone terminal of this embodiment includes a control unit 10, a radio unit 20, a storage unit 30, a battery unit 40, a camera unit 50, a display unit 60, and an audio processing unit 70. Each component will be described.

  First, the radio unit 20 will be described. The wireless unit 20 includes an antenna for wireless communication and performs wireless communication with a mobile wireless base station (not shown). The radio unit 20 performs reception processing on received data received from the mobile radio base station and outputs the received data to the control unit 10. Further, the radio unit 20 performs transmission processing of transmission data output from the control unit 10 and transmits the transmission data to the mobile radio base station. The wireless communication performed by the wireless unit 20 is based on the conventional technology. The frequency, modulation method, and the like used by the wireless unit 20 depend on the wireless communication method used by the mobile phone terminal, and are not particularly limited in this embodiment.

  Next, the storage unit 30 will be described. The storage unit 30 includes a ROM (Read Only Memory), a RAM (Random Access Memory), and the like. The storage unit 30 stores a processing program for the control unit 10 to perform processing, determination threshold data for the control unit 10 to set a frame rate, and other various data normally used in a mobile phone terminal. The storage unit 30 outputs stored data in response to a command from the control unit 10.

  Next, the battery unit 40 will be described. The battery unit 40 is, for example, a battery. The battery unit 40 supplies power to each component of the mobile phone terminal of this embodiment.

  Next, the camera unit 50 will be described. The camera unit 50 is, for example, a CCD (Charge Coupled Device) camera or the like. The camera unit 50 captures an object such as a caller for transmission to a call destination in videophone communication. The camera unit 50 generates video data such as a photographed object and outputs it to the control unit 10. In this embodiment, the number of images (frames) transmitted per second to the opposite side of the videophone communication is called a frame rate. In the present embodiment, the camera unit 50 generates video data at two frame rates. One value is a high frame rate (hereinafter referred to as a high speed rate). In this embodiment, the high rate is a frame rate that generates 15 frames per second. Another value is a low frame rate (hereinafter referred to as a low rate). In this embodiment, the low speed rate is a frame rate that generates 5 frames per second. The camera unit 50 sets a frame rate to be converted into data based on a frame rate high speed setting command (or a frame rate low speed setting command) output from the frame rate setting unit 13 of the control unit 10. The camera unit 50 converts the captured video data into data based on the set frame rate. Note that the frame rates of the high rate and low rate set by the camera unit 50 are not limited to 15 frames and 5 frames per second. In the present embodiment, the high speed rate is not limited except that the frame rate is higher than the low speed rate.

  Next, the display unit 60 will be described. The display unit 60 is a display device such as an LCD. The display unit 60 displays an image from the call destination of the videophone communication output by the control unit 10 and other characters.

  Next, the audio processing unit 70 will be described. The audio processing unit 70 includes a speaker and a microphone. The voice processing unit 70 acquires the voice spoken by the user with the microphone in the videophone communication, converts the voice into voice data, and outputs the voice data to the control unit 10. In addition, the audio processing unit 70 converts the audio data received from the communication partner output by the control unit 10 in the videophone communication into audio and outputs it from the speaker.

  Next, the control unit 10 will be described. The control unit 10 is configured by a CPU (Central ProCessing Unit), an MPU (Micro Processing Unit), and the like, and executes a processing program stored in the storage unit 30 to provide a communication function and videophone communication provided in the mobile phone terminal. Each function such as a function is realized.

  In the present embodiment, the control unit 10 further includes a determination unit 11, a received signal strength calculation unit 12, and a frame rate setting unit 13.

  First, the received signal strength calculation unit 12 will be described. The received signal strength calculation unit 12 calculates a received signal strength (hereinafter referred to as RSSI: Receive Signal Strength Indicator) from the received radio signal output from the radio unit 20 and outputs the received signal strength to the determination unit 11. In mobile phone communication, RSSI always fluctuates due to fading and the like. When the RSSI fluctuation is severe, the frame rate change setting frequently occurs. Since the RSSI calculation method is a well-known technique, a description thereof will be omitted.

Next, the frame rate setting unit 13 will be described. The frame rate setting unit 13 controls the frame rate setting of the camera unit 50. The frame rate setting unit 13 receives a frame rate decrease command (or a frame rate increase command) output from the determination unit 11, and sets a frame rate setting value at which the camera unit 50 converts the image data into a high-speed rate or a low-rate rate. It selects from among them and outputs a set value change command to the camera unit 50. The frame rate setting unit 13 stores the frame rate currently used by the camera unit 50.
In this embodiment, the frame rate setting unit 13 selects a low rate as the set value of the frame rate when a frame rate reduction command is input. As described above, the low speed rate is a frame rate for generating 5 frames per second. The frame rate setting unit 13 outputs a frame rate low speed setting command to the camera unit 50 so as to change the frame rate to a low speed rate.
On the other hand, when a frame rate increase command is input, the frame rate setting unit 13 selects a high-speed rate as the frame rate setting value. As described above, the high-speed rate is a frame rate that generates 15 frames per second. The frame rate setting unit 13 outputs a frame rate high speed setting command to the camera unit 50 so as to change the frame rate to the high speed rate. The frame rate selected by the frame rate setting unit 13 is not limited to this example. The range of frame rates selected by the frame rate setting unit 13 depends on the range of frame rates that can be set by the camera unit 50. The frame rate setting unit 13 may select a frame rate from more options according to the range of frame rates that can be set by the camera unit 50.

