JP3535479B2 - Mobile terminal unit - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile phone and a personal digital assistant (PDA: Personal Digital Assistant).
s), a mobile terminal device such as a PHS (Personal Handyphone System) terminal, and more particularly to a mobile terminal device including a camera, the mobile terminal unit and a flash unit.

[0002]

2. Description of the Related Art In recent years, mobile terminal devices typified by mobile phones and PHS terminals have rapidly spread, and as one of them, a terminal device equipped with a camera has been developed. This type of terminal device has, for example, a CMOS (Complementary Metal Oxide Semicond
uctor) and the like using a solid-state image sensor,
A still image or a moving image captured by this camera is transmitted. For example, the user's face or surrounding scenery,
Brochures, photographs, catalogs, etc. can be sent to the other party as image information, which is very convenient. However, current cameras are limited in the number of elements and sensitivity due to restrictions such as the size and price of mobile terminal devices, and it is generally difficult for the camera alone to obtain an image of satisfactory quality at night or in a dark room.

[0003]

Therefore, recently, it has been proposed to incorporate a flash into a portable terminal device. However, the flash requires an electronic component that is difficult to miniaturize, such as a large-capacity capacitor that determines the amount of emitted light.

The present invention has been made in view of the above circumstances. An object of the present invention is to provide a portable terminal device capable of satisfying nighttime photographing without increasing the size and weight of the device body. It is to provide the portable terminal unit and the flash unit.

[0005]

[0006]

[0007]

[0008]

[0009]

[0010]

[0011]

[0012]

[0013]

[0014]

[0015]

In order to achieve the above object, the present invention takes the following means. (1) A portable terminal unit equipped with a camera and to which a flash unit is detachably mounted via a connector, and in the state where the flash unit is mounted, power is supplied to the flash unit via the connector. Power supply control means for charging the power storage means and a light emission control signal to the flash unit via the connector in response to a shutter operation of the camera to discharge the power storage means to perform a light emitting operation. And a light emission control means. Further, the power supply control means includes a power supply condition determination means, the first condition is that the flash unit is attached, and the second condition is that the portable terminal unit is set to a mode in which the camera is used. If the third condition is that the battery remaining amount of the mobile terminal unit is equal to or more than a predetermined amount, the first to third
The power supply condition determination means determines whether or not each of the conditions is satisfied, and when the power supply condition determination means determines that all of the first to third conditions are satisfied, power supply to the flash unit is started. It is something that is done. Therefore, according to the mobile terminal unit according to the present invention, flash photography using the flash unit can be performed as needed without increasing the size and weight of the mobile terminal unit itself, and can be used at night or in a dark room. Can also obtain images of satisfactory quality. Further, when the flash unit is attached to the mobile terminal unit and the power supply condition is satisfied, the charging of the flash unit is automatically started. Therefore, the user can start flash photography in a short time. Moreover, the power supply operation is performed only when the mobile terminal unit satisfies the conditions required for using the flash unit, and thus the power supply to the flash unit does not guarantee the original operation of the mobile terminal unit. This problem can be prevented in advance.

[0016]

[0017]

(2) The power supply control means includes a power supply condition determination means and a charging operation detection means for detecting a charging start operation. The charging operation detection means detects the charging start operation, and the power supply condition determination means. By this, when it is determined that all the first to third conditions are satisfied, power supply to the flash unit is started. With this configuration, charging is not started just by mounting the flash unit on the mobile terminal unit, and charging is started only when the user performs a charging start operation. For this reason, it is possible to prevent unnecessary charging when the flash unit is not used immediately after being mounted, and thus it is possible to suppress the battery consumption of the mobile terminal unit.

(3) In the invention described in (2),
The charging operation detecting means further includes a function of determining whether or not the continuous operation time of the charging start operation is within a predetermined time, the continuous operation time of the charging start operation is within the predetermined time, and the first to the first The power supply to the flash unit is started only when all the conditions of 3 are satisfied.
With this configuration, even if all of the first to third conditions are satisfied, if the continuous operation time of the charging start operation exceeds the predetermined time, this charging start operation is an erroneous operation. It is judged and charging is not started. Therefore, it is possible to prohibit the charging operation when a charging start operation that is unrelated to the user's intention is performed.

(4) In the invention described in (2) or (3), the power supply control means is further provided with a notification means of a power supply condition determination result, and the power supply condition determination means determines one of the first to third conditions. When it is determined that at least one is not satisfied, the fact is notified to the user. With this configuration, the user can know that the power supply condition is not satisfied. At that time, it is preferable to notify the user of the reason why the power supply condition is not satisfied and also the operation guidance.

(5) The power supply control means has a plurality of predetermined different power supply times, estimates the state of charge in the power storage means of the flash unit, and selects from among the plurality of power supply times according to the estimation result. Power is supplied by selecting an appropriate power supply time. With this configuration, it is possible to optimally supply power according to the state of charge in the power storage unit of the flash unit, thereby preventing overcharging and wasting the battery of the mobile terminal unit. Can be suppressed.

