JP2008017030A - Portable terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a portable terminal which allows a radio communication function and a camera function to be used at the same time, and suppresses the influence of high frequency radiation noise generated from electric circuits of the camera on the radio communication function. <P>SOLUTION: The portable terminal having a radio communication function and a camera comprises a means 109 for coding parallel-formed image data outputted from the camera so as to restrict the continuous output of the same code, a means 110 for converting the parallel-formed image data coded by the coding means 109 to serial data, a decoding process means 111 for recovering the image data upon receipt of the serial data outputted from the parallel/serial converting means 110, and a means 112 for converting the received serial data into parallel-formed data. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a portable terminal device including a wireless communication function for communicating using radio waves and a camera capable of photographing an arbitrary subject, and more particularly to reduction of radiation noise during camera operation.

  In recent years, mobile terminal devices such as mobile phone terminals are increasingly equipped with a camera capable of photographing an arbitrary subject. This type of camera generally uses an individual imaging device such as a CCD image sensor, and operates in synchronization with a clock signal having a frequency of about several tens of MHz.

  For this reason, when using a camera mounted on a portable terminal device, harmonic components of the clock signal, that is, frequency components that are integral multiples of the fundamental frequency of the clock signal, for example, conductor patterns and wiring on the circuit board Radiates from etc. However, a mobile terminal device such as a mobile phone terminal is equipped with not only a camera but also a wireless communication function for communication using radio waves, and the circuit of the camera and the circuit for realizing the wireless communication function are mutually connected. Arranged in close proximity. Therefore, high-frequency radiation noise generated by the operation of the camera adversely affects the wireless communication function. Specifically, the reception sensitivity of the wireless communication function deteriorates due to radiation noise.

  Therefore, for example, in the prior art disclosed in Patent Document 1, the mobile phone terminal stops the supply of the clock signal during the reception period of the control signal during standby reception for intermittently receiving the control signal from the base station. is suggesting. That is, the camera operation is temporarily stopped during communication.

In the prior art disclosed in Patent Document 2, when the operation of the camera is temporarily stopped, an image taken before the stop is displayed, and control is performed so as not to cause a sense of incongruity in the display content. Has proposed.
JP 2002-261880 A JP 2005-45563 A

  However, for example, when trying to realize the function of a videophone, since the operation of the camera cannot be stopped even during communication, it is impossible to adopt the conventional technique disclosed in Patent Document 1. Inevitably, it is inevitable that the reception sensitivity is lowered due to radiation noise from the camera.

  In particular, a YUV data bus is often used for a circuit for processing a camera signal, and there is a possibility that the same code composed of a plurality of bits appears continuously or periodically on the YUV data bus. Since it is high, harmonics including various frequency components are generated as in the case of the random signal. For example, when the basic frequency of the clock signal is N, the code having the same value of 2 bits is N / 2 times the frequency, and the code having the same value of 3 bits is the N / 3 times the frequency. In addition to the higher harmonics, harmonics with a frequency N / 2 times the fundamental frequency and harmonics with a frequency N / 3 times the fundamental frequency are also generated from the YUV data bus. Radiation noise has an adverse effect on various frequency bands including bands. For this reason, even if the frequency of the clock signal is devised, it is inevitable that the reception sensitivity of the radio circuit is lowered due to the influence of radiation noise when the camera is used.

  Note that the YUV data bus represents YUV data representing a color by three pieces of information: a luminance signal (Y), a difference (U) between the luminance signal and the blue component, and a difference (V) between the luminance signal and the red component. This is a bus (collection of signal lines) to be handled.

  The present invention is a portable terminal device that can simultaneously use a wireless communication function and a camera function, and that can suppress the influence of high-frequency radiation noise generated from an electric circuit of the camera on the wireless communication function. The purpose is to provide.