  The determination unit 11 receives the RSSI output from the received signal strength calculation unit 12 and determines whether the RSSI exceeds the threshold or is lower than the threshold. Threshold data for the determination unit 11 to perform RSSI threshold determination is stored in the storage unit 30. The determination unit 11 acquires threshold data from the storage unit 30 and performs RSSI determination. If the determination unit 11 determines that the frame rate of image data in videophone communication should be reduced as a result of the RSSI threshold determination, the determination unit 11 outputs a frame rate reduction command to the frame rate setting unit 13. If the determination unit 11 determines that the frame rate of the image data in the videophone communication should be increased as a result of the RSSI threshold determination, the determination unit 11 outputs a frame rate increase command to the frame rate setting unit 13.

  In the present embodiment, the determination unit 11 has two thresholds for determining the RSSI value. Of the two threshold values, a threshold value with a high RSSI is called “threshold H”, and a threshold value with a low RSSI is called “threshold L”. The determination performed by the determination unit 11 differs depending on the frame rate set in the camera unit 50 when performing the determination. As described above, in this embodiment, the frame rate set to the camera unit 50 is two, that is, a high speed rate and a low speed rate.

The determination unit 11 acquires the frame rate currently set in the camera unit 50 from the frame rate setting unit 13.
First, when the frame rate currently set in the camera unit 50 is a high-speed rate, the determination unit 11 performs determination based on the threshold value L. When the RSSI changes from a value higher than the threshold value L to a lower value, the determination unit 11 determines that the frame rate of the image data in the videophone communication should be reduced. In other cases, determination unit 11 does not determine that the frame rate of image data in videophone communication should be reduced.
On the other hand, when the frame rate currently set in the camera unit 50 is a low speed rate, the determination unit 11 performs determination based on the threshold value H. When the RSSI changes from a value lower than the threshold value H to a higher value, the determination unit 11 determines that the frame rate of the image data in the videophone communication should be increased. In other cases, determination unit 11 does not determine that the frame rate of image data in videophone communication should be reduced.

  The determination performed by the determination unit 11 will be described with reference to FIG. FIG. 2 is an example of a graph showing the relationship between RSSI and time when the mobile phone terminal of this embodiment is performing videophone communication. In FIG. 2, the vertical axis is RSSI, and the horizontal axis is time. Further, “H” indicates the value of the threshold value H, and “L” indicates the value of the threshold value L. Marks “a, b, c, d, e” are written on the time axis for explanation. A description will be given along the flow of the time axis.

(Time from time a to time b)
It is assumed that the frame rate of the camera unit 50 is a high rate at time a. Since the frame rate of the camera unit 50 is a high rate, the determination unit 11 performs determination based on the threshold value L. In this time zone, the RSSI is higher than the threshold value H. The determination unit 11 does not determine that the frame rate should be lowered because the RSSI is not a value lower than the threshold value L.

(Time from time b to time c)
As described above, at time b, the frame rate of the camera unit 50 is a high-speed rate. At time b, the RSSI is lower than the threshold value H. However, since the frame rate of the camera unit 50 is a high rate, the determination unit 11 performs determination based on the threshold value L. The determination unit 11 does not determine that the frame rate should be lowered because the RSSI has not changed to a value lower than the threshold value L. Further, in this time zone, the RSSI goes up and down many times with the threshold value H interposed therebetween. . If the threshold value is only the threshold value H, the frame rate of the camera unit 50 has been set and changed many times during this time period.

(Time from time c to time d)
As described above, at time c, the frame rate of the camera unit 50 is a high-speed rate. At time c, the RSSI is lower than the threshold value L. Since the frame rate of the camera unit 50 is a high rate, the determination unit 11 performs the determination based on the threshold value L. Therefore, the determination unit 11 determines that the frame rate should be reduced at time c. The determination unit 11 outputs a frame rate reduction command to the frame rate setting unit 13 based on the determination. The frame rate setting unit 13 inputs a frame rate reduction command. The frame rate setting unit 13 selects a low frame rate and outputs a frame rate low speed setting command to the camera unit 50. The camera unit 50 inputs a frame rate low speed setting command. The camera unit 50 changes the data conversion frame rate of the video to be shot to a low rate. Thereafter, the frame rate setting unit 13 stores the current frame rate of the camera unit 50 as a low speed rate. The determination unit 11 obtains the current frame rate of the camera unit 50 from the frame rate setting unit 13 to detect that the current frame rate of the camera unit 50 is set to a low rate. Thereafter, the determination unit 11 performs the determination based on the threshold value H because the frame rate of the camera unit 50 is the low rate. In this time zone, the RSSI goes up and down many times with the threshold value L in between. However, since the determination unit 11 performs the determination based on the threshold value H, it does not determine that the frame rate should be increased. If the threshold value is only the threshold value L, the frame rate of the camera unit 50 has been set and changed many times during this time period.