(6) In the invention described in (5), the power feeding control means has a predetermined first power feeding time and a second power feeding time shorter than the first power feeding time, It is determined whether or not power is being supplied to the power storage means of the unit, and if the power is not being supplied, the first power supply time is selected to perform power supply for new charging, while if power is being supplied, Power is supplied for additional charging by selecting the second power supply time. With this configuration, when the power storage unit is not charged at all, such as immediately after the flash unit is mounted, the first power supply time set to a length long enough to be fully charged is selected. Since the battery is charged in this manner, the power storage unit can be surely fully charged.
On the other hand, when the charging start operation is performed again in a state where the charging voltage of the power storage unit is lowered due to spontaneous discharge or the like, the second power feeding time set to be shorter than the first power feeding time is selected and charging is performed. By doing so, it is possible to efficiently restore the power storage unit to the fully charged state without supplying extra power.

(7) In the invention described in (5) or (6), when the portable terminal unit has a self-timer function for photographing, the power supply control means sets the self-timer function. Whether or not the self-timer function is set is determined, and the set time of the self-timer is added to the power supply time. With this configuration, the light emission operation with the optimum light amount can be performed at the time of the shutter operation in consideration of the set time of the self-timer, and thus the flash can be used more effectively.

[0024]

[0025]

[0026]

[0027]

1 is an external view showing the configuration of a portable terminal device equipped with a camera according to an embodiment of the present invention. The mobile terminal device of this embodiment includes a mobile terminal unit MU and a flash unit FU,
The flash unit FU is detachably attached to the mobile terminal unit MU using a connector. A key input unit 21, a display unit 22 and a camera 23 are arranged on the front surface of the mobile terminal unit MU. In addition, 1 is an antenna. On the front surface of the flash unit FU, a light emitting unit 31
And a charging display section 32 is provided.

On the other hand, FIG. 2 is a block diagram showing a circuit configuration of the mobile terminal unit MU. In the figure, a radio carrier signal sent from a base station (not shown) via a radio channel is received by an antenna 1 and then input to a receiving circuit (RX) 3 via an antenna duplexer (DUP) 2. In the receiving circuit 3, the received radio carrier signal is mixed with the receiving local oscillation signal output from the frequency synthesizer (SYN) 4 and frequency-converted into a receiving intermediate frequency signal. And this received intermediate frequency signal is
After being sampled in the A / D converter 6 including a low pass filter, it is input to the digital demodulation circuit (DEM) 7.

The digital demodulation circuit 7 establishes frame synchronization and bit synchronization for the digital received intermediate frequency signal, and then performs digital demodulation processing. The baseband digital demodulated signal obtained by this demodulation processing is a time division multiple access circuit (TDMA) 8
, And the time slot destined for itself is separated and extracted for each transmission frame. The information on the frame synchronization and the bit synchronization obtained in the digital demodulation circuit 7 is notified to the control circuit 20.

The digital demodulated signal output from the TDMA circuit 8 is subsequently subjected to an error correction code decoding circuit (CH-
COD) 9 and undergoes error correction decoding processing. In this error-correction-decoded digital demodulated signal,
Depending on the communication mode at that time, there are information data such as mail and call voice data. Of these, the call voice data is input to the voice code decoding circuit (SP-COD) 10 and subjected to voice decoding processing, whereby a digital received signal is reproduced. This digital reception signal is returned to an analog reception signal by the D / A converter 11, and then input to a voice amplifier (not shown) through the switching circuit 12a. After being amplified here, it is supplied to the speaker 13 and output as a loud sound. It Further, the information data such as the received mail and the received download data is taken into the control circuit 20, stored in the memory (MEM) 24 by the control circuit 20, and decrypted and displayed on the display unit 22.

On the other hand, the voice transmitted by the speaker is the microphone 1
After being collected by 4 and converted into a transmission signal and further amplified to a predetermined level by a transmission amplifier (not shown),
It is input to the A / D converter 19 via the switching circuit 12b. Then, the A / D converter 19 samples the signal at a predetermined sampling period, and thereby, the signal is converted into a digital transmission signal composed of a sample pulse train.
After the acoustic echo is canceled by an echo canceller (not shown), the digital transmission signal is input to the voice code decoding circuit (SP-COD) 10 and voice coded there.

This voice-coded digital transmission signal is input to the error correction code decoding circuit (CH-COD) 9 and is error-correction coded there. In addition, the control circuit 20
Information data such as image data and a transmission mail output from is also input to the error correction code decoding circuit 9 and is error correction coded. The digital transmission signal output from the error correction code decoding circuit 9 is input to the TDMA circuit 8. In the TDMA circuit 8, time division multiple access (TD
A transmission frame corresponding to the (MA) system is generated, and a process for inserting the digital transmission signal is performed in the time slot assigned to the own device in the transmission frame.

