KR100574513B1 - Power supply of portable composition apparatus and method thereof - Google Patents

Abstract

Provided are a power supply device and a power supply method for a portable composite device. The power supply device included in the portable composite apparatus capable of generating and storing image data and reproducing the stored image data includes: a first power input unit to which a first external power is input and a second power input unit to which a second external power is input; And an input power switching unit operable to selectively apply any one of the first and second external power sources to the portable composite device. Accordingly, when there are a plurality of paths through which external power can be input to the portable composite device, selective input between the plurality of external power sources is possible, thereby preventing collision between the plurality of external power sources. In addition, the reverse flow phenomenon of the input external power source can be prevented and unnecessary power consumption can be prevented.

Cradle, External Power, Reverse Power, Power Supply

Description

Power supply of portable composite device and method of power supply

1 is a circuit diagram of a conventional power supply;

Figure 2a is a perspective view showing the front and right side of the portable composite device,

Figure 2b is a view showing the lower surface of the portable composite device,

Figure 2c is a perspective view showing the back and left side of the portable composite device,

3 is an internal block diagram of a portable multi-device;

4A is a perspective view of the front of the cradle;

4b is a perspective view of the back of the cradle;

Figure 4c is a view showing a case where the portable composite device is mounted on the cradle,

5 is a detailed block diagram of the power supply unit of FIG. 3;

6 is a detailed block diagram of an input power switch of FIG. 5;

7 is a circuit diagram of an input power switch of FIG. 6, and

8 is a flowchart provided to explain a power supply method of a portable multi-function device according to an embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

210: recording unit 231: operation unit

233: second control unit 240: display unit

243: LCD 250: storage

251: memory card 255: HDD

300: main control block 340: CODEC

350: GUI generation unit 360: first control unit

The present invention relates to a power supply device and a power supply method of a portable composite device, and more particularly, when there are a plurality of paths through which external power can be input to a portable composite device capable of generating, storing and reproducing image data. The present invention relates to a power supply device and a power supply method of a portable composite device which enables selective input between external power supplies and prevents reverse flow of the input external power supply.

Portable multi-function devices have functions such as camcorders, digital cameras, MP3 players, voice recorders, data storage devices, and web cameras, and are compact for users to carry and use. Says the device. Such portable composite devices can be implemented by incorporating notable digital technologies into image processing devices such as camcorders.

Recent portable devices are typically powered by a battery, but can also be powered by the cradle by being seated in the cradle to which the adapter is connected. In addition, the adapter can be directly connected to the portable device to receive power.

If the portable device is provided with an adapter connector and a cradle connector separately, there are two power supply paths of the portable device.

Hereinafter, a power supply of a conventional portable device will be described with reference to FIG. 1 is a circuit diagram of a conventional power supply.

The power supply device includes a first power input terminal 10, a first fuse 20, a diode 30, a second fuse 40, and a second power input terminal 20. The first power input terminal 10 is a terminal for inputting external power output from the adapter, and the second power input terminal 20 is a terminal for inputting external power output from the cradle.

The external power input to the first power input terminal 10 is applied to the converter input terminal through the first fuse 20, and is supplied to the portable device after voltage conversion.

The external power input to the second power input terminal 50 is applied to the converter input terminal through the second fuse 40 and the diode 30, and is supplied to the portable device after voltage conversion.

According to the related art as described above, the external power input to the first power input terminal 10 and the external power input to the second power input terminal 50 may collide.

Then, the power input to the second power input terminal 50 may be reversed to the first power input terminal 10, and if the metallic foreign material is in contact with the first power input terminal 10, the inside of the portable device There is a risk of short circuit. Therefore, in order to prevent such a risk, when the portable device is seated on the cradle, the first power input terminal 10 is designed to be positioned and covered by the contact surface of the cradle, thereby preventing contact with metallic foreign matter. In this case, the design is restricted.

In addition, due to the phenomenon of 'line drop' in the diode 30, unnecessary power is consumed and heat is generated.

The present invention has been made to solve the above problems, and an object of the present invention is to provide a plurality of paths for inputting external power to a portable composite device capable of generating, storing, and reproducing image data. The present invention provides a power supply device and a power supply method for a portable composite device that enables selective input between external power sources and prevents reverse flow of an input external power source.

According to the present invention for achieving the above object, the power supply device provided in the portable composite device capable of generating and storing the image data, and reproduce the stored image data, the first power input unit is a first external power input; A second power input unit to which a second external power source is input; And an input power switching unit operable to selectively apply any one of the first and second external power sources to the portable composite device.

