JP2008172692A - Mobile terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a mobile terminal which suppresses the problem of an EMI or an EMS between an image data signal and an antenna accompanied by an improvement in the image quality of a mobile phone. <P>SOLUTION: A self-synchronous code encoder 21 encodes image data 21a into a self-synchronous code with a clock existing therein and outputs code data 21b. An ATT 22 adjusts an amplitude of the code data 21b. An LPF 23 attenuates a radio frequency band of a radio unit, outputs a smooth waveform signal and sends it to a wire harness 10. Thus, measures to cope with EMI from the wire harness 10 to the radio unit are taken. An LPF 25 receives a signal of the LPF 23a passed through the wire harness 10 and attenuates the radio frequency band of the radio unit. Thus, measures to cope with EMS from the radio unit to the wire harness 10 are taken. The original image data 21a are decoded by a shaping circuit 26 and a self-synchronous code decoder 27. If a decoding error occurs, an output amplitude of the ATT 22 is enlarged. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to a portable terminal such as a folding cellular phone, and more particularly to transmission of image data between upper and lower casings.

  There is an LSI used for image data transmission between the upper and lower housings of a mobile phone (see Non-Patent Document 1, for example). The mobile phone described here uses the LVDS (Low Voltage Differential Signal) method for transmitting and receiving image data between the upper and lower housings, and the external synchronous high-speed serial transfer using data and clock. Is used to reduce the number of signals and achieve low EMI. The harness for transmitting and receiving image data and the like is wired between the upper and lower housings through the hinge portion.

  The LVDS defines the physical level, and the speed is increased by setting the signal amplitude to a low voltage of several hundred mV. Further, low EMI can be realized while suppressing radiation noise to the outside by low voltage and differential cancellation. On the other hand, since it is a low voltage, it is vulnerable to incoming noise from outside, but it can cope with EMS from outside by differential cancellation. If a pair of wires is used for the harness wiring of the differential signal, it is more resistant to EMI and EMS.

  On the other hand, the external synchronization method defines a data and clock transmission method, in which data and a clock are transmitted in parallel through two signal lines, and data is reproduced by the clock on the receiving side.

  Although not described in Non-Patent Document 1, an antenna for mobile communication of a mobile phone is often built in the vicinity of a hinge portion. This is for the purpose of shortening the wiring of the radio frequency signal between the radio unit and the antenna by arranging both the radio unit and the antenna on the lower housing side. Therefore, the antenna is arranged in the vicinity of the hinge portion so that the antenna is not hidden while the user holds the lower casing. Therefore, the harness and the antenna are arranged close to each other, and EMI from the harness to the antenna tends to be a problem. Also, EMS from the antenna to the harness image data signal tends to be a problem. Moreover, a pair wiring by a flexible substrate may be used as a harness instead of a twisted pair wire, and the EMI / EMS performance may be deteriorated.

  In recent years, the display unit and camera unit of mobile phones have become increasingly difficult to reduce the EMI of the LVDS itself as the image data amount per unit time increases as the resolution and color tone increase in order to achieve higher image quality. It has become. Therefore, measures such as shielding the harness are required.

  FIG. 4 is a timing chart of conventional external synchronization data and clocks. For both data and clock, the LVDS uses a low voltage amplitude to achieve low EMI. However, although the voltage is low, the rising and falling edges of the waveform are steep and include harmonic components, which affects the radio frequency of the antenna as the data becomes faster.

It is also conceivable to smooth out the externally synchronized data and the steep waveform of the clock to reduce harmonic components and reduce EMI. However, in the case of the external synchronization type of data and clock, as the data and clock become faster, if the waveform is smoothed, the deviation between the data and the clock increases, resulting in a data error on the receiving side.
[Search November 14, 2006], Internet <URL: http://www.semicon.toshiba.co.jp/product/assp/selection/topics/1173947_1928.html>

  As mobile phones have higher image quality, problems such as EMI and EMS between the image data signal and the antenna tend to occur. The present invention originally uses a self-synchronous code method, which is a data and clock transmission method used in LAN, optical communication, etc., for transmission / reception of image data between the upper and lower housings of the mobile terminal, and is unique to the mobile terminal. An object of the present invention is to provide a portable terminal in which problems of EMI and EMS between the image data signal and the antenna are suppressed.