  A first invention (Claim 1) is a portable terminal device including a wireless communication function for communicating using radio waves and a camera capable of photographing an arbitrary subject, and is paralleled every N bits from the camera. Encoding means for encoding the parallel format image data output to the same code so as to suppress continuous output of the same code, and the encoded parallel format image data output from the encoding means as serial data Parallel / serial conversion means for converting, serial data output from the parallel / serial conversion means, decoding processing means for decoding and restoring the image data, and output from the parallel / serial conversion means Serial / parallel conversion means for receiving serial data and converting it into parallel data is provided.

  In the first invention, before the parallel format image data is converted into serial data, the continuous output of the same code is suppressed by using the encoding means. By preventing the same code from appearing continuously, it is possible to suppress a signal component having a frequency lower than the fundamental frequency of the clock signal from appearing on the signal line for transferring camera signal data. Thereby, the frequency interval of each frequency component in the frequency spectrum of the radiation noise is widened, and a frequency band that is not affected by the radiation noise is formed. Therefore, the frequency band that is not affected by radiation noise matches the frequency band used in wireless communication, or the frequency band of each frequency component included in the radiation noise and the frequency band used in wireless communication do not overlap. By adjusting in advance, the influence of radiation noise can be greatly reduced.

  According to a second invention (invention 2), in the first invention, the encoding means adds at least one redundant bit in the middle or around the parallel image data inputted every N bits. Thus, M-bit encoded parallel data having a number of bits larger than N bits is generated.

  In the second aspect of the invention, encoded parallel data can be generated by adding redundant bits. Further, by devising the value of the redundant bit to be added, it is possible to suppress the appearance of a plurality of bits of the same code continuously.

  According to a third invention (Claim 3), in the second invention, the encoding means obtains a result obtained by inverting the value of at least one bit in the inputted N-bit data as the value of the redundant bit to be added. It is characterized by outputting.

  In the third aspect of the invention, since the value obtained by inverting the value of at least one bit in the input N-bit data is used as a redundant bit value, for example, control is performed so that adjacent bits have different values. It is possible to suppress the appearance of a plurality of bits of the same code continuously.

  According to a fourth invention (invention 4), in the first invention, there is further provided variable clock generation means for generating a clock signal having a variable frequency for determining a bit rate of serial data output from the parallel / serial conversion means. It is characterized by that.

  In the fourth aspect of the invention, the bit rate of the serial data output from the parallel / serial converter can be changed by adjusting the variable clock generator, so that the frequency of each frequency component included in the radiation noise is appropriately set. The frequency band that can be changed and is not affected by the radiation noise matches the frequency band used for wireless communication, or the frequency band of each frequency component included in the radiation noise and the frequency band used for wireless communication Can be adjusted so that they do not overlap.

  According to a fifth aspect (invention 5), in the fourth aspect, the variable clock generation means determines the frequency of the clock signal to be output according to the coding rate of the coding means.

  Depending on the coding rate (number of bits before coding / number of bits after coding) of the coding means, the number of bits of the code that appears continuously after coding changes, and the frequency component included in the radiation noise changes. In the fifth invention, since the frequency of the clock signal to be output is determined according to the coding rate, a frequency band that is not affected by the radiation noise is used for wireless communication even when the coding rate is changed. The frequency band can be adjusted to match the frequency band, or the frequency of each frequency component included in the radiation noise can be adjusted so as not to overlap with the frequency band used for wireless communication.

  According to a sixth invention (invention 6), in the first invention, there is provided a clock regeneration means for generating a clock signal synchronized with parallel data outputted from the serial / parallel conversion means from the inputted serial data. Further, it is provided.

  In the sixth aspect of the invention, the clock recovery means provided on the receiving side for receiving the serial data generates a clock signal from the input serial data, so that the serial data is transmitted between the receiving side and the receiving side. There is no need to transmit a clock signal together with serial data. As a result, the clock signal does not appear on the transmission path, and it is possible to further reduce the high frequency components included in the radiation noise, thereby suppressing the adverse effect of the radiation noise.