The input power switching unit may include: a first switching unit configured to perform a switching operation so that the first external power is applied to the portable composite device; A second switching unit configured to perform a switching operation so that the second external power is applied to the portable composite device; And an input power selection unit configured to control the selected one of the first and second switching units to perform the switching operation when the first and second external power sources are input together.

The first switching unit may include: a first power supply switching unit configured to switch the first external power to the portable composite device; A first reverse power cut-off switching unit which switches to block the second external power from flowing backward to the first power input unit; And controlling the switching operation of the first power supply switching unit to be performed when the first external power is input, and controlling the switching operation of the first reverse power cut-off switching unit to be performed when the second external power is input. 1 switching control unit; preferably includes.

The first power supply switching unit and the first backflow power cut-off switching unit each include a FET transistor, and the source terminal of the FET transistor included in the first power supply switching unit and the first backflow power cut-off switching unit. Source terminals of the FET transistors may be interconnected.

The second switching unit may include: a second power supply switching unit configured to perform a switching operation so that the second external power is applied to the portable composite device; A second countercurrent power cut-off switching unit configured to switch to block the first external power from flowing back to the second power input unit; And controlling the switching operation of the second power supply switching unit to be performed when the second external power is input, and controlling the switching operation of the second countercurrent power cut-off switching unit to be performed when the first external power is input. It is preferable to include a; 2 switching control unit.

The second power supply switching unit and the second backflow power cut-off switching unit each include a FET transistor, and the source terminal of the FET transistor included in the second power supply switching unit and the second backflow power cut-off switching unit. Source terminals of the FET transistors may be interconnected.

The input power selector may control the second switching controller to stop the switching operation of the second power supply switching unit when the first external power is input.

The first external power may be directly input to the first power input unit, and the second external power may be input to the second power input unit through a predetermined external device.

In addition, the predetermined external device may be a cradle on which the portable composite apparatus is seated and capable of transferring the received second external power to the portable composite apparatus.

On the other hand, according to the present invention, it is possible to generate and store the image data, and reproduce the stored image data, and having a first power input unit for inputting a first external power and a second power input unit for inputting a second external power A power supply method of a portable composite device may include: a) receiving at least one of the first and second external power sources; b) if one of the first and second external power sources is input, applying the input external power to the portable composite device; And c) if both the first and second external power sources are input, applying any one selected to the portable composite device.

And, the step b), if the first external power is input, applying the input first external power to the portable composite device; And blocking the input of the first external power from flowing backward to the second power input unit.

In addition, the step b), if the second external power is input, applying the input second external power to the portable composite device; And blocking the input of the second external power from flowing backward to the first power input unit.

And, the step c), if both the first and the second external power is input, applying the first external power to the portable composite device; Blocking the second external power from being applied to the portable composite device; And blocking the first external power from flowing backward to the second power input unit.

The power supply method may further include: blocking the second external power from being applied to the portable composite device when the second external power is input while the first external power is being supplied to the portable composite device; And blocking the first external power from flowing backward to the second power input unit.

The power supply method may further include: blocking the first external power from being applied to the portable composite device when the second external power is input while the first external power is being supplied to the portable composite device; Applying the second external power source to the portable composite device; And blocking the reverse flow of the second external power to the first power input unit.

In addition, the first external power may be directly input to the first power input unit, and the second external power may be input to the second power input unit through a predetermined external device.

The predetermined external device may be a cradle in which the portable composite device is seated and may transmit the received second external power to the portable composite device.

Hereinafter, with reference to the drawings will be described the present invention in more detail.

Figure 2a is a perspective view showing the front and right side of the portable composite device according to the present invention. As shown in FIG. 2A, a front surface of the portable composite apparatus includes a lens unit 211 used for photographing a subject, a remote controller signal receiver 111 for receiving a remote controller signal, and an earphone terminal 113 for connecting earphones. Power supply cable connection terminal 117 is provided for receiving external power through a USB terminal 115 and a power supply (not shown) for serial communication with a PC or a printer.

In this way, the front portion of the portable composite device is provided with a terminal mainly used for connecting to an external device, the right side of the portable composite device photo button 231a for taking a still image and a battery for mounting a battery therein The cover 121 is provided. In addition, a microphone 271 for receiving a sound signal from the outside is provided on the upper surface of the portable composite device.

Figure 2b is a perspective view of the bottom surface of the portable composite device. As shown in FIG. 2B, a cradle connection terminal for receiving power and image signals through a tripod fixing unit 131 and a cradle (not shown) for mounting a tripod on a lower surface of the portable composite apparatus. 133 is provided.

Hereinafter, operation buttons provided on the outside of the portable composite apparatus will be described with reference to FIG. 2C. Figure 2c is a perspective view showing the back and left side of the portable composite device. For convenience of operation of the user, the operation button of the portable composite device, as shown in Figure 2c, is provided on the back of the portable composite device or the LCD panel 150.