The digital transmission signal output from the TDMA circuit 8 is subsequently supplied to a digital modulation circuit (MOD).
15 is input. In the digital modulation circuit 15, a transmission intermediate frequency signal digitally modulated by the digital transmission signal is generated, and the transmission intermediate frequency signal is D / A.
After being converted into an analog signal by the converter 16, it is input to the transmission circuit (TX) 5. As a digital modulation method, for example, π / 4 shift DQPSK (π / 4 shif
ted, differentially encoded quadrature phase shift
keying) method is used.

In the transmission circuit 5, the modulated transmission intermediate frequency signal is mixed with the transmission local oscillation signal output from the frequency synthesizer 4, and thereby converted into a radio carrier frequency corresponding to the radio communication channel. Then, this transmission radio carrier signal is controlled to a predetermined transmission power level by a transmission power amplifier (not shown), and then transmitted from the antenna 1 to the base station (not shown) via the antenna duplexer 2.

The portable terminal unit also includes a key input section 21, a display section 22, a camera 23, a memory (ME).
M) 24. The key input unit 21 includes various keys necessary for communication such as a transmission key, an end key, a plurality of function keys and a dial key, and further, a shutter key for operating the camera 23 and a flash unit F.
It has a charging key for charging U. Note that these shutter key and charge key can also be used as keys required for the above communication under the control of software.

The display 22 is, for example, a liquid crystal display (LC
D: Liquid Crystal Display) is used to display the display data output from the control circuit 20. The display data includes not only management data such as a telephone directory and transmission / reception history, data representing the operating state of the apparatus, but also transmission / reception mail and image data.

The camera 23 is, for example, a CMOS (Compleme
ntary Metal Oxide Semiconductor) or CCD (Charg
It uses a solid-state imaging device such as an e-coupled device) and is controlled by the control circuit 20. The memory 24 is composed of, for example, a RAM or a flash memory, stores a telephone directory, mails or download data received from a terminal of a communication partner or an information site, and also stores the camera 21.
The image data captured by, the sent mail, etc. are also saved.

Reference numeral 18 denotes a power supply circuit, which charges the flash unit FU with the power supply voltage Vcc necessary for the operation of each circuit of the mobile terminal unit MU based on the output voltage of the battery 17 which is a secondary battery. Charging voltage required for V
generate ss.

By the way, the portable terminal unit MU is provided with an earphone jack 25, a power supply circuit 26, a plug insertion / removal detection section 27, and a mounting identification section 28 as a structure for mounting and using the flash unit FU. ing.

The earphone jack 25 is originally used for mounting an earphone unit (not shown), but is also used as a terminal side jack for mounting the flash unit FU. The earphone jack 25
Is connected to the D / A converter 11 and the A / D converter 19 via the switching circuits 12a and 12b. The switching between the switching circuits 12a and 12b is performed by the control circuit 20.
Controlled by.

The power feeding circuit 26 has a power feeding time designated by the power feeding control signal VC given from the control circuit 20,
The charging voltage Vss output from the power supply circuit 18 is supplied to the flash unit FU. Here, as the above-mentioned power supply time, two types of first power supply time and second power supply time are prepared. The first power supply time is set to a time (for example, 15 seconds) necessary and sufficient to charge the flash unit FU from the initial state to the fully charged state. The second power supply time is
A sufficient and sufficient time (for example, 10 seconds) to charge the flash unit FU from a partially discharged state to a fully charged state.
Seconds).

The plug insertion / removal detection unit 27 detects insertion of the plug of the earphone unit or the flash unit FU into the earphone jack 25, and notifies the control circuit 20 of the insertion detection signal DET1.

The mounting identification section 28 applies a predetermined identification voltage to a specific terminal of the earphone jack 25 when the plug insertion / removal detection section 27 detects the insertion of the plug.
On the other hand, it is monitored whether the detection voltage is returned from the flash unit FU via another specific terminal. Then, the mounting identification signal DE indicating whether or not the detected voltage is returned
The control circuit 20 is notified of T2.

The control circuit 20 includes, for example, a microcomputer as a main control unit, and has a flash unit as a new control function related to the present invention in addition to the normal control functions such as a radio access control function and a call control function. It has an identification function 20a and a flash power supply control function 20b.

When the flash unit identification function 20a detects that the plug is attached to the earphone jack 25 by the insertion detection signal DET1 output from the plug insertion / removal detection unit 27, the attachment identification unit 28 notifies the attachment. Based on the identification signal DET2, it is identified whether the attached external unit is the earphone unit or the flash unit FU.

The flash power supply control function 20b is activated by pressing the charge key and determines whether or not the preset power supply condition is satisfied. When the result of this determination is that the power supply conditions are satisfied, it is determined whether the state of the flash unit FU at this time is the initial state or the power supply state. Then, in the initial state, the first power feeding time described above is selected, while in the power feeding state, the second power feeding time is selected, and the power feeding control signal VC for designating these is generated. It is applied to the power supply circuit 26. Further, when selecting the power feeding time, it is determined whether or not the self-timer is being set, and if it is being set, the set time of the self-timer is added to the power feeding time.