  According to the present invention, the frequency interval of each frequency component in the frequency spectrum of radiation noise is widened, and a frequency band that is not affected by radiation noise is formed. Therefore, the frequency band that is not affected by radiation noise matches the frequency band used in wireless communication, or the frequency band of each frequency component included in the radiation noise and the frequency band used in wireless communication do not overlap. By adjusting in advance, the influence of radiation noise can be greatly reduced.

  One embodiment of the portable terminal device of the present invention will be described below with reference to FIGS.

  FIG. 1 is a block diagram illustrating a configuration of a main part of the mobile terminal device according to the embodiment. FIG. 2 is an electric circuit diagram showing a detailed configuration of a part of the portable terminal device shown in FIG. FIG. 3 is an electric circuit diagram showing a detailed configuration of a part of the portable terminal device shown in FIG. 4 to 6 are graphs each showing a specific example of a frequency spectrum of harmonics generated by an electric signal of serial data encoded inside the mobile terminal device shown in FIG.

  In this embodiment, it is assumed that the present invention is applied to a mobile terminal 100 having a wireless communication function and a camera for shooting, such as a mobile phone terminal. Referring to FIG. 1, the mobile terminal 100 includes a wireless unit 101, an audio processing unit 102, an image display unit 103, a terminal operation unit 104, a main control unit 105, a power generation unit 106, and a battery 107. A camera 108, an encoding unit 109, a parallel-serial conversion unit 110, a decoding unit 111, and a serial-parallel conversion unit 112.

  The radio unit 101 includes a modulator, a demodulator, a signal amplifier, an antenna, and the like (not shown). The radio unit 101 performs radio communication with a predetermined radio base station using radio waves, and is necessary for voice communication and data communication. Secure communication lines.

  The audio processing unit 102 includes a receiver, a speaker, a microphone, an audio amplifier, and the like (not shown), and has a function of performing audio input, audio output, and notification by a ringer.

  The image display unit 103 includes a planar display unit using liquid crystal or the like, and can display information such as an image on the screen as visible information.

  The terminal operation unit 104 includes a keypad for accepting an input operation from the user. The terminal operation unit 104 is used for an operation for the user to communicate with the outside, an operation for voice input / output, and an image data capturing operation. Instructions from the user regarding operations for displaying images and operations for displaying images are accepted.

  The power generation unit 106 includes a DC / DC converter, and generates a power supply voltage required by each circuit included in the mobile terminal 100 based on the power supplied from the battery 107.

  The camera 108 has a function of taking an image of an arbitrary subject as necessary, such as a two-dimensional CCD image sensor, and outputting digital data of a two-dimensional color image. Specifically, the camera 108 operates in accordance with a control signal output from the main control unit 105, and outputs a pixel clock signal SG1, a YUV data signal SG2, a horizontal synchronization signal HSYNC, and a vertical synchronization signal VSYNC. In this example, the YUV data signal SG2 is output as 8-bit parallel data. The pixel clock signal and the YUV data signal output from the camera 108 are input to the encoding unit 109, and the horizontal synchronization signal and the vertical synchronization signal output from the camera 108 are input to the main control unit 105.

  The encoding unit 109 encodes the YUV data signal SG2 sequentially input as 8-bit parallel data from the camera 108 in synchronization with the pixel clock signal SG1. Specifically, by adding redundant bits, encoded data having a different number of bits from the input parallel data is generated. This encoding is performed in order to prevent a specific code composed of a plurality of bits from appearing continuously.

  The parallel-serial conversion unit 110 converts the encoded YUV parallel data SG3 output from the encoding unit 109 into serial data SG4. The frequency of the clock signal that determines the bit rate of the serial data SG4 is variable, and is automatically controlled by the main control unit 105 to an appropriate frequency.

  The decoding unit 111 receives the encoded YUV serial data SG4 output from the parallel-serial conversion unit 110, and performs decoding processing. That is, the redundant bits added by the encoding unit 109 are removed to restore the data before encoding.