(Time from time d to time e)
As described above, at the time d, the frame rate of the camera unit 50 is the low rate. In this time zone, the RSSI is higher than the threshold value L. However, since the determination unit 11 performs the determination based on the threshold value H, it does not determine that the frame rate should be increased.

(Time after time e)
As described above, at the time e, the frame rate of the camera unit 50 is a low speed rate. At time e, the RSSI is higher than the threshold value H. Since the determination unit 11 performs the determination based on the threshold value H, it determines that the frame rate should be increased at time e. The determination unit 11 outputs a frame rate increase command to the frame rate setting unit 13. The frame rate setting unit 13 inputs a frame rate increase command. The frame rate setting unit 13 selects a high frame rate and outputs a high frame rate setting command to the camera unit 50. The camera unit 50 inputs a frame rate high speed setting command. The camera unit 50 changes the data conversion frame rate of the video to be shot to a high rate. Thereafter, the frame rate setting unit 13 stores the current frame rate of the camera unit 50 as a high-speed rate. The determination unit 11 detects that the current frame rate of the camera unit 50 is set at a high rate by acquiring the current frame rate of the camera unit 50 from the frame rate. Thereafter, the determination unit 11 performs determination based on the threshold value L because the frame rate of the camera unit 50 is a high rate.

  The above is the description of the determination performed by the determination unit 11. As described above, the determination unit 11 performs determination based on the threshold value L when the frame rate of the camera unit 50 is a high-speed rate. Further, the determination unit 11 performs determination based on the threshold value H when the frame rate of the camera unit 50 is a low speed rate. By doing so, the determination unit 11 can perform stable RSSI determination even when the fluctuation of the RSSI serving as a reference for determination is severe near one of the threshold values. Thereby, the frame rate of the camera unit 50 by the frame rate setting unit 13 can be selected stably without frequently switching.

The above is the description of the configuration in this embodiment. In this embodiment, the frame rate of the camera unit 50 can be set to two, but this is not limited to two. If the camera unit 50 can set the frame rate more finely, it is possible to increase the selection of the frame rate specified by the frame rate setting change command output from the frame rate setting unit 13.
In addition, the frame rate setting unit 13 does not specify a frame rate setting value, but may specify a value such as how much the frame rate is decreased (or increased) with respect to the current frame rate value. .
Further, the two threshold values of the determination unit 11 may be variable. When the camera unit 50 can set the frame rate more finely, the determination unit 11 classifies the RSSI into a plurality of stages according to the value, and sets a threshold value H and a threshold value L according to each classification. It is also possible to make a determination. Thus, stable frame rate selection can be performed even when the frame rate gradually decreases.

  Further, the frame rate setting unit 13 determines that the frame rate should be increased (or decreased) according to the current frame rate of the camera unit 50 stored therein, and selects the high rate or the low rate. Also good. In this case, the determination unit 11 always outputs a frame rate increase command when the RSSI is higher than the threshold value H, or outputs a frame rate decrease command whenever the RSSI is lower than the threshold value L. The frame rate setting unit 13 receives a frame rate increase command (or a frame rate decrease command) output from the determination unit 11. The frame rate setting unit 13 selects the frame rate to be set in the camera unit 50 according to the stored current frame rate of the camera unit 50 in the same manner as the determination method of the determination unit 11 described above, and the camera unit 50 Output frame rate high speed setting command (or frame rate low speed setting command). In this way, the RSSI threshold determination and the frame rate increase or decrease determination may be shared by the determination unit 11 and the frame rate setting unit 13.

  Further, the frame rate setting unit 13 may exist in the camera unit 50. The reception strength calculation unit 12 may be present in the radio unit 20. These are not limited as long as they can function similarly.

[Description of operation method]
Next, an operation method in this embodiment will be described. FIG. 3 shows an operation flow in this embodiment.

(Step A01)
The mobile phone terminal in this embodiment starts videophone communication.

(Step A02)
The determination unit 11 determines whether the mobile phone terminal continues the videophone communication state. If the videophone communication state is being continued, the process proceeds to step A03. On the other hand, when the videophone communication is terminated, this operation is terminated.

(Step A03)
The determination unit 11 acquires the threshold value H and the threshold value L stored in the storage unit 30 from the storage unit 30.

(Step A04)
The determination unit 11 acquires the current frame rate setting of the camera unit 50 stored in the frame rate setting unit 13 from the frame rate setting unit 13.

(Step A05)
The determination unit 11 determines whether the current frame rate of the camera unit 50 is a high speed rate. When the current frame rate of the camera unit 50 is the high speed rate, the process proceeds to step A06. On the other hand, if the current frame rate of the camera unit 50 is not a high speed rate (if it is a low speed rate), the process proceeds to step A12.

(Step A06)
The reception signal strength calculation unit 12 receives the reception signal output from the radio unit 20 and calculates RSSI. The received signal strength calculation unit 12 outputs the calculated RSSI to the determination unit 11.

(Step A07)
The determination unit 11 receives the RSSI output from the received signal strength calculation unit 12. Since the current frame rate of the camera unit 50 is a high-speed rate, the determination unit 11 performs determination based on the threshold value L. The determination unit 11 determines whether the input RSSI is lower than the threshold value L. When RSSI is a value lower than the threshold value L, the process proceeds to step A08. On the other hand, if the RSSI is not lower than the threshold value L, the process proceeds to step A11.

(Step A08)
The determination unit 11 determines that the frame rate should be reduced because the RSSI is lower than the threshold value L. The determination unit 11 outputs a frame rate reduction command to the frame rate setting unit 13.

(Step A09)
The frame rate setting unit 13 inputs a frame rate reduction command output from the determination unit 11. The frame rate setting unit 13 selects a low rate from the frame rates of the camera unit 50. The frame rate selection unit 13 outputs a frame rate low speed setting command to the camera unit 50 so as to change the frame rate of the camera unit 50 to the low speed rate.

(Step A10)
The camera unit 50 inputs a frame rate low speed setting command output from the frame rate setting unit 13. The camera unit 50 changes the setting of the frame rate to a low speed rate. The frame rate setting unit 13 stores that the current frame rate of the camera unit 50 is set to a low speed rate. Thereafter, the process returns to step A02.

(Step A11)
The determination unit 11 does not determine that the frame rate should be lowered because the RSSI is not a value lower than the threshold value L. Therefore, the process returns to step A02.

(Step A12)
The reception signal strength calculation unit 12 receives the reception signal output from the radio unit 20 and calculates RSSI. The received signal strength calculation unit 12 outputs the calculated RSSI to the determination unit 11.

(Step A13)
The determination unit 11 receives the RSSI output from the received signal strength calculation unit 12. Since the current frame rate of the camera unit 50 is the low speed rate, the determination unit 11 performs determination based on the threshold value H. The determination unit 11 determines whether or not the input RSSI is higher than the threshold value H. If the RSSI is higher than the threshold value H, the process proceeds to step A14. On the other hand, if the RSSI is not higher than the threshold value H, the process proceeds to step A17.

(Step A14)
The determination unit 11 determines that the frame rate should be increased because the RSSI is higher than the threshold value H. The determination unit 11 outputs a frame rate increase command to the frame rate setting unit 13.

(Step A15)
The frame rate setting unit 13 inputs a frame rate increase command output from the determination unit 11. The frame rate setting unit 13 selects a high rate from the frame rates of the camera unit 50. The frame rate selection unit 13 outputs a frame rate high-speed setting command to the camera unit 50 so as to change the setting of the frame rate of the camera unit 50 to the high-speed rate.

(Step A16)
The camera unit 50 inputs a frame rate high-speed setting command output from the frame rate setting unit 13. The camera unit 50 changes the setting of the frame rate to the high speed rate. The frame rate setting unit 13 stores that the current frame rate of the camera unit 50 is set to a high rate. Thereafter, the process returns to step A02.

(Step A17)
The determination unit 11 does not determine that the frame rate should be increased because the RSSI is not higher than the threshold value H. Therefore, the process returns to step A02.

  The above is the description of the operation method of this embodiment. The determination unit 11 performs determination based on the threshold value L when the frame rate of the camera unit 50 is set at a high speed rate. On the other hand, when the frame rate of the camera unit 50 is set at the low speed rate, the determination unit 11 performs determination based on the threshold value H. As described above, by performing the determination using the two threshold values, the determination unit 11 can perform a stable determination even when the fluctuation of the reference RSSI is intense near one of the threshold values. Become. Accordingly, the frame rate setting unit 13 can stably select the frame rate.

In step A03, the determination unit 11 acquires the threshold value H and the threshold value L from the storage unit 30, but this may be acquired only when there is a change in each threshold value.
In step A04, the determination unit 11 acquires the current frame rate of the camera unit 50 from the frame rate setting unit 13, but this may be acquired only when the frame rate is changed.
Further, in step A07 and step A13, the determination unit 11 performs each threshold value determination of RSSI, but does not limit which determination is performed when RSSI is at the limit value of each threshold value.
Further, in step A10 and step A16, the frame rate setting unit 13 stores that the current frame rate of the camera unit 50 has been changed, but this receives a setting change completion notification from the camera unit 50. It may be a method that works.