As shown in FIG. 2C, a rear surface of the portable composite apparatus includes a zoom switch 231b for zooming in / zooming out the lens unit 211 and a shooting button 231c for capturing a video. ), An operation mode selection switch 231d for selecting an operation mode (storage / playback / power-off mode) of the portable composite device, a menu button 231e for displaying a menu screen on the LCD 243, and an LCD 243. A menu dial 231f is provided for moving the cursor to a specific menu on the menu screen displayed on the screen and selecting a menu in which the cursor is located.

In addition, the rear side of the portable composite apparatus is provided with a memory card engaging portion 143 and an indicator light 141 for mounting a memory card. The indicator light 141 is composed of a power indicator and a charging indicator. The power indicator emits light when the portable composite device is 'powered on', and the charging indicator light is orange when the portable composite device is being charged. Emits color light.

In addition, the LCD panel 150 coupled to change the position of the portable composite device has a mode button for displaying the LCD screen 243 and a menu screen on which the image and menu screen to be photographed and reproduced are displayed. (231g), rewind (◀◀) button 231h, fast forward (▶▶) button 231i, play / stop (▶ ∥) button 231j, and stop (■) button 231k are provided.

3 is an internal block diagram of a portable composite device. The portable composite apparatus includes a photographing unit 210, a National Television System Committee / Phase Alternation Line (NTSC / PAL) decoder 220, an operation unit 231, a second control unit 233, a flash memory 235, A display unit 240, a storage unit 250, a universal serial bus (USB) interface unit 261, a synchronous dynamic random access memory (SDRAM) 263, an audio signal processor 270, and a main control block 300 are provided. do.

The photographing unit 210 photoelectrically converts an optical signal incident through the lens into an electrical signal and performs a predetermined signal processing process on the converted signal. The photographing unit 210 performing such a function includes a lens unit 211, a lens driving unit 213, a charge coupled device (CCD) 215, and a correlated double sampler / auto gain controller / analaog- CDS / AGC / ADC. to-digital converter) 217.

The lens driver 213 drives the lens unit 211 under the control of the second control unit 233. Specifically, the lens driving unit 213 zooms in / zooms out the lens unit 211 and focuses the lens unit 211. It adjusts automatically, and controls the opening and closing amount of the aperture (not shown) provided in the lens unit 211.

The CCD 215 converts the optical image incident through the lens unit 211 into an electrical signal and outputs the electrical signal. That is, the optical image of the subject is formed on the optical surface of the CCD 215 by the lens unit 211, and the CCD 215 converts the optical image formed on the photosensitive surface into an electrical signal and scans horizontally and vertically. Output in the form of electrical signals in dimensions.

The CDS / AGC / ADC 217 removes noise from a signal output from the CCD 215 using a correlated double sampling circuit, and uses an auto gain control circuit. Adjust the gain so that the level of the signal remains constant and convert it to a digital signal using an A / D converter.

The NTSC / PAL decoder 220 converts an NTSC or PAL signal input through a video line input terminal (not shown) into a digital signal and delivers the digital signal to the main control block 300. NTSC or PAL is one of the standardized television outputs. NTSC is used in Korea and PAL is used in Europe.

The main control block 300 compresses a digital signal applied from the photographing unit 210, the NTSC / PAL decoder 220, and the USB interface unit 261 into data of a predetermined format and stores the data in the storage unit 250. In addition, the main control block 300 may extend the data stored in the storage unit 250 and apply it to the display unit 240. The data received from the audio signal processor 270 may be stored in the storage 250, and the stored data may be applied to the audio signal processor 270. In addition to the main control block 300 controls the overall operation in the device, it is made of a single chip for the miniaturization of the Z-Form.

The main control block 300 performing such a function includes a digital signal processor (DSP) 310, an optical detection module (ODM) 320, a multiplexer (330), a codec (340), and a graphical user (GUI). Interface (350), first controller 360, memory card interface 371, CF (Compact Flash) interface 373, DMA (Direct Memory Access) 375 and system bus 380 Equipped.

The DSP 310 performs predetermined signal processing on the digital signal applied from the photographing unit 210, and then applies the DSP 310 to the MUX 330 or the system bus 380. In addition, the DSP 310 separates the digital signal applied from the photographing unit 210 into a luminance (Y) signal and a chrominance (Crominance: C) signal and applies the ODM signal to the ODM 320.

The ODM 320 generates ODM data, which is control information, based on the Y signal and the C signal received from the DSP 310, and outputs the ODM data to the first controller 360. Specifically, the ODM data includes AE (Auto Exposure) data for optimizing the amount of light incident on the CCD 215, AF (Auto Focus) