JP2010081344A - Mobile terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a small-sized mobile terminal capable of easily detecting the defect of a coaxial cable. <P>SOLUTION: A mobile terminal includes: a casing 1 comprising a battery 112; a plurality of coaxial cables 115, 116 connected in common to the battery 112; and a casing 2 housing therein a camera 105 and a display section 106. The camera 105 and the display section 106 are separately connected to the battery 112 via the coaxial cables 115, 116. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a mobile terminal including a plurality of casings, and more particularly to a mobile terminal in which a power supply line between the casings is configured by a coaxial cable.

  Patent Document 1 describes a mobile phone having a first housing part and a second housing part. A negative voltage generation circuit, a transmission circuit, an amplifier circuit, and a superimposing circuit are accommodated in the first casing. Various circuits such as an infrared communication circuit and an LCD (Liquid Crystal Display) circuit are accommodated in the second casing.

The negative voltage generated by the negative voltage generation circuit is supplied to the amplifier circuit and the superposition circuit. The amplifier circuit uses the negative voltage from the negative voltage generation circuit as an operating voltage, and amplifies the transmission radio signal from the transmission circuit. The superimposing circuit superimposes the negative voltage from the negative voltage generating circuit on the transmission radio signal amplified by the amplifier circuit, and outputs a DC superimposed transmission radio signal. The DC superimposed transmission radio wave signal is supplied to various circuits of the second housing part via a coaxial cable. Each of the various circuits extracts a negative voltage from the DC superimposed transmission radio signal supplied via the coaxial cable, and uses this negative voltage as an operating voltage.
JP 2004-274934 A

  In the mobile phone described in Patent Document 1, since the various circuits of the second housing portion are commonly connected to one coaxial cable, if the current consumption of the various circuits is large, the allowable current capacity (rated It is necessary to use a coaxial cable with a large current. When the allowable current capacity of the coaxial cable is increased, the outer diameter of the cable is increased accordingly. For this reason, if a coaxial cable having a sufficient allowable current capacity is used, a space occupied by the coaxial cable becomes large. This becomes an impediment to downsizing of the mobile phone.

  If power is supplied to various circuits using a plurality of coaxial cables connected in parallel, the allowable current capacity of each coaxial cable can be reduced, and the space occupied by each coaxial cable is one. It becomes smaller than the occupied space when the coaxial cable is used. However, this case has the following problems.

  Since various circuits operate even if one of the multiple coaxial cables connected in parallel is broken, it is difficult to detect the breakage of the coaxial cable, and the broken coaxial cable It is also difficult to specify. For this reason, for example, when there is a connection failure of the coaxial cable at the time of manufacture, the failure cannot be detected by the operation check in the inspection process, and a defective product may be shipped. Further, in the inspection of the product returned from the user due to the poor connection of the coaxial cable, it is necessary to inspect each part of the mobile phone in order to identify the defective portion, which is troublesome.

  In order to reduce the occupied space, when the number of coaxial cables connected in parallel is set to the minimum necessary number corresponding to the current consumption of various circuits, disconnection occurred in one of the coaxial cables. In this case, power is supplied to various circuits by the remaining coaxial cable, and as a result, the amount of current flowing per coaxial cable exceeds the rated current value. For this reason, the problem that the coaxial cable generates heat occurs.

  It should be noted that the above heat generation problem can be solved by increasing the number of coaxial cables connected in parallel. However, in this case, the occupied space by the coaxial cable increases as the number of the coaxial cables is increased.

  An object of the present invention is to solve the above-described problems and provide a small portable terminal that can easily detect a defect of a coaxial cable.

In order to achieve the above object, the mobile terminal of the present invention
A first housing portion provided with a DC power supply;
A plurality of coaxial cables commonly connected to the DC power source;
And at least one second housing portion in which a plurality of functional portions each providing different functions are accommodated,
The plurality of functional units are separately connected to the DC power supply via different coaxial cables among the plurality of coaxial cables.

  According to the present invention, since the plurality of functional units are connected to the DC power supply via different coaxial cables, if a disconnection occurs in any of the coaxial cables, the function connected to the coaxial cable in which the disconnection has occurred. Part does not work. Therefore, when the function unit does not operate by the operation check, it is possible to estimate the disconnection of the coaxial cable connected to the function unit as the cause of the failure. In this way, it is possible to easily confirm the cutting of the coaxial cable.