  The serial / parallel converter 112 receives the serial data SG5 after decoding output from the decoder 111, performs serial / parallel conversion, and outputs a YUV data signal SG6 as 8-bit parallel data.

  When the image data signal is transferred over a relatively long distance (for example, about several centimeters) on the circuit board of the portable terminal 100, the YUV signal appearing between the parallel-serial conversion unit 110 and the decoding unit 111 is used. Signal transfer is performed using the serial data SG4. Thereby, not only the number of signal lines is reduced, but also the influence of radiation noise can be reduced. That is, since the YUV data is encoded, it is difficult for the same code composed of a plurality of bits to appear continuously, and a frequency band that is not affected by radiation noise is formed as will be described later. By adjusting the frequency band not affected by the radiation noise so as to coincide with the frequency band used in the wireless communication, the influence of the radiation noise on the wireless communication can be suppressed.

  The main control unit 105 includes an arithmetic processing unit (CPU) (not shown), a storage device, and the like, and controls each circuit connected to the main control unit 105 according to an instruction input from the terminal operation unit 104. To do. In particular, when the operation of the wireless unit 101 and the operation of the camera 108 are performed simultaneously, the main control unit 105 outputs from the parallel-serial conversion unit 110 according to the frequency band used by the wireless unit 101 for wireless communication. The bit rate (transmission speed) of the serial data SG4 to be transmitted is controlled. Thereby, it is possible to prevent the influence of the radiation noise of the signal output from the camera 108 from appearing in the frequency band used for wireless communication.

  A specific configuration relating to the encoding unit 109 and the parallel-serial conversion unit 110 described above is shown in FIG. As shown in FIG. 2, in this example, the encoding unit 109 is configured by using 12 master-slave D-type flip-flops (D-FF) 201 to 212. The parallel-serial conversion unit 110 includes 12 master-slave D-type flip-flops (D-FFs) 213 to 224, 11 switches 230 provided at inputs of the D-FFs 213 to 223, A clock multiplication circuit 225 and a switch switching circuit 226 are included.

  First, the encoding unit 109 will be described. The YUV data signal SG2 output from the camera 108 is 8-bit parallel data, and the signal lines of each bit of the YUV data signal SG2 are YUV0, YUV1, YUV2, YUV3, YUV4, YUV5, YUV6, YUV7 in FIG. It is represented by

  The signal lines YUV0, YUV1, YUV2, YUV3, YUV4, YUV5, YUV6, YUV7 of each bit of the YUV data signal SG2 are D-FF201, D-FF202, D-FF203, D-FF204, D-FF206, D-, respectively. It is connected to the data input terminals of FF207, D-FF208, and D-FF209. The signal line YUV3 is also connected to the inverted data input terminal (input terminal with a circle in the figure) of the D-FF 205. Further, the signal line YUV7 is also connected to the inversion side data input terminal of the D-FF 210, the D-FF 211 data input terminal, and the inversion side data input terminal of the D-FF 212.

  Each of the D-FFs 201 to 212 outputs the data input to the data input terminal or the data input terminal on the inverting side at a timing synchronized with the falling of the level of the pixel clock signal SG1. The data input to the inverted data input terminal is output with the logic of 0/1 inverted.

  Therefore, for example, when data of “1, 1, 1, 1, 1, 1, 1, 1, 1” appears as 8-bit parallel data in the YUV data signal SG2, 12 bits output from the D-FFs 201 to 212. The parallel data becomes “1, 1, 1, 1, 0, 1, 1, 1, 1, 0, 1, 0”. That is, redundant bits are added, and 8-bit parallel data is converted into 12-bit encoded parallel data. Among the 12-bit parallel data output from the D-FFs 201 to 212, these are redundant bits to which the fifth bit, the tenth bit, the eleventh bit, and the twelfth bit are added, respectively. is there. Note that the number of redundant bits to be added can be increased or decreased as necessary.