On the other hand, the flash unit FU and its plug 30 are constructed as follows. FIG. 3 is a block diagram showing its configuration. The flash unit FU includes a light emitting unit 31 having a flash lamp, a charging display unit 32 using a neon tube, a power receiving unit 33, a capacitor 34,
The signal input unit 35 and the delay control unit 36 are provided.

Of these, the power receiving unit 33 stores the charging voltage Vss supplied from the portable terminal unit MU in the capacitor 34.
And charge it. The signal input unit 35 receives the light emission control signal FRS output from the mobile terminal unit MU. The delay control unit 36 delays the light emission control signal FRS output from the signal input unit 35 by a preset delay time and supplies the light emission control signal FRS to the light emitting unit 31, thereby discharging the charging voltage of the capacitor 34 and causing the capacitor 34 to emit light.

The plug 30 has five terminals A, B, C,
D and E are arranged in a line in order from the tip, and they are inserted into an earphone jack 25 having seven terminals capable of stereo audio output and microphone audio input. 5A and 5B are a sectional view and a side view showing the structures of the earphone jack 25 and the flash unit FU, respectively. FIG. 6 shows the earphone jack 25.
3 is a diagram showing a circuit configuration of FIG.

That is, first, the terminal A is used as a power receiving terminal for the charging voltage Vss.
It contacts with the terminal T2 arranged at the deepest part. The reason for assigning the power feeding terminal to the deepest terminal T2 of the earphone jack 25 is to prevent terminals other than the power receiving terminal A of the plug 30 from accidentally making contact with the power feeding terminal T2 during the plug 30 insertion / removal process. is there.

The terminal B is used as a plug insertion / removal detection terminal and a mounting identification voltage power receiving terminal, respectively.
Contact the terminal T3 of the earphone jack 25. The terminal C is used as a ground terminal and contacts the terminal T6 of the earphone jack 25. The terminal D is used as a terminal for receiving the light emission control signal FRS, and is connected to the terminal T1 of the earphone jack 25.
To contact.

The terminal E is connected to the terminal B in the plug and comes into contact with the terminal T7 of the earphone jack 25.
With this configuration, the mounting identification voltage applied to the terminal B is returned from the terminal E of the plug 30 to the mobile terminal unit MU as a detection voltage via the terminal T7 of the earphone jack 25.

FIG. 7 shows the terminals A to E of the plug 30 and the terminals T1 to T7 of the jack 25 when the plug 30 is inserted into the earphone jack 25 at a constant speed.
It is the figure which showed the contact timing with, and t0-t in the figure
Reference numeral 19 indicates a contact start or end timing between terminals.

Next, the operation of the apparatus configured as described above will be described. First, the mounting identification process of the flash unit FU is performed as follows. FIG. 4 is a flowchart showing the processing procedure and processing contents. That is, the mobile terminal unit MU monitors the insertion of the external unit plug into the earphone jack 25 by the control circuit 20 in step 4a.

Now, in this state, it is assumed that the user inserts the plug 30 of the flash unit FU into the earphone jack 25 of the portable terminal unit MU in order to perform flash photography. Then, the plug insertion / removal detection unit 27 outputs the detection signal DET1, and the control circuit 20 recognizes in step 4a that the plug of the external unit is inserted by the detection signal DET1.

When the plug 30 is inserted into the earphone jack 25, the attachment identifying voltage is applied from the attachment identifying section 28 to the terminal B of the plug. At this time, if the inserted plug is the plug of the earphone unit, the detection voltage is not returned to the mobile terminal unit MU. However, if the inserted plug is the plug 30 of the flash unit FU, since the terminal B and the terminal E are connected in the plug 30, the mounting identification voltage is directly mounted from the terminal E as a detection voltage. It is returned to the identification unit 28. And
The mounting identification signal D from the mounting identification unit 28 to the control circuit 20.
ET2 is notified. In step 4b, the control circuit 20 recognizes that the mounted external unit is the flash unit FU by the notification of the mounting identification signal DET2. Then, the process proceeds to step 4c, where the operation mode of the mobile terminal unit MU is set to the flash unit F.
Set to U usage mode.

As the terminal for returning the detected voltage,
The terminal E located closest to the base end of the plug 30 is used. Therefore, in the process of inserting the plug 30, the terminal E
Is the terminal T7 of the earphone jack 25 as shown in FIG.
There is no concern about contact with terminals other than. Therefore, the control circuit 2
0 can identify the mounting of the flash unit without causing an erroneous determination.

Next, assume that the user presses the charge key to charge the flash unit FU. Then, the control circuit 20 executes power supply control according to the following procedure. FIG. 8 is a flowchart showing the power supply control procedure and control contents.

That is, the control circuit 20 of the mobile terminal unit MU shifts to step 8b when it detects the pressing of the charging key in step 8a, and first determines the use state of the self-timer. As a result of this determination, if the self-timer is not being used, the process directly proceeds to step 8d, while if the self-timer is being used, the process of adding the set time of the self-timer to the power feeding time is performed in step 8c. Go to step 8d. The reason why the set time of the self-timer is added to the power supply time is to compensate for the decrease of the charging voltage due to the natural discharge of the capacitor 34 during the self-timer time period from the operation of the shutter key to the actual operation of the shutter. This is because.