  In addition, a coaxial cable having an optimum allowable current capacity can be provided for each functional unit. As a result, the space occupied by the coaxial cable is larger than that in the case where power is supplied to each functional unit using a single coaxial cable. Can be small. Thereby, size reduction of a portable terminal can be achieved.

  Next, embodiments of the present invention will be described with reference to the drawings.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of a mobile terminal according to the first embodiment of the present invention. This portable terminal has two casing portions 1 and 2 and two coaxial cables 115 and 116.

  The housing unit 1 accommodates a power supply IC (Integrated Circuit) 101 and a control unit (CPU: Central Processing Unit) 102 for controlling the operation of the mobile terminal. The casing unit 1 is equipped with a battery 112 that is a DC power source.

  The power supply IC 101 has a three-terminal structure including a positive terminal, a negative terminal, and an output terminal. The positive terminal is connected to a power line to which the positive terminal of the battery 112 is connected, and the negative terminal is connected to the negative terminal of the battery 112. Connected to a ground (GND) line. The control unit 102 is connected between the output terminal of the power supply IC 101 and the ground line. The current consumption of the power supply IC is, for example, 200 mA.

  Each of the coaxial cables 115 and 116 includes an inner conductor and an outer conductor that covers the periphery of the coaxial cable via an insulator. The outer periphery of the outer conductor is covered with an insulating member. One end of the inner conductor of each of the coaxial cables 115 and 116 is commonly connected to the power supply line of the housing unit 1. One end of the outer conductor of each of the coaxial cables 115 and 116 is commonly connected to the ground line of the casing unit 1, and the other end of the outer conductor is commonly connected to the ground (GND) line of the casing unit 2. . The allowable current of each of the coaxial cables 115 and 116 is, for example, 200 mA.

  The housing unit 2 accommodates power supply ICs 103 and 104, a camera 105, and a display unit 106. The power supply ICs 103 and 104 also have the above three-terminal structure. The positive terminal of the power supply IC 103 is connected to the other end of the inner conductor of the coaxial cable 115, and the positive terminal of the power supply IC 104 is connected to the other end of the inner conductor of the coaxial cable 116. The negative terminals of the power supply ICs 103 and 104 are commonly connected to the ground (GND) line of the housing unit 2.

  The camera 105 is connected between the output terminal of the power supply IC 103 and the ground line of the housing unit 2. The display unit 106 is connected between the output terminal of the power supply IC 104 and the ground line of the housing unit 2. The current consumption of each of the power supply ICs 103 and 104 is, for example, 200 mA.

  Although not shown in FIG. 1, the portable terminal has an operation unit in which a plurality of operation keys are arranged, a storage unit in which programs and data are stored, and the control unit 102 is connected to the operation unit from the operation unit. An instruction signal based on the input operation (pressing an operation key) is received, and the operation of each unit (including the camera 105 and the display unit 106) of the portable terminal is controlled.

  Next, the operation of the mobile terminal of this embodiment will be described.

  The power supply to the CPU 102 accommodated in the housing unit 1 is performed by the power supply IC 101 connected to the battery 112. The power supply to the camera 105 accommodated in the housing unit 2 is performed by the power supply IC 103 connected to the battery 112 via the coaxial cable 115. The power supply to the display unit 106 accommodated in the housing unit 2 is performed by a power supply IC 104 connected to the battery 112 via the coaxial cable 116.

  When the coaxial cable 115 is disconnected, the power supply to the camera 105 by the power supply IC 103 is stopped. For this reason, even if the operator performs an input operation for activating the camera 105 on the operation unit, the camera 105 is not activated. Thus, when the camera 105 stops operating, the operator can estimate the disconnection of the coaxial cable 115 as one of the causes of the failure.

  When the coaxial cable 116 is disconnected, power supply to the display unit 106 by the power supply IC 104 is stopped, so that the display unit 106 does not operate even if an input operation for displaying information is performed. Therefore, the operator can estimate the disconnection of the coaxial cable 116 as one of the causes of the failure.

  Further, in the mobile terminal of the present embodiment, even when the coaxial cable is short-circuited, the functional unit that receives power supply from another coaxial cable operates. Thus, when the coaxial cable is short-circuited, only a part of the functions are stopped.

(Second Embodiment)
FIG. 2 is a block diagram showing a configuration of a mobile terminal according to the second embodiment of the present invention. This portable terminal has two casing portions 1 and 2 and three coaxial cables 315, 316, and 317.

  The casing unit 1 is basically the same as that shown in FIG. 1, but the connection form to the coaxial cables 315, 316 and 317 is different.

  One end of the inner conductor of each of the coaxial cables 315, 316, and 317 is connected in common to the power supply line of the housing unit 1. A fuse 318 is inserted in a line connecting the coaxial cable 315 and the power supply line. A fuse 319 is inserted in a line connecting the coaxial cable 316 and the power supply line. A fuse 320 is inserted in a line connecting the coaxial cable 317 and the power supply line. One end of the outer conductor of each of the coaxial cables 315, 316, and 317 is connected in common to the ground (GND) line of the housing portion 1, and the other end of the outer conductor is common to the ground (GND) line of the housing portion 2. It is connected to the. Each allowable current of the coaxial cables 315, 316, and 317 is, for example, 200 mA.

  The housing unit 2 houses power supply ICs 303 and 304, an infrared communication unit 305, a camera 306, a display unit 307, and a camera light 308. The power supply IC 304 includes power supply units 401 and 402. Each of the power supply IC 303 and the power supply units 401 and 402 has a three-terminal structure.

  The positive terminal of the power supply IC 303 is connected to the other end of the inner conductor of the coaxial cable 315. The positive terminal of the power supply unit 401 is connected to the other end of the inner conductor of the coaxial cable 316. The positive terminal of the power supply unit 402 is connected to the other end of the inner conductor of the coaxial cable 317. The negative terminals of the power supply IC 303 and the power supply units 401 and 402 are commonly connected to the ground line of the housing unit 2. The current consumption of the power supply IC 303 and the power supply unit 401 is, for example, 200 mA. The current consumption of the power supply unit 402 is, for example, 150 mA.

  The infrared communication unit 305 is connected between the output terminal of the power supply IC 303 and the ground line of the housing unit 2. The camera 305 is connected between the output terminal of the power supply unit 401 and the ground line of the housing unit 2. The display unit 307 is connected between the output terminal of the power supply unit 402 and the ground line of the housing unit 2. The camera light is connected between the other end of the inner conductor of the coaxial cable 317 and the ground line of the housing unit 2.

  Although not shown in FIG. 2, the mobile terminal has an operation unit in which a plurality of operation keys are arranged, a storage unit in which programs and data are stored, and the control unit 102 is connected to the operation unit. An instruction signal based on the input operation (pressing the operation key) is received, and the operation of each unit (including the infrared communication unit 305, the camera 306, the display unit 307, and the camera light 308) of the portable terminal is controlled.

  Next, the operation of the mobile terminal of this embodiment will be described.

  Power supply to the control unit 102 accommodated in the housing unit 1 is performed by a power supply IC 101 connected to the battery 112.

  In the housing unit 2, the power supply to the infrared communication unit 305 is performed by a power supply IC 303 connected to the battery 112 via the coaxial cable 315. The power supply to the camera 306 is performed by the power supply unit 401 connected to the battery 112 via the coaxial cable 316. The power supply to the display unit 307 is performed by the power supply unit 402 connected to the battery 112 via the coaxial cable 317. Power is supplied to the camera light 308 from the battery 112 via the coaxial cable 317.

  When the coaxial cable 315 is disconnected, the power supply to the infrared communication unit 305 by the power supply IC 303 is stopped. For this reason, even if the operator performs an input operation for activating the infrared communication unit 305 on the operation unit, the infrared communication unit 305 is not activated. Thus, when the infrared communication unit 305 stops operating, the operator can estimate the disconnection of the coaxial cable 315 as one of the causes of the failure.

  When the coaxial cable 316 is disconnected, power supply to the camera 306 by the power supply unit 401 is stopped. For this reason, even if the operator performs an input operation for activating the camera 306 on the operation unit, the camera 306 is not activated. Thus, when the camera 306 stops operating, the operator can estimate the disconnection of the coaxial cable 316 as one of the causes of the failure.

  When the coaxial cable 317 is disconnected, power supply to the display unit 307 by the power supply unit 402 is stopped and power supply from the battery 112 to the camera light 308 via the coaxial cable 317 is stopped. Therefore, even if an input operation for displaying information or a camera light operation is performed, the display unit 106 and the camera light 308 do not operate. Therefore, the operator can estimate the disconnection of the coaxial cable 317 as one of the causes of the failure.

  In the portable terminal of the present embodiment, the power supply IC 304 controls the power supply to the two functional units of the camera 306 and the display unit 307. The power supply IC 304 is provided for each functional unit of the camera 306 and the display unit 307. In addition, power supply units 401 and 402 are provided. The power supply units 401 and 402 are connected to the battery 112 via different coaxial cables 316 and 317, respectively. Thus, by providing a power supply unit for each function unit in one power supply IC, and connecting each power supply unit to the battery 112 via different coaxial cables, it is possible to achieve an optimal current capacity for each function unit. A connection form using a coaxial cable can be provided. As a result, when power is supplied to a plurality of functional units with one power supply IC, the problem of heat generation of other coaxial cables due to the cutting of the coaxial cable and the problem of the occupied space of the coaxial cable can be solved. .

  In the portable terminal of this embodiment, since the coaxial cables 315 to 317 are connected to the battery 112 via the fuses 318 to 320, when a short circuit occurs in the power supply IC to which the coaxial cable is connected, The fuse inserted in the coaxial cable is cut. Thereby, since it is suppressed that the electric current more than an allowable current flows into a coaxial cable, the problem of heat_generation | fever of a coaxial cable can be avoided.

  In addition, even when the coaxial cable is short-circuited, the functional unit receiving power supply from another coaxial cable operates. Thus, when the coaxial cable is short-circuited, only a part of the functions are stopped.

  The fuse may be inserted anywhere in the line to which each coaxial cable is connected.

(Third embodiment)
FIG. 3 is a block diagram showing a configuration of a mobile terminal according to the third embodiment of the present invention. This portable terminal has the housing parts 1 and 2 and the two coaxial cables 115 and 116 shown in FIG. Part of the configuration of the housing unit 1 and part of the operation of the power supply ICs 103 and 104 are different from those of the first embodiment.

  The casing unit 1 includes a separation circuit 107 and a notification unit 108 in addition to the power supply IC 101 and the control unit 102. The power supply IC 101 supplies power to the control unit 102, the separation circuit 107, and the notification unit 108.

  The power supply IC 103 transmits an identification signal for identifying itself to the separation circuit 107 through the coaxial cable 115 at regular time intervals. The power supply IC 104 transmits an identification signal for identifying itself to the separation circuit 107 via the coaxial cable 116 at regular time intervals.

  The separation circuit 107 receives the identification signals from the power supply ICs 103 and 104 through the coaxial cables 115 and 116, and supplies the received identification signals to the control unit 102.

  The control unit 102 monitors the reception status of the identification signals of the power supply ICs 103 and 104 supplied from the separation circuit 107, and determines whether or not each identification signal is supplied at regular time intervals. When the identification signal of either of the power supply ICs 103 and 104 cannot be received, the control unit 102 causes the notification unit 108 to perform an operation for notifying that an abnormality has occurred in the coaxial cable. For example, the notification unit 108 includes an LED, a speaker, and the like, and notifies that an abnormality has occurred in the coaxial cable by controlling the lighting of the LED and the output of the speaker. By this notification operation, the operator can know that a break has occurred in any of the coaxial cables.

  For example, when the coaxial cable 115 is disconnected, power supply to the camera 105 by the power supply IC 103 is stopped. Therefore, even if the operator performs an input operation for starting the camera 105 on the operation unit, the camera 105 Does not start. The failure in this case includes failure of the camera 105 itself, disconnection of the coaxial cable 115, and failure of the power supply IC 103.

  In the above state, when the notification by the notification unit 108 is not made, it can be determined that the camera 105 is in failure. On the other hand, when the notification by the notification unit 108 is made, it can be determined that the coaxial cable 115 is disconnected or the power supply IC 103 is broken. In this way, the notification by the notification unit 108 can distinguish between the failure of the camera 105 and the disconnection of the coaxial cable 115 or the failure of the power supply IC 103.

  The above-described failure isolation by notification can be performed in the same manner for the other coaxial cables 116.

  Moreover, the alerting | reporting part 108 is good also as a structure which provided LED for every coaxial cable. In this case, the housing unit 1 includes a table (memory) that stores the identification information of each LED and the identification information of each power supply IC in a one-to-one correspondence. When the identification signal of any of the power supply ICs 103 and 104 cannot be received, the control unit 102 refers to the table to determine the LED corresponding to the identification signal that could not be received, and performs a notification operation by the LED. Let it be done. By this notification operation, the operator can determine the disconnection of the coaxial cable or the failure of the power supply IC without checking the operation.