  By adding such redundant bits, it is possible to prevent the same code from appearing continuously. In other words, as described above, data of “1, 1, 1, 1, 1, 1, 1, 1” in which the same value “1” continues as 8-bit parallel data appears in the YUV data signal SG2. Also, the 12-bit parallel data (SG3) output from the D-FFs 201 to 212 is “1, 1, 1, 1, 0, 1, 1, 1, 1, 0, 1, 0”. The consecutive occurrence of bits having the same value of “1” or “0” in adjacent positions is suppressed to a maximum of 4 bits.

  A signal (the least significant bit of SG3) output from the D-FF 201 of the encoding unit 109 is applied to the data input terminal of the D-FF 213 via the switch 230. Similarly, a signal output from the D-FF 202 is the switch 230. The signal output from D-FF 203 is applied to the data input terminal of D-FF 215 via switch 230, and the signal output from D-FF 204 is applied to switch 230. The signal output from the D-FF 205 is applied to the data input terminal of the D-FF 217 via the switch 230, and the signal output from the D-FF 206 is applied to the switch 230. Applied to the data input terminal of the D-FF 218 via the D-FF 207 and output from the D-FF 207 A signal applied to the data input terminal of the D-FF 219 via the switch 230 and output from the D-FF 208 is applied to a data input terminal of the D-FF 220 via the switch 230, and a signal output from the D-FF 209 is A signal applied to the data input terminal of the D-FF 221 via the switch 230 and output from the D-FF 210 is applied to a data input terminal of the D-FF 222 via the switch 230, and a signal output from the D-FF 211 is The signal is applied to the data input terminal of the D-FF 223 via the switch 230, and the signal output from the D-FF 212 is directly applied to the data input terminal of the D-FF 224.

  The switches 230 provided at the inputs of the D-FFs 213 to 223 select either one of the two input terminals according to the control signal output from the switch switching circuit 226, respectively, and the rear D-FFs (213 to 223). ) Connect to the data input terminal. One of the two input terminals provided in each switch 230 is connected to the output terminal of the preceding D-FF (214 to 224), and the output (SG3) of the D-FF (201 to 211) of the encoding unit 109 It is connected.

  The clock multiplication circuit 225 receives the pixel clock signal SG1 and multiplies the frequency of this signal to generate a serial data clock signal SCLK. The multiplication factor in the clock multiplication circuit 225 is determined by a control signal output from the main control unit 105. The frequency of the serial data clock signal SCLK determines the transmission speed (bit rate) of the serial data SG4. The main control unit 105 obtains the value of the control signal necessary for appropriately controlling the transmission speed of the serial data SG4 by calculation in advance and stores it in the internal memory. To the clock multiplier circuit 225 as a control signal.

  The D-FFs 213 to 224 take in signals applied to the respective data input terminals at the rising timing of the level of the serial data clock signal SCLK and output them at the falling timing of the level of the serial data clock signal SCLK.

  The switch switching circuit 226 generates a timing signal for switching each switch 230 in accordance with the control signal output from the main control unit 105. Each switch 230 selects the parallel data (SG3) output from the encoding unit 109 in the initial state. In this state, the D-FFs 213 to 224 take in the parallel data (SG3) at the rising timing of the serial data clock signal SCLK and output it at the falling timing of the serial data clock signal SCLK.

  Next, each switch 230 switches the selection state according to the signal output from the switch switching circuit 226. Thereby, the output terminal of D-FF (214-224) ahead of each switch 230 and the data input terminal of D-FF (213-223) behind are connected. In this state, the D-FFs 213 to 223 take in the data output from the preceding D-FFs (214 to 224) at the rising timing of the level of the serial data clock signal SCLK, and the level of the serial data clock signal SCLK rises. Output at the falling timing. By repeating such an operation, time-series data for each bit corresponding to 12-bit parallel data (SG3), that is, serial data SG4 appears at the output terminal of the D-FF 213.