When the process proceeds to step 8d, the control circuit 20 determines the power supply condition. The power supply conditions to be determined are the following four items. Power supply condition 1 The continuous pressing time of the charge key must be less than the specified time. Power supply condition 2 The flash unit FU must be installed. Power supply condition 3 The operation mode of the mobile terminal unit MU is set to the camera use mode. Power supply condition 4 The remaining battery level of the mobile terminal unit MU is 1
Must be 0% or more.

The power supply condition 1 is to eliminate erroneous charging when the charging key is continuously pressed in a state not intended by the user. The power supply conditions 2 and 3 are for preventing the charging operation from being performed when the flash unit FU is not ready. The power supply condition 4 is to prevent the flash unit FU from being charged when the battery remaining amount of the mobile terminal unit MU is low. This prevents the portable terminal unit MU from becoming inoperable as a result of charging the flash unit FU and running out of battery.

When all of the above power supply conditions 1 to 4 are satisfied, the control circuit 20 subsequently sets the power supply time.
As described above, two types of power feeding time are prepared, namely the first power feeding time and the second power feeding time. The first power supply time is a sufficient time (for example, 15 minutes) to charge the flash unit FU from the initial state to the fully charged state.
Seconds). The second power supply time is set to a time (for example, 10 seconds) necessary and sufficient for additionally charging the flash unit FU from a partially discharged state to a fully charged state.

The control circuit 20 selects one of the first power feeding time and the second power feeding time based on the following selection conditions. That is, selection condition 1 When the charge key is pressed while power is not being supplied to the flash unit FU. Selection condition 2 If either one of the cases where the flash unit FU is first mounted is selected, the first power supply time (15 seconds) is selected.

On the other hand, selection condition 3 When the charge key is pressed while power is already supplied to the flash unit FU. If the above condition applies, the second power supply time (10 seconds) is selected.

The above-described power supply time selection sequence can be realized not only by the control circuit 20 using software but also by using a logic circuit. Figure 9
Shows an example of the circuit configuration.

When the selection and setting of the power feeding time is completed in this way, the control circuit 20 proceeds to step 8e, where the power feeding control signal VC for designating the power feeding time is generated and given to the power feeding circuit 26. Then, the charging voltage Vss is sent from the power feeding circuit 26 to the power receiving section 33 of the flash unit FU via the terminal T2 of the earphone jack 25 and the terminal A of the plug 30, and the capacitor 34 is charged thereby.

For example, when the user attaches the flash unit FU to the mobile terminal unit MU for the first time,
Even if the flash unit FU is attached, the camera 23
If it is not used, that is, if it is not in the camera use mode, the control circuit 20 determines that it is in the selection condition 1 or the selection condition 2 described above, and the first power supply time (15 seconds). ) Is selected. Therefore, the capacitor 34 of the flash unit FU is newly charged for a sufficiently long time according to the first power supply time (15 seconds). Therefore, as shown in FIG. 10, the capacitor 34 surely reaches the charging voltage value corresponding to the fully charged state.

On the other hand, it is assumed that the user does not operate the shutter key for a while after reaching the full charge. Then, the charging voltage value of the capacitor 34 gradually decreases due to spontaneous discharge as shown in FIG. 10, for example. Then, when the voltage becomes less than or equal to the voltage at which light emission is possible,
2 goes out.

In such a case, the user depresses the charge key again. This re-operation of the charge key corresponds to the state of the selection condition 3 described above, that is, the state where the charge key is pressed down again while power is already being supplied to the flash unit FU. Therefore, the control circuit 20 selects the second power supply time (10 seconds), and the capacitor 34 of the flash unit FU is additionally charged according to the second power supply time (10 seconds). Therefore, the capacitor 34 returns to the fully charged state as shown in FIG. In this case, since the second power feeding time set to be short is selected as the power feeding time, the capacitor 34 is efficiently charged without causing overcharging or the like.

Further, during the above new charging or additional charging, the control circuit 20 creates a message indicating "charging" in step 8g, and displays this message on the display unit 22.
To display. Therefore, the user can know from this message that the flash unit FU is being charged. Then, when the capacitor 34 is fully charged, the neon tube of the charge display section 32 of the flash unit FU is turned on. Therefore, the user can confirm the completion of charging by turning on the charging display unit 32.

On the other hand, it is assumed that any one of the feeding conditions 1 to 4 is not satisfied. In this case, the control circuit 2
For 0, the process proceeds to step 8f and the power supply stop process is performed. That is, the power supply control signal VC is not generated. Therefore,
The charging voltage is not supplied from the power supply circuit 26 to the flash unit FU, and therefore the capacitor 34 is not charged. Further, at this time, the control circuit 20 shifts to step 8h, where a message indicating "a factor of non-satisfaction of the power supply condition" is generated, and this message is displayed on the display unit 22. Therefore, the user can clearly know the reason why the flash unit FU is not charged by this message.

Now, it is assumed that the user who confirms the completion of charging by lighting the charge display portion 32 of the flash unit FU pushes the shutter key provided in the key input portion 21 of the portable terminal unit MU. Then, the light emission control signal FRS is generated in the control circuit 20, and this light emission control signal FRS is sent to the signal input unit 35 of the flash unit FU via the terminal T1 of the earphone jack 25 and the terminal D of the plug 30. Then, this emission control signal FRS
Is applied to the light emitting unit 31 after being delayed by the delay control unit 36 for a predetermined time. Therefore, in the light emitting section 31, the light emitting operation is performed by discharging the charging voltage of the capacitor 34.

FIG. 11 shows an example of the light emission timing. As shown in the figure, between the generation timing of the light emission control signal FRS according to the operation of the shutter key and the timing at which the camera 23 actually starts photographing, about 0.5 msec.
There is a time difference. However, this time difference is absorbed by the delay controller 36 provided in the flash unit FU. Therefore, the flash emission timing is set to the camera 2
This coincides with the shooting start timing of No. 3.

Then, it is assumed that the photographing is completed and the user pulls out the plug 30 of the flash unit FU from the earphone jack 25 of the portable terminal unit MU. Then, the control circuit 20 detects this state by the detection signal DET1 output from the plug insertion / removal detection unit 27. Since the power supply condition is not satisfied by pulling out the plug, the flash use mode currently set is released. Therefore, the power supply from the mobile terminal unit MU to the flash unit FU is not performed thereafter.

At this time, since the power feeding terminal T2 of the earphone jack 25 is arranged at the deepest part of the jack, the terminals other than the terminal A of the plug 30 are the power feeding terminals of the earphone jack 25 in the process of pulling out the plug 30. There is no need to worry about contacting T2. Further, in the process of pulling out the plug, as is apparent from the timing chart shown in FIG. 7, the contact state between the ground terminal C of the plug 30 and the ground terminal T6 of the earphone jack 25 is disconnected at the earliest timing. Become. That is, the power supply circuit system is opened and power supply is stopped at the earliest stage of the plug withdrawal process. Therefore, the control circuit 2 in the process of pulling out the plug
0 and the malfunction of the flash unit FU are prevented.

As described above, in this embodiment, the flash unit FU is provided separately from the mobile terminal unit MU equipped with the camera 23, and the plug 30 of this flash unit FU is attached to the earphone jack 25 of the mobile terminal unit MU. . In this state, it is confirmed that a predetermined power supply condition is satisfied, and an appropriate power supply time is selected according to the power supply state at that time, and then the mobile terminal unit MU is selected.
Powers the flash unit FU to charge the capacitor 34. Then, the light emitting control signal FRS is given from the portable terminal unit MU to the flash unit FU in response to the shutter operation of the camera 23, so that the capacitor 34 is discharged and the light emitting operation is performed.

Therefore, according to this embodiment, the user can mount the flash unit FU on the portable terminal unit MU to perform flash photography as necessary. Therefore, it is possible to obtain an image of satisfactory quality even at night or in a dark room. Also, when not shooting,
Since the flash unit FU can be removed in the daytime or in a bright place even when shooting, the size and weight of the mobile terminal unit MU can be kept smaller than when the flash function is built into the mobile terminal unit MU.

Also, the earphone jack 25 already provided in the mobile terminal unit MU is shared as a connector, and the external unit attached when the plug 30 is inserted into the earphone jack 25 is automatically identified. Therefore, it is not necessary to newly provide a connector dedicated to the flash unit FU, and the mounting of the flash unit FU can be surely recognized.

Further, before power supply to the flash unit FU, it is determined whether or not a predetermined power supply condition is satisfied, and power is supplied only when the predetermined power supply condition is satisfied. For this reason, power can be supplied only when the flash unit FU is certainly in a chargeable state, whereby it is possible to reliably prevent the occurrence of a power supply accident.

In addition, first and second power supply times having different lengths are prepared, and power is supplied by selectively using the above two kinds of power supply times according to the power supply state of the flash unit FU. There is. Therefore, in a state in which the capacitor 34 is not charged at all, such as immediately after mounting the flash unit FU, the capacitor 34 can be surely fully charged by the first power supply time (15 seconds).
On the other hand, when the charge key is pressed again while the charging voltage of the capacitor 34 is lowered due to spontaneous discharge or the like, the second power supply time (10 seconds) set shorter than the first power supply time is selected. By performing the charging in this way, the capacitor 34 can be efficiently restored to the fully charged state without supplying extra power.

When the self-timer is used, the set time of the self-timer is added to the power supply time. Therefore, the decrease in the charging voltage value during the self-timer operation period is compensated for and the camera is compensated. It is possible to always obtain the light emission amount of the specified amount or more at the shooting timing of 23.