Further, the frame rate setting unit 13 determines that the frame rate should be increased (or decreased) in accordance with the stored current frame rate of the camera unit 50, and selects the high speed rate or the low speed rate. It is good also as a method.
In this case, when the RSSI is higher than the threshold value H in step A07, the determination unit 11 always outputs a frame rate increase command in step A08, or the RSSI is lower than the threshold value L in step A07. Sometimes, in step A08, a frame rate reduction command is always output.
In step A09, the frame rate setting unit 13 inputs a frame rate increase command (or a frame rate decrease command) output from the determination unit 11. Further, in step A09, the frame rate setting unit 13 selects a frame rate to be set in the camera unit 50 according to the stored current frame rate of the camera unit 50 in the same manner as the determination method of the determination unit 11 described above. Then, a frame rate high speed setting command (or a frame rate low speed setting command) is output to the camera unit 50. In this way, the RSSI threshold determination and the frame rate increase or decrease determination may be shared by the determination unit 11 and the frame rate setting unit 13.

  The above is the description of the first embodiment.

(Second embodiment)
Next, a second embodiment will be described. In the second embodiment, the remaining battery level is used as a reference value for determination in changing the setting of the frame rate for transmitting an image in videophone communication.

[Description of configuration]
First, the configuration in the present embodiment will be described. FIG. 4 is a functional block diagram showing the configuration of the mobile phone terminal according to the present embodiment. In the present embodiment, a portion different from the first embodiment will be described. As in the first embodiment, the mobile phone terminal of FIG. 4 includes a control unit 10, a radio unit 20, a storage unit 30, a battery unit 40, a camera unit 50, a display unit 60, and an audio processing unit 70. And an input unit 80.

  In the present embodiment, the radio unit 20, the storage unit 30, the battery unit 40, the camera unit 50, the display unit 60, the audio processing unit 70, and the input unit 80 are the same as those in the first embodiment. Description is omitted.

  Next, the control unit 10 will be described. As in the first embodiment, the control unit 10 includes a determination unit 11, a received signal strength calculation unit 12, a frame rate setting unit 13, and further includes a battery remaining amount calculation unit 14.

  In the present embodiment, the frame rate setting unit 13 and the received signal strength calculation unit 12 are the same as those in the first embodiment, and thus description thereof is omitted.

  The battery remaining amount calculation unit 14 is connected to the battery unit 40. The remaining battery level calculation unit 14 calculates the remaining battery level of the battery unit 40. The remaining battery level is the output voltage of the battery unit 40. The remaining battery level of the mobile phone terminal is calculated based on the relationship between the resistance of each circuit in the mobile phone terminal and the current consumption flowing to each circuit. The current consumption increases and decreases depending on the function provided by the mobile phone terminal and the state of wireless communication. For this reason, the battery remaining amount increases or decreases with fluctuations in current consumption. Although there are several types of battery remaining amount calculation methods, the calculation method is not particularly limited in this embodiment. The remaining battery level calculation unit 14 outputs the calculated remaining battery level to the determination unit 11.

  In this embodiment, the determination unit 11 inputs the remaining battery level output from the remaining battery level calculation unit 14 and determines whether the remaining battery level exceeds or falls below the threshold value. The threshold data for the determination unit 11 to perform determination is stored in the storage unit 30. The determination unit 11 acquires threshold data from the storage unit 30 and determines the remaining battery level. If the determination unit 11 determines that the frame rate of the image data in the videophone communication should be reduced as a result of the determination of the remaining battery level, the determination unit 11 outputs a frame rate reduction command to the frame rate setting unit 13. If the determination unit 11 determines that the frame rate of the image data in videophone communication should be increased as a result of the determination of the remaining battery level, the determination unit 11 outputs a frame rate increase command to the frame rate setting unit 13.

  In this embodiment, the determination unit 11 has two thresholds for performing determination on the remaining battery level. Of the two threshold values, the threshold value at a high battery level is called “threshold H”, and the threshold value at a low battery level is called “threshold L”. The determination performed by the determination unit 11 differs depending on the frame rate currently set in the camera unit 50. As described above, in this embodiment, the frame rate set to the camera unit 50 is two, that is, a high speed rate and a low speed rate.

The determination unit 11 acquires the frame rate currently set in the camera unit 50 from the frame rate setting unit 13.
First, when the frame rate set in the camera unit 50 is a high-speed rate, the determination unit 11 performs determination based on the threshold value L. When the remaining battery level changes from a value higher than the threshold value L to a lower value, the determination unit 11 determines that the frame rate of image data in videophone communication should be reduced. In other cases, determination unit 11 does not determine that the frame rate of image data in videophone communication should be reduced.
On the other hand, when the frame rate set in the camera unit 50 is a low speed rate, the determination unit 11 performs determination based on the threshold value H. When the remaining battery level changes from a value lower than the threshold value H to a higher value, the determination unit 11 determines that the frame rate of image data in videophone communication should be increased. In other cases, determination unit 11 does not determine that the frame rate of image data in videophone communication should be reduced.
Since the determination method for the remaining battery level and the threshold value H and the threshold value L by the determination unit 11 is the same as the determination method for the RSSI variation and the threshold value H and the threshold value L described with reference to FIG. Omitted.

  The above is the description of the configuration in this embodiment. As described above, the determination unit 11 performs determination based on the threshold value L when the frame rate of the camera unit 50 is a high-speed rate. Further, the determination unit 11 performs determination based on the threshold value H when the frame rate of the camera unit 50 is a low speed rate. By doing so, the determination unit 11 can determine the stable battery remaining amount even when the variation in the remaining battery level, which is a criterion for determination, is severe near one of the threshold values due to the variation in the current consumption of the mobile phone terminal. Can be performed. Thereby, the frame rate of the camera unit 50 by the frame rate setting unit 13 can be selected stably without frequently switching.

In this embodiment, the frame rate of the camera unit 50 can be set to two, but this is not limited to two. If it can be set more finely, it is possible to increase the selection of the frame rate specified by the frame rate high speed setting command (or the frame rate low speed setting command) output from the frame rate setting unit 13.
Further, instead of designating a set value, it is possible to designate a value in such a manner that the frame rate is decreased (or increased) with respect to the current frame rate value.
Further, the two threshold values of the determination unit 11 may be variable. When the camera unit 50 can set the frame rate more finely, the determination unit 11 classifies the remaining battery level into a plurality of stages, and sets the threshold value H and the threshold value L for each of the determinations. Is also possible. As a result, stable frame rate selection can be performed even when setting is made such that the frame rate gradually decreases as the remaining battery level decreases.

  Further, the frame rate setting unit 13 determines that the frame rate should be increased (or decreased) according to the current frame rate of the camera unit 50 stored therein, and selects the high rate or the low rate. Also good. In this case, the determination unit 11 always outputs a frame rate increase command when the remaining battery level becomes higher than the threshold value H, or always outputs a frame rate decrease command when the remaining battery level becomes lower than the threshold value L. Is output. The frame rate setting unit 13 receives a frame rate increase command (or a frame rate decrease command) output from the determination unit 11. The frame rate setting unit 13 selects the frame rate to be set in the camera unit 50 according to the stored current frame rate of the camera unit 50 in the same manner as the determination method of the determination unit 11 described above, and the camera unit 50 Output frame rate high-speed setting command (or frame rate low-speed setting command). As described above, the determination of the remaining battery level and the determination of increase or decrease of the frame rate may be shared by the determination unit 11 and the frame rate setting unit 13.

  Further, the battery remaining amount calculation unit 14 may exist in the battery unit 40. These are not limited as long as they can function similarly.

[Description of operation method]
Next, an operation method in this embodiment will be described. FIG. 5 shows an operation flow in this embodiment. In the present embodiment, a portion different from the first embodiment will be described.
In FIG. 5, Step B06, Step B07, Step B12, and Step B13 are different from the first embodiment. Step A01 to step A05, step A08 to step A11, and step A14 to step A17 are the same operation methods as those in the first embodiment, and thus description thereof is omitted.

(Step B06)
The remaining battery level calculation unit 14 calculates the remaining battery level of the battery unit 40. The remaining battery level calculation unit 14 outputs the calculated remaining battery level to the determination unit 11.

(Step B07)
The determination unit 11 inputs the remaining battery level output from the remaining battery level calculation unit 14. Since the current frame rate of the camera unit 50 is a high-speed rate, the determination unit 11 performs determination based on the threshold value L. The determination unit 11 determines whether the input remaining battery level is lower than the threshold value L. If the remaining battery level is lower than the threshold value L, the process proceeds to step A08. On the other hand, if the remaining battery level is not lower than the threshold value L, the process proceeds to step A11.

(Step B12)
The remaining battery level calculation unit 14 calculates the remaining battery level of the battery unit 40. The remaining battery level calculation unit 14 outputs the calculated remaining battery level to the determination unit 11.

(Step B13)
The determination unit 11 inputs the remaining battery level output from the remaining battery level calculation unit 14. Since the current frame rate of the camera unit 50 is the low speed rate, the determination unit 11 performs determination based on the threshold value H. The determination unit 11 determines whether the input remaining battery level is higher than the threshold value H. When the remaining battery level is higher than the threshold value H, the process proceeds to step A14. On the other hand, if the remaining battery level is not higher than the threshold value H, the process proceeds to step A17.

  The above is the description of the operation method according to the present embodiment. The determination unit 11 performs determination based on the threshold value L when the frame rate of the camera unit 50 is set at a high speed rate. On the other hand, when the frame rate of the camera unit 50 is set at the low speed rate, the determination unit 11 performs determination based on the threshold value H. As described above, by performing the determination using the two threshold values, the determination unit 11 can perform a stable determination even when the reference remaining battery level varies greatly around the two threshold values. Become. Accordingly, the frame rate setting unit 13 can stably select the frame rate.

In step A03, the determination unit 11 acquires the threshold value H and the threshold value L from the storage unit 30, but this may be acquired only when there is a change in each threshold value.
In step A04, the half-value shame unit 11 acquires the current frame rate of the camera unit 50 from the frame rate setting unit 13, but this may be acquired only when the frame rate is changed.
In step A07 and step A13, the determination unit 11 determines each threshold value of the remaining battery level. When the remaining battery level is at the limit value of each threshold value, the frame rate should be decreased (or the frame rate should be increased). ) Is determined depending on the design and is not particularly limited.
Further, in step A10 and step A16, the frame rate setting unit 13 stores that the current frame rate of the camera unit 50 has been changed, but this receives a setting change completion notification from the camera unit 50. It may be a method that works.

Further, the frame rate setting unit 13 determines that the frame rate should be increased (or decreased) in accordance with the stored current frame rate of the camera unit 50, and selects the high speed rate or the low speed rate. It is good also as a method.
In this case, when the remaining battery level is higher than the threshold value H in step A07, the determination unit 11 always outputs a frame rate increase command in step A08, or the remaining battery level is lower than the threshold value L in step A07. When the value is reached, a frame rate reduction command is always output in step A08.
In step A09, the frame rate setting unit 13 inputs a frame rate increase command (or a frame rate decrease command) output from the determination unit 11. Further, in step A09, the frame rate setting unit 13 selects a frame rate to be set in the camera unit 50 according to the stored current frame rate of the camera unit 50 in the same manner as the determination method of the determination unit 11 described above. Then, a frame rate high speed setting command (frame rate low speed setting command) is output to the camera unit 50. As described above, the determination of the remaining battery level and the determination of increase or decrease of the frame rate may be shared by the determination unit 11 and the frame rate setting unit 13.

  The above is the description of the second embodiment.

  As described above, in the mobile phone terminal of the present invention, the determination unit 11 performs determination based on the threshold value L when the frame rate of the camera unit 50 is set at a high rate. On the other hand, when the frame rate of the camera unit 50 is set at the low speed rate, the determination unit 11 performs determination based on the threshold value H. As described above, the determination using the two threshold values enables the determination unit 11 to perform stable determination even when the reference value fluctuates significantly. In addition, the frame rate setting unit 13 can stably select the frame rate. Accordingly, the camera unit 50 can stably maintain a frame rate for converting captured images into data.

The first embodiment and the second embodiment are not realized only independently. The first embodiment and the second embodiment can be realized in combination with each other. For example, in the configuration of FIG. 4, the determination criterion of the determination unit 11 is determined by combining both RSSI and the remaining battery level. The determination unit 11 can gradually decrease the frame rate of the camera unit 50 as the remaining battery level decreases, and further change the frame rate based on the RSSI value according to each step. It is. In this case as well, stable videophone communication video can be provided by using two threshold values for each determination of the remaining battery level and RSSI.
In addition, the present invention is not limited to the videophone communication according to the above-described embodiment, and can be applied to various techniques for ensuring stability in the process of determining based on a threshold value.

It is a functional block diagram of 1st Example in this invention. It is the graph which showed the example of the relationship between RSSI during videophone communication, and time. It is an operation | movement flow of 1st Example in this invention. It is a functional block diagram of 2nd Example in this invention. It is an operation | movement flow of 2nd Example in this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 Control part 11 Determination part 12 Received signal strength calculation part 13 Frame rate setting part 14 Battery remaining charge calculation part 20 Radio | wireless part 30 Memory | storage part 40 Battery part 50 Camera part 60 Display part 70 Audio | voice processing part 80 Input part

Claims (13)

The frame rate of the video to be transmitted to the opposite terminal of the videophone communication, based on either the high-speed frame rate or the low-speed frame rate lower than the high-speed frame rate, out of the two selectable frame rates. A camera unit to generate,
A wireless unit that transmits the video data as a wireless signal for the videophone communication;
A received signal strength calculating unit for calculating received signal strength in the videophone communication;
When a low-speed frame rate is set in the camera unit, when the received signal strength exceeds the high level threshold value using the high level threshold value of the two threshold values for the received signal strength, the camera unit Output the high-speed frame rate setting command to
When a high-speed frame rate is set in the camera unit, a low-level threshold lower than the high-level threshold is used, and the low-speed frame is sent to the camera unit when the received signal strength falls below the low-level threshold. A determination unit that outputs a rate setting command;
A mobile phone terminal comprising: The mobile phone terminal according to claim 1,
When the received signal strength exceeds the high level threshold, the determination unit always outputs the high-speed frame rate setting command to the camera unit, and the received signal strength interrupts the low level threshold Always outputs a setting command for the low-speed frame rate to the camera unit,
When the camera unit is generating the video data based on the low-speed frame rate, when the high-speed frame rate setting command is input, the frame rate is changed to the high-speed frame rate,
A cellular phone terminal that changes the frame rate to the low-speed frame rate when the setting instruction for the low-speed frame rate is input when the video data is generated based on the high-speed frame rate. The mobile phone terminal according to claim 1 or 2, wherein
The camera unit can generate the video data based on one high-speed frame rate selected from a plurality of high-speed frame rates or one low-speed frame rate selected from a plurality of low-speed frame rates. And
The determination unit can change the high level threshold corresponding to the selected one high-speed frame rate, and can change the low level threshold corresponding to the selected one low-speed frame rate. Mobile phone terminal. The mobile phone terminal according to claim 1,
A battery unit that calculates a remaining battery level that is a remaining power level;
When the camera unit is generating the video data based on a low-speed frame rate, the determination unit uses a high level battery threshold of two thresholds for the battery remaining amount, and the battery remaining amount is When the high-level battery threshold is exceeded, the high-speed frame rate setting command is output to the camera unit,
When the camera unit is generating the video data based on a high-speed frame rate, when the battery level is below the low level battery threshold using a low level battery threshold lower than the high level battery threshold A mobile phone terminal that outputs a setting command for the low-speed frame rate to the camera unit; The mobile phone terminal according to claim 4, wherein
The determination unit always outputs the high-speed frame rate setting command to the camera unit when the remaining battery level exceeds the high-level battery threshold, and the remaining battery level interrupts the low-level battery threshold. If so, always output the low frame rate setting command to the camera unit,
When the camera unit is generating the video data based on the low-speed frame rate, when the high-speed frame rate setting command is input, the frame rate is changed to the high-speed frame rate,
A cellular phone terminal that changes the frame rate to the low-speed frame rate when the setting instruction for the low-speed frame rate is input when the video data is generated based on the high-speed frame rate. The mobile phone terminal according to claim 4 or 5, wherein
The camera unit generates the video data based on one low-speed frame rate selected from one of the plurality of high-speed frame rates or one of the plurality of low-speed frame rates. Is configurable,
The determination unit can change the high-level battery threshold corresponding to the selected one high-speed frame rate, and can change the low-level battery threshold corresponding to the selected one low-speed frame rate. Is possible mobile phone terminal. The frame rate of the video to be transmitted to the opposite terminal of the videophone communication, based on either the high-speed frame rate or the low-speed frame rate lower than the high-speed frame rate, out of the two selectable frame rates. Generating step;
Transmitting the video data as a radio signal for the videophone communication;
Calculating received signal strength in the videophone communication;
When the camera unit sets a low frame rate, the camera unit uses a high level threshold value of two threshold values for the received signal strength, and the received signal strength exceeds the high level threshold value. Output the high-speed frame rate setting command to
When the camera unit sets a high frame rate, a low level threshold lower than the high level threshold is used, and when the received signal strength interrupts the low level threshold, the low speed frame is sent to the camera unit. Outputting a rate setting command;
A mobile phone terminal control method comprising: The mobile phone terminal control method according to claim 7,
The step of outputting the setting command includes:
When the received signal strength exceeds the high level threshold, the high-speed frame rate setting command is always output to the camera unit, and when the received signal strength interrupts the low level threshold, the Outputting a low-speed frame rate setting command to the camera unit;
The data conversion step includes:
When the video data is generated based on the low-speed frame rate, when the high-speed frame rate setting command is input, the frame rate is changed to the high-speed frame rate,
When the video data is generated based on the high-speed frame rate, the mobile phone terminal control method includes the step of changing the frame rate to the low-speed frame rate when the low-speed frame rate setting command is input. . The mobile phone terminal control method according to claim 7 or claim 8,
The step of outputting the setting command includes:
The high-level threshold and the low-level threshold are respectively set to one high-speed frame rate selected from the plurality of high-speed frame rates or one low-speed frame rate selected from the plurality of low-speed frame rates. A mobile phone terminal control method including a step of changing correspondingly. The mobile phone terminal control method according to claim 7,
A cellular phone terminal control method further comprising: calculating a remaining battery level that is a remaining power level. The mobile phone terminal control method according to claim 10,
The step of outputting the setting command includes:
When the camera unit is generating the video data based on a low-speed frame rate, the battery level is set to the high level battery threshold by using a high level battery threshold of the two thresholds for the battery level. If exceeded, output the setting instruction of the high-speed frame rate to the camera unit,
When the camera unit is generating the video data based on a high-speed frame rate, using a low level battery threshold that is lower than the high level threshold, and the remaining battery level is below the low level battery threshold. And a step of outputting a command for setting the low-speed frame rate to the camera unit. The mobile phone terminal control method according to claim 11,
The step of outputting the setting command always outputs the setting command of the high-speed frame rate to the camera unit when the remaining battery level exceeds the high level battery threshold, and the remaining battery level is the low level battery. When the threshold is interrupted, the step of always outputting the setting instruction of the low-speed frame rate to the camera unit;
The data conversion step includes:
When the video data is generated based on the low-speed frame rate, when the high-speed frame rate setting command is input, the frame rate is changed to the high-speed frame rate,
When the video data is generated based on the high-speed frame rate, the mobile phone terminal control method includes the step of changing the frame rate to the low-speed frame rate when the low-speed frame rate setting command is input. . The mobile phone terminal control method according to claim 11 or 12,
The step of outputting the setting command includes the high-level battery at one high-speed frame rate selected from a plurality of high-speed frame rates or one low-speed frame rate selected from a plurality of low-speed frame rates. A mobile phone terminal control method, comprising: changing a threshold value and the low-level battery threshold value in association with each other.

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