  It is also possible to combine the configurations described in the first to third embodiments. For example, the configuration of the mobile terminal of the third embodiment may be applied to the mobile terminal of the second embodiment. In this case, the power supply IC 304 may transmit identification information for identifying itself to the separation circuit, and each of the power supply units 401 and 402 supplies identification information for identifying itself to the separation circuit. You may send it.

  Moreover, in each embodiment, the housing | casing part 2 may be provided with two or more. In this case, the plurality of housing parts 2 may be connected in series with the housing part 1 or in parallel.

  According to one aspect of the present invention, a mobile terminal includes a first casing unit provided with a DC power supply, and a plurality of coaxial cables connected to the DC power supply in common, and a plurality of functions each providing different functions. At least one second housing portion in which the functional portions are housed, and the plurality of functional portions are separately connected to the DC power source via different coaxial cables among the plurality of coaxial cables. ing. Here, the function unit corresponds to an infrared communication unit, a camera, a display unit, and the like.

  The portable terminal may include at least one first power supply IC for supplying power to the plurality of functional units.

  The first power supply IC may include a plurality of power supply units provided for each functional unit.

  Further, the first casing portion accommodates a control portion, a separation circuit provided in a connection line between the plurality of coaxial cables and the DC power source, and a notification portion for notifying abnormality. The power supply IC transmits an identification signal for identifying itself to the separation circuit via the plurality of coaxial cables at regular time intervals, and the separation circuit receives the identification signal from the power supply IC. To the control unit, and the control unit monitors the reception state of the identification signal from the power supply IC, and if the identification signal cannot be received at regular time intervals, the notification unit notifies the abnormality. May be performed.

  Further, a fuse may be provided in each of the lines to which the plurality of coaxial cables are connected.

  According to the above configuration, since the plurality of functional units are connected to the battery via different coaxial cables, if a disconnection occurs in any of the coaxial cables, the function connected to the coaxial cable in which the disconnection has occurred. Part does not work. Therefore, when the function unit does not operate by the operation check, it is possible to estimate the disconnection of the coaxial cable connected to the function unit as the cause of the failure. In this way, it is possible to easily confirm the cutting of the coaxial cable.

  In addition, a coaxial cable having an optimum allowable current capacity can be provided for each functional unit. As a result, the space occupied by the coaxial cable is larger than that in the case where power is supplied to each functional unit using one coaxial cable. Can be small. Thereby, size reduction of a portable terminal can be achieved.

  The present invention can be applied to all portable terminals such as a cellular phone and a portable information terminal.

It is a block diagram which shows the structure of the portable terminal which is the 1st Embodiment of this invention. It is a block diagram which shows the structure of the portable terminal which is the 2nd Embodiment of this invention. It is a block diagram which shows the structure of the portable terminal which is the 3rd Embodiment of this invention.

Explanation of symbols

1, 2 Cases 101, 103, 104 Power supply IC
102 Control unit 105 Camera 106 Display unit 112 Battery 115, 116 Coaxial cable

Claims (5)

A first housing portion provided with a DC power supply;
A plurality of coaxial cables commonly connected to the DC power supply;
And at least one second housing portion in which a plurality of functional portions each providing different functions are accommodated,
The mobile terminal, wherein the plurality of functional units are separately connected to the DC power source via different coaxial cables among the plurality of coaxial cables.   The portable terminal according to claim 1, comprising at least one power supply IC for supplying power to the plurality of functional units.   The portable terminal according to claim 2, wherein the power supply IC includes a plurality of power supply units provided for each functional unit. The first housing portion includes
A control unit;
A separation circuit provided in a connection line between the plurality of coaxial cables and the DC power source;
A notification unit for informing the abnormality;
Is housed,
The power supply IC transmits an identification signal for identifying itself to the separation circuit via the plurality of coaxial cables at regular time intervals,
The separation circuit supplies an identification signal from the power supply IC to the control unit,
The control unit monitors the reception state of the identification signal from the power supply IC, and if the identification signal cannot be received at a constant time interval, causes the notification unit to report an abnormality. 3. The mobile terminal according to 3.   The portable terminal according to any one of claims 1 to 4, further comprising a fuse in each of the lines to which the plurality of coaxial cables are connected.

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