Further, the flash unit FU is provided with a light emission timing delay control section 36 so that the flash light is emitted at a time point delayed by a preset time from the time point when the light emission control signal FRS is given from the portable terminal unit MU. ing. Therefore, in the mobile terminal unit MU, even if there is an operation delay between the shutter key being pressed and the camera 23 actually starting the shooting operation, the flash emission timing matches the shooting operation timing of the camera 23. Can be made.

Further, in this embodiment, when assigning a function to each terminal of the earphone jack 25 and the plug 30 of the flash unit FU, the power supply terminal is assigned to the terminal at the deepest portion of the jack 25 and the plug 30 is also assigned.
The terminal position of the plug 30 is devised so that the contact state between the ground terminals is turned on the latest in the insertion process, and the contact state between the ground terminals is turned off earliest in the process of pulling out the plug 30.

Therefore, in the process of inserting the plug 30 and the process of pulling out the plug 30, the terminals other than the power receiving terminal A of the plug 30 are the power feeding terminals T2 of the earphone jack 25.
There is no need to worry about contact with. Also, in the plug insertion process, the power supply circuit system becomes a closed circuit at the latest stage, and on the other hand, in the pulling process, the power supply circuit system becomes an open circuit at the earliest stage.
Accidents due to power supply can be reliably prevented.

The present invention is not limited to the above embodiment. For example, in the above-described embodiment, after the flash unit FU is mounted, the power supply control is started in response to the pressing of the charging key. However, when the mounting of the flash unit FU is detected, the power is automatically supplied without waiting for the operation of the charging key. It may be configured to start the control. In this way, the user's operation can be simplified and the charging time can be shortened.

In the above embodiment, after the first or second power feeding time has elapsed, it is considered that the capacitor 34 has reached full charge, and power feeding is stopped thereafter. As described above, the charging voltage value of the capacitor 34 decreases due to spontaneous discharge. Therefore, the first or second
Even after the power feeding time has passed, it is preferable to intermittently repeat the power feeding for supplementary charging at regular intervals. By doing so, the charge voltage value of the capacitor 34 can be held at a value corresponding to full charge until the user operates the shutter key. It should be noted that the power feeding time for the above-mentioned supplementary charging may be set shorter than the first and second power feeding times.

Further, when the portable terminal unit is provided with a strap, a simulated jack is attached to this strap, and an unused flash unit is attached to this simulated jack and held. Good.
In this way, the strap can also be used as a holder for the flash unit. At that time, by devising the shape of the flash unit, it can be provided with a function as an accessory.

Further, as the portable terminal unit, a portable information terminal (PDA), a portable audio player, a portable navigation device, a clock and the like can be applied in addition to the portable telephone.

In addition, the shapes and configurations of the portable terminal unit and the flash unit, the structure of the connector, the method for identifying the mounting of the flash unit, the power supply control procedure for the flash unit and their contents, etc. are various within the scope of the present invention. It can be modified and implemented.

[0090]

As described above in detail, in the present invention, the flash unit is provided separately from the portable terminal unit having the camera, and the flash unit is detachably attached to the portable terminal unit by the connector. . Then, while the flash unit is attached to the mobile terminal unit, the power storage means of the flash unit is charged by performing power supply control from the mobile terminal unit to the flash unit via the connector, and in this charged state, By performing light emission control from the portable terminal unit to the flash unit via the connector according to the shutter operation of the camera, the above-mentioned power storage means is discharged to perform the light emitting operation.

Therefore, according to the present invention, it is possible to provide a portable terminal device provided with a camera, a portable terminal unit and a flash unit for the same, which are capable of satisfying nighttime photographing without increasing the size and weight of the device body. You can

[Brief description of drawings]

FIG. 1 is an external view of a mobile terminal device according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a circuit configuration of a mobile terminal device according to an embodiment of the present invention.

FIG. 3 is a block diagram showing a main configuration of the mobile terminal device shown in FIG.

FIG. 4 is a flowchart showing a procedure and contents of flash unit identification processing.

FIG. 5 is a diagram showing structures of an earphone jack and a flash unit plug used as connectors in the mobile terminal device according to the embodiment of the present invention.

6 is a diagram showing a circuit configuration of the earphone jack shown in FIG.

7 is a diagram showing the contact timing of each terminal when inserting the flash unit plug into the earphone jack shown in FIG.

8 is a flowchart showing a flash unit power supply control procedure and its contents by the mobile terminal device shown in FIG.

FIG. 9 is a diagram showing a power supply condition determination sequence and a power supply time determination sequence by a logic circuit.

FIG. 10 is a diagram showing charge / discharge characteristics in the flash unit.

FIG. 11 is a diagram showing a relationship between a light emission control signal and a flash light emission waveform.