  In order to achieve the above object, a mobile terminal of the present invention encodes a radio unit for transmitting and receiving radio signals, an antenna connected to the radio unit, and a self-synchronous encoding of a data signal in a clock. A self-synchronous code encoder that outputs data; a first filter that attenuates a frequency band of the radio unit with respect to the encoded data; a line connected to the first filter output; and the other of the lines A second filter connected to the end for attenuating the frequency band of the radio unit; a shaping circuit for shaping the second filter output into a binary signal; and a self for decoding the data signal from the shaping circuit output And a synchronization code decoder.

  According to the present invention, it is possible to suppress problems of EMI and EMS between an image data signal unique to a mobile terminal and an antenna.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a structural diagram of a mobile terminal according to an embodiment of the present invention, and shows “A: front view”, “B: harness connection”, and “C: side view”. The portable terminal 100 has a foldable structure, and an upper housing 1 and a lower housing 2 are engaged with a hinge 3 so as to be freely rotatable. As shown in “A: Front view”, an audio receiver 4, a display unit 5, and the like are arranged in the upper housing 1. A camera 6 and the like are disposed on the back side of the upper housing 1. An operation key 7 and the like are disposed on the lower housing 2.

  As shown in “B: harness connection”, the upper substrate 8 is disposed inside the upper housing 1, and the main substrate 9 is disposed inside the lower housing 2. The upper substrate 8 and the main substrate 9 are electrically connected by the wire harness 10. The wire harness 10 includes a connector 11, a connector 12, a wire 13 and the like. The wire harness 10 is wired through the inside of the hinge 3. High-speed image data transmitted from the main board 9 to the display unit 5, high-speed camera data transmitted from the camera 6 to the main board 9, and the like are transmitted to the wire harness 10.

  As shown in “C: side view”, the main board 9 is disposed inside the lower housing 2 and the connector 12 of the wire harness 10 is connected thereto. A wireless unit 16 is mounted on the main board 9. An antenna 14 is mounted near the hinge 3 and connected to the wireless unit 15. The wireless unit 15 and the antenna 14 are disposed in the vicinity of the wire harness 10.

Since high-speed image data and camera data flow through the wire harness 10, there is a possibility of generating radiation noise, and external EMI countermeasures are necessary. In particular, since the wireless unit 16 and the antenna 14 are disposed in the vicinity of the wire harness 10 (FIG. 1), it is necessary to prevent the antenna 14 during wireless reception from affecting the weak radio signal received from the outside. There is.
Further, since high-speed image data and camera data of the wire harness 10 use low-amplitude signals for speeding up, there is a risk of being affected by external noise, and external EMI countermeasures are necessary. In particular, at the time of wireless transmission, high power high frequency output is performed from the wireless unit 15 to the antenna 14. Therefore, there is a risk of becoming a noise source to the wire harness 10. Therefore, it is necessary to take measures against noise between the wireless part and the wire harness.

FIG. 2 is a block diagram of relevant portions of the mobile terminal according to the embodiment of the present invention.
FIG. 3 is a time chart of the self-synchronization method of the mobile terminal according to the embodiment of the present invention.
The operation will be described below with reference to FIGS. In the portable terminal 100, an antenna 14, a wireless unit 15, a self-synchronizing code encoder 21, an ATT 22 (attenuator), an LPF 23 (low-pass filter), a connector 12, a control unit 24, and the like are mounted on the lower housing 2 side. On the upper housing 1 side, a connector 11, an LPF 25, a shaping circuit 26, a self-synchronous code decoder 27, a display unit 5, an error detection unit 28, and the like are mounted. The lower housing 2 and the upper housing 1 are connected by a wire harness 10 (track).

  The image data 21 a input to the self-synchronous code encoder 21 is various image data displayed on the display unit 28. The self-synchronizing code encoder 21 encodes the image data 21a into a self-synchronizing code and outputs code data 21b. The self-synchronous code is a method that can be transmitted through one signal line with clock information included in the data, and is a method that is contrasted with the external synchronous method.

  The self-synchronous code is a well-known technique, and is outlined in, for example, [searched on November 14, 2006] and the Internet <URL: http://miyasan.serio.jp/series3/denso062.html>. Yes. The self-synchronous code is a system in which data and a clock are included in one signal, such as Manchester code (bi-phase code), 4B / 5B code, and the like.

  As shown in FIG. 3A, the Manchester code is a simple encoding that simply converts “1” of the original data (image data 21a) into “01” and converts the original data “0” into “10”. (Encoding). As a result, a change point always occurs in the data of the self-synchronization code 21b. On the receiving side, by detecting the change point, the clock is reproduced and the original data is decoded.

  As shown in FIG. 3B, the 4B / 5B code is a simple encoding that encodes original data (image data 21a) into nibbles (4 bits) and converts 4 bits into 5 bits. is there. At this time, for example, the encoding always includes a change point so as to convert the original data “0000” into “11110”. On the receiving side, by detecting the change point, the clock is regenerated and the original data is decoded. Equivalent to 4B / 5B, such as 8B / 10B. In both the Manchester code and the 4B / 5B code, a preamble having a large number of clock components may be transmitted prior to data transmission in order to increase the accuracy of clock recovery on the receiving side. The internal details of the self-synchronizing code encoder 21 are well known and will not be described.

  The ATT 22 adjusts the amplitude of the input code data 21b. Since the rise and fall are steep and include harmonics with the output of the ATT 22, the LPF 23 attenuates the radio frequency band of the radio unit with respect to the output of the ATT 22, as shown in FIGS. 3 (a) and 3 (b). A smooth waveform signal such as the LPF 23 a is output and sent to the wire harness 10.

  In addition, as a physical level system of the signal of the LPF 23a, a single signal may be transmitted by two twisted pair lines by a differential system such as LVDS, or may be transmitted by a single line that is not a differential system.

  In the Manchester code, the frequency of the self-synchronization code 21b is a maximum of twice that of the image data 21a. Further, in the 4B / 5B code, the frequency of the self-synchronization code 21b is five times the maximum of the image data 21a. Since the radio frequency is sufficiently higher than the frequency of the image data 21a, it is easy to make the influence of the attenuation of the frequency component of the self-synchronization code 21b slight even if the radio frequency band is attenuated. Accordingly, the radio frequency band can be sufficiently attenuated, and the radiation noise to the radio unit due to the signal of the LPF 23a passing through the wire harness 10 can be greatly reduced.

  On the upper housing 1 side, the LPF 25 receives the signal of the LPF 23 a that has passed through the wire harness 10. The LPF 25 attenuates the radio frequency band of the radio unit. Thereby, the influence on the wire harness 10 of the high power high frequency output of the radio | wireless part at the time of radio | wireless transmission can be fully attenuated.

  The shaping circuit 26 binarizes the signal of the LPF 23a with a rounded waveform. This binarization is binarized using the integrated average value of the LPF 23a signal as a threshold. In both the Manchester code and the 4B / 5B code, the ratio of “1” and “0” of the self-synchronization code 21b is made uniform, so that there is little DC component and binarization can be performed easily. Then, the shaping circuit 26 outputs a signal equivalent to the self-synchronization code 21b shown in FIGS.

  The self-synchronous code decoder 27 reproduces the clock from the binarized data equivalent to the self-synchronous code 21b by detecting the change point, and outputs the same image data 27a as the original image data 21a. The internal details of the shaping circuit 26 and the self-synchronous code decoder 27 are well known and will not be described in detail. The display unit 5 displays the decoded image data 27a.

  The error detection unit 28 checks the decoding error of the self-synchronous code decoder 27. The error detection method may be a checksum, CRC, or other known techniques. If an error is detected, error information 28a is transmitted to the control unit 24. When receiving the error information 28a, the control unit 24 increases the amplitude of the ATT 22 so that no error occurs. Further, the amplitude of the ATT 22 is reduced within a range in which a self-synchronous transmission error does not occur. This makes it possible to optimize the transmission quality of the self-synchronization method and the EMI and EMS performance with the radio unit.

  Although not shown in the figure, the same applies to the portion that transmits the camera data of the camera 6 on the upper housing 1 side to the lower housing 2 side. Further, the present invention can be applied not only to image relationships such as image data and camera data, but also to devices including a high-speed digital data transmission unit.

  Further, although the antenna is disposed in the lower housing, EMI and EMS with the image data harness can be improved even when the antenna is disposed in the upper housing.

  In addition, although a plurality of cases have been described, even a single case portable terminal has a large interference between the antenna and the harness in the case of a small size, so it may be applied to a single case portable terminal. Good.

  The signal (image data 21a) output from the self-synchronous code encoder 21 in FIG. 2 includes the reception frequency of the reception circuit in the wireless unit 15, and reaches the receiver through the path of the ATT 22, LPF 23, wire 13 and antenna 14. Then, it interferes with a receiver designed to receive even a weak signal and degrades reception performance. Therefore, it is effective for the LPF 23 to attenuate the reception frequency particularly greatly.

  When the transmission circuit in the wireless unit 15 in FIG. 2 performs a transmission operation, when the signal reaches the shaping circuit 26 through the path of the antenna 14, the wire 13, and the LPF 25, transmission is generally high power. It becomes noise for the LPF 23 a) and impedes the output of the shaping circuit 26. Therefore, it is effective for the LPF 24 to attenuate the transmission frequency particularly greatly.

  Further, the mobile terminal can be applied to a device including an antenna and a high-speed digital data transmission unit such as a mobile phone, a PDA, and a PHS.

  According to the embodiment of the present invention, the self-synchronous code is applied to a high-speed data transmission unit (such as image data) of a mobile terminal, focusing on the fact that decoding is possible even if the waveform of the transmission path is considerably rounded. It is possible to attenuate the radio frequency band and reduce the mutual influence between the high-speed data transmission unit and the radio unit. Therefore, noise generated by a high-speed digital data transmission unit such as image data can be greatly reduced, and the influence on the radio unit can be reduced. Moreover, the influence on the high-speed digital data transmission part by the high output radio signal from a radio | wireless part can be reduced. As a result, it is possible to cope with an increase in the speed of the data transmission unit such as high image quality.

1 is a structural diagram of a mobile terminal according to an embodiment of the present invention. The block diagram of the portable terminal which concerns on the Example of this invention. The time chart of the Manchester code | cord | chord of the portable terminal which concerns on the Example of this invention. The time chart of the LVDS of the conventional portable terminal.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Upper housing | casing 2 Lower housing | casing 3 Hinge 4 Audio | voice receiver 5 Display part 6 Camera 7 Operation key 8 Upper board 9 Main board 10 Wire harness 11, 12 Connector 13 Wire 14 Antenna 15 Wireless unit 21 Self-synchronous code encoder 22 ATT
23 LPF
24 Control unit 25 LPF
26 shaping circuit 27 self-synchronous code decoder 28 error detection unit 100 portable terminal

Claims (5)

A radio unit for transmitting and receiving radio signals; and
An antenna connected to the radio unit;
A self-synchronous code encoder that encodes a data signal and self-synchronously encodes the clock signal to output encoded data;
A first filter for attenuating the frequency band of the radio unit with respect to the encoded data;
A line connected to the first filter output;
A second filter connected to the other end of the line to attenuate the frequency band of the radio unit;
A shaping circuit for shaping the second filter output into a binary signal;
A portable terminal comprising: a self-synchronous code decoder for decoding the data signal from the shaping circuit output. Furthermore,
A plurality of freely engaging housings;
Engaging means for connecting between the housings,
The line is wired between the plurality of cases through the engagement means,
The mobile terminal according to claim 1, wherein the antenna is disposed in the vicinity of the engaging means.   The mobile terminal according to claim 1, wherein the data signal is image data. A radio unit for transmitting and receiving radio signals; and
An antenna connected to the radio unit;
A self-synchronous code encoder that encodes a data signal and self-synchronously encodes the clock signal to output encoded data;
Amplitude adjusting means for adjusting the amplitude of the encoded data;
A first filter for attenuating the frequency band of the radio unit with respect to the output of the amplitude adjusting means;
A line connected to the first filter output;
A second filter connected to the other end of the line to attenuate the frequency band of the radio unit;
A shaping circuit for shaping the second filter output into a binary signal;
A self-synchronizing code decoder for decoding the data signal from the shaping circuit output;
Error detection means for detecting an error in the decoded data signal;
A portable terminal comprising: control means for changing the amplitude of the amplitude adjusting means when the error is detected.   The first filter has a large attenuation in the reception frequency band of the radio unit, and the second filter has a large attenuation in the transmission frequency band of the radio unit. The mobile terminal according to item 1.

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