  The parallel-serial conversion unit 110 can also perform parallel-serial conversion on only a part of the 12-bit parallel data output from the encoding unit 109 and output it as serial data SG4. That is, even if only a part of the four redundant bits added by the encoding unit 109 is used, the encoded serial data can be output. Actually, the main control unit 105 gives a predetermined control signal to the switch switching circuit 226 according to the required coding rate (number of bits after coding / number of bits before coding), whereby the switch switching circuit 226 is provided. The switch 230 to be switched is selected, and the parallel-serial conversion processing regarding unnecessary redundant bits is omitted.

  As described above, since parallel encoding is performed after the encoding unit 109 performs encoding, the serial data SG4 is encoded, and 5 bits or more of the same value continuously appear on the serial data SG4. There is nothing. Thereby, the frequency characteristic of the radiation noise generated by the serial data SG4 can be controlled. Details will be described later.

  On the other hand, a specific configuration regarding the above-described decoding unit 111 and serial / parallel conversion unit 112 is shown in FIG. As shown in FIG. 3, in this example, the decoding unit 111 includes 12 master-slave D-type flip-flops (D-FFs) 301 to 312, a clock extraction circuit 321, and a clock synchronization circuit 322. It is. The serial / parallel conversion unit 112 is configured by using eight master-slave D-type flip-flops (D-FFs) 313 to 320.

  First, the decoding unit 111 will be described. The decoding unit 111 performs a process for restoring the data encoded by the encoding unit 109 to the data before encoding. Therefore, the decoding unit 111 needs to perform processing corresponding to the coding rate (number of bits after coding / number of bits before coding) in the coding unit 109. For example, when 4 bits of redundant bits are added and 12 bits of encoded data is input as serial data SG4, 4 bits of redundant bits are removed to extract 8-bit data before encoding. It will be.

  The clock extraction circuit 321 generates a serial data clock signal SG8 necessary for receiving the serial data SG4 by detecting rising and falling of the level of the input serial data SG4. The twelve D-FFs 301 to 312 operate in synchronization with the timing of the serial data clock signal SG8 output from the clock extraction circuit 321, respectively.

  That is, the first D-FF 312 captures the serial data SG4 at the rising timing of the serial data clock signal SG8, and outputs the captured data at the falling timing of the serial data clock signal SG8. The D-FF 311 connected to the output terminal of the D-FF 312 takes in the data output from the D-FF 312 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing.

  Similarly, the D-FF 310 takes in the data output from the D-FF 311 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 309 takes in the data output from the D-FF 310 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 308 takes in the data output from the D-FF 309 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 307 takes in the data output from the D-FF 308 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 306 takes in the data output from the D-FF 307 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 305 takes in the data output from the D-FF 306 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 304 takes in the data output from the D-FF 305 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 303 takes in the data output from the D-FF 304 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 302 takes in the data output from the D-FF 303 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing. The D-FF 301 takes in the data output from the D-FF 302 at the rising timing of the serial data clock signal SG8 and outputs it at the falling timing.

  The clock synchronization circuit 322 receives the serial data clock signal SG8 output from the clock extraction circuit 321 and divides the frequency by a necessary division ratio to generate a pixel clock signal SG7. The frequency division ratio of the clock synchronization circuit 322 is determined by a control signal output from the main control unit 105. This pixel clock signal SG7 is a signal having the same frequency and timing as the serial data clock signal SCLK generated by the clock multiplication circuit 225 of the parallel-serial conversion unit 110 by multiplication.

  Further, according to the control signal output from the main control unit 105, the clock synchronization circuit 322 matches the output of the D-FF 304 with the inverted signal of the output of the D-FF 305 and the inverted signal of the output of the D-FF 309 and the output of the D-FF 310 The pixel clock signal SG7 is output in synchronization with this timing.

  In order to receive the transmitted serial data SG4 and restore the original data, it is necessary to grasp the timing of each bit of the serial data. In the decoding unit 111 shown in FIG. Generates a serial data clock signal SG8 representing the timing of each bit from the received serial data SG4, and the clock synchronization circuit 322 generates a pixel clock signal SG7 representing the timing of each byte of parallel data. It is not necessary to transmit the timing signal together with the serial data SG4 to the side.

  When a camera activation instruction is input from the terminal operation unit 104 by a user input operation, the main control unit 105 illustrated in FIG. 1 performs control as follows. That is, the main control unit 105 confirms the reception frequency (frequency used for communication) in the wireless unit 101 and serial data SG4 so that the frequency of the harmonic component of the serial data SG4 does not overlap with the reception frequency of the wireless unit 101. The transmission speed and the coding rate are determined, and the encoding unit 109, the parallel / serial conversion unit 110, the decoding unit 111, and the serial / parallel conversion unit 112 are controlled according to the result.

  Since the relationship between the reception frequency and the appropriate transmission rate and coding rate can be known by calculation or the like, the result of the calculation performed in advance is stored in the main control unit 105. Then, the data stored using the reception frequency as a parameter is read, and an appropriate transmission rate and coding rate are determined.

  A specific example regarding the relationship between the reception frequency and the appropriate transmission rate and coding rate will be described below. In each example shown in FIGS. 4 to 6, it is assumed that the frequency of the pixel clock representing the timing of each byte of parallel data is 24 MHz. FIG. 4 shows a distribution state in the frequency domain of each harmonic component included in the serial data when the coding rate is 10/8 and the serial data transmission rate is 240 MHz. FIG. 5 shows a distribution state in the frequency domain of each harmonic component included in the serial data when the encoding rate is 11/8 and the serial data transmission rate is 264 MHz. FIG. 6 shows the encoding rate. Represents the distribution state in the frequency domain of each harmonic component included in the serial data when the transmission speed of serial data is 288 MHz.

  For each harmonic component as shown in FIGS. 4 to 6, on the serial data, a code whose value changes every bit, a code in which two adjacent bits have the same value in succession, and an adjacent 3 Harmonics of various fundamental frequencies generated by a code having consecutive bits having the same value, a code having consecutive four bits having the same value, and a code having consecutive five bits having the same value. Are shown in FIGS. 4, 5 and 6 (a) to (e). 4, 5, and 6, (a) shows harmonics of the fundamental frequency generated by a code whose value changes for each bit, and (b) shows two adjacent bits having the same value continuously. The harmonics of the fundamental frequency generated by a certain code, (c) is the harmonics of the fundamental frequency generated by a code in which 3 adjacent bits have the same value, and (d) is the consecutive 4 bits of adjacent. The harmonics of the fundamental frequency generated by the code having the same value are shown, and (e) shows the harmonics of the fundamental frequency generated by the code of the adjacent 5 bits having the same value.

  For example, when the reception frequency is 1680 MHz, in the graph of FIG. 4, harmonic components appear at the same frequency. Therefore, when the control condition is applied with a coding rate of 10/8 and a serial data transmission speed of 240 MHz, serial data The effect of radiation noise of higher harmonics appears on the communication frequency. Therefore, in such a case, other control conditions are applied so that the reception frequency and the frequency of the harmonics of the radiation noise of the serial data do not overlap. For example, in the case of applying a control condition of an encoding rate of 11/8 and a serial data transmission rate of 264 MHz, the frequency at which each harmonic component appears shifts from the reception frequency of 1680 MHz as shown in FIG. Therefore, even when the camera 108 is used, communication can be performed without being affected by radiation noise. Similarly, when a control condition of a coding rate of 12/8 and serial data transmission rate of 288 MHz is applied, as shown in FIG. 6, the frequency at which each harmonic component appears shifts from 1680 MHz, which is the reception frequency. Therefore, even when the camera 108 is used, communication can be performed without being affected by radiation noise.

  In addition, when transmitting serial data without encoding, it is highly possible that codes of various bit lengths continuously appear on the serial data, so as with the frequency component included in the random signal, The serial data includes harmonic components of various frequencies, and the frequency interval between adjacent harmonic components is narrowed. Therefore, even if the serial data transmission rate is changed, the frequency of the radiation noise and the reception frequency cannot be shifted.

  In this embodiment, it is assumed that the main control unit 105 automatically adjusts the coding rate and serial data transmission speed in accordance with the reception frequency. However, according to the input operation from the user, the coding rate and The serial data transmission speed may be manually changed.

  The serial data SG4 transmitted between the parallel / serial conversion unit 110 and the decoding unit 111 is preferably transmitted as a balanced signal using a differential circuit and a pair of signal lines. By transmitting as a balanced signal, transmission with low power becomes possible, and furthermore, radiation noise caused by standing waves and harmonics of the serial data SG4 is canceled and reduced between the lines. It also helps prevent deterioration.

  As described above, by applying the present invention, it is possible to prevent the frequency of radiation noise generated by a signal output from the camera from overlapping with the frequency used for wireless communication. Therefore, by applying the present invention to a mobile phone terminal with a camera or a portable information terminal having a camera and a wireless communication function, it is possible to suppress deterioration in wireless communication performance even when the camera is used.

It is a block diagram which shows the structure of the principal part of the portable terminal device in embodiment. It is an electric circuit diagram which shows the detailed structure of a part of portable terminal device shown in FIG. It is an electric circuit diagram which shows the detailed structure of a part of portable terminal device shown in FIG. It is a graph which shows the specific example of the frequency spectrum of the harmonic generated by the electric signal of the serial data encoded inside the portable terminal device shown in FIG. It is a graph which shows the specific example of the frequency spectrum of the harmonic generated by the electric signal of the serial data encoded inside the portable terminal device shown in FIG. It is a graph which shows the specific example of the frequency spectrum of the harmonic generated by the electric signal of the serial data encoded inside the portable terminal device shown in FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 100 Portable terminal 101 Radio | wireless part 102 Audio | voice processing part 103 Image display part 104 Terminal operation part 105 Main control part 106 Power supply generation part 107 Battery 108 Camera 109 Encoding part 110 Parallel serial conversion part 111 Decoding part 112 Serial parallel conversion part 201-212 D Type flip-flop (D-FF)
213-224 D-type flip-flop (D-FF)
225 Clock multiplication circuit 226 Switch switching circuit 230 Switch 301 to 312 D-type flip-flop (D-FF)
313 to 320 D-type flip-flop (D-FF)
321 Clock extraction circuit 322 Clock synchronization circuit

Claims (6)

A mobile terminal device having a wireless communication function for communicating using radio waves and a camera capable of shooting an arbitrary subject,
Encoding means for encoding parallel format image data output in parallel every N bits from the camera so as to suppress continuous output of the same code;
Parallel / serial conversion means for converting encoded parallel image data output from the encoding means into serial data;
Decoding processing means for receiving serial data output from the parallel / serial conversion means and decoding the image data to perform decoding processing;
Serial / parallel conversion means for receiving serial data output from the parallel / serial conversion means and converting the serial data into parallel data;
A portable terminal device characterized by comprising:   2. The portable terminal device according to claim 1, wherein the encoding unit adds at least one redundant bit before or after the parallel-format image data input every N bits to add more bits than N bits. A portable terminal device that generates a large number of M-bit encoded parallel data.   3. The portable terminal device according to claim 2, wherein the encoding means outputs a result obtained by inverting the value of at least one bit in the input N-bit data as the value of the redundant bit to be added. Mobile terminal device.   2. The portable terminal device according to claim 1, further comprising variable clock generation means for generating a clock signal having a variable frequency for determining a bit rate of serial data output from the parallel / serial conversion means. Mobile terminal device.   5. The portable terminal device according to claim 4, wherein the variable clock generation unit determines a frequency of a clock signal to be output according to a coding rate of the coding unit.   2. The portable terminal device according to claim 1, further comprising clock recovery means for generating a clock signal synchronized with parallel data output from the serial / parallel conversion means from input serial data. A portable terminal device.

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