[Explanation of symbols]

MU ... mobile terminal unit FU ... Flash unit 1 ... antenna 2 ... Antenna duplexer (DUP) 3 ... Receiving circuit (RX) 4 ... Frequency synthesizer (SYN) 5 ... Transmission circuit (TX) 6, 19 ... A / D converter 7. Digital demodulation circuit (DEM) 8 ... Time division multiple access circuit (TDMA) 9 ... Error correction code decoding circuit (CH-COD) 10 ... Speech code decoding circuit (SP-COD) 11, 16 ... D / A converter 12a, 12b ... Switching circuit 13 ... Speaker 14 ... Microphone 15 ... Digital modulation circuit (MOD) 17 ... Battery 18 ... Power supply circuit (POW) 20 ... Control circuit 20a ... Flash unit identification function 20b ... Flash unit power supply control function 21 ... Key input section 22 ... Display 23 ... Camera 24 ... Memory (MEM) 25 ... Earphone jack 26 ... Power feeding control unit 27 ... Plug insertion / removal detection unit 28 ... Wearing identification section 30 ... Flash unit plug 31 ... Light emitting part 32 ... Charge display 33 ... Power receiving unit 34 ... Capacitor 35 ... Signal input section 36 ... Delay control unit FRS ... Light emission control signal VSS ... Power supply control signal DET1 ... Insertion detection signal DET2 ... Wearing identification signal

─────────────────────────────────────────────────── ─── Continuation of the front page (51) Int.Cl. ⁷ Identification code FI H04N 5/238 H04N 5/238 Z (72) Inventor Yuji Umemoto 3-1, Asahigaoka, Hino-shi, Tokyo Toshiba Hino Plant Co., Ltd. (56) References JP 2001-86393 (JP, A) JP 2000-201335 (JP, A) JP 2002-368862 (JP, A) Registered utility model 3074054 (JP, U) (58) Field (Int.Cl. ⁷ , DB name) H04M 1/00-1/253 H04M 1/58-1/62 H04M 1/66-1/82 H04N 5/222-5/257 G03B 15/04-15 / 05 G03B 17/02 G03B 17/22

Claims (7)

(57) [Claims] 1. A portable terminal unit comprising a camera, to which a flash unit is detachably mounted via a connector, wherein the flash unit is mounted to the flash unit via the connector. A power supply control means for supplying power to charge the power storage means and a light emission control signal to the flash unit via the connector in response to a shutter operation of a camera to discharge the power storage means to perform a light emitting operation. And a power-supply control means that sets the flash unit as a first condition, and sets the portable terminal unit to a mode in which the camera is used. When the second condition is set and the third condition is that the remaining battery amount of the mobile terminal unit is equal to or more than a predetermined amount, A power supply condition determining means for determining whether or not the first to third conditions are satisfied, and a case where the power supply condition determining means determines that the first to third conditions are satisfied, A mobile terminal unit, comprising: a first power supply starting means for starting power supply to the flash unit. 2. A portable terminal unit comprising a camera, to which a flash unit is detachably attached via a connector, wherein the flash unit is attached to the flash unit via the connector. A power supply control means for supplying power to charge the power storage means and a light emission control signal to the flash unit via the connector in response to a shutter operation of a camera to discharge the power storage means to perform a light emitting operation. And a power supply control means, wherein the first condition is that the flash unit is mounted, and the portable terminal unit is set to a mode in which the camera is used. When the second condition is set and the third condition is that the remaining battery amount of the mobile terminal unit is equal to or more than a predetermined amount, A power supply condition determining means for determining whether or not each of the first to third conditions is satisfied; a charging operation detecting means for detecting a charging start operation; and a charging start operation detected by the charging operation detecting means. Is
And a second power supply starting means for starting power supply to the flash unit when the power supply condition determining means determines that all the first to third conditions are satisfied. . 3. The charging operation detecting means further comprises a function of determining whether or not the continuous operation time of the charging start operation is within a predetermined time, and the second power supply starting means is the charging start operation. The power supply to the flash unit is started when it is determined that the continuous operation time of is within a predetermined time and all the first to third conditions are satisfied. Terminal unit. 4. The power supply control means further comprises a notification means for notifying the user of the fact that, when the power supply condition determination means determines that at least one of the first to third conditions is not satisfied. The mobile terminal unit according to claim 1 or 2, wherein. 5. A portable terminal unit comprising a camera, to which a flash unit is detachably attached via a connector, wherein the flash unit is attached to the flash unit via the connector. A power supply control means for supplying power to charge the power storage means and a light emission control signal to the flash unit via the connector in response to a shutter operation of a camera to discharge the power storage means to perform a light emitting operation. And a power supply control means that has a plurality of different power supply times set in advance, estimates the state of charge of the power storage means of the flash unit, and determines the charge state according to the estimation result. A mobile terminal unit characterized in that an appropriate power supply time is selected from among the plurality of power supply times to perform power supply. 6. The power supply control means has a predetermined first power supply time and a second power supply time shorter than the first power supply time, and is supplying power to the power storage means of the flash unit. If the power is not being supplied, the first power supply time is selected to supply power for new charging.
On the other hand, the mobile terminal unit according to claim 5, wherein when power is being supplied, the second power supply time is selected to supply power for additional charging. 7. The power supply control means further has a function of determining whether or not a self-timer function is set, and adding the set time of the self-timer to the power supply time when the self-timer function is set. 6. The method according to claim 5, wherein
Alternatively, the mobile terminal unit according to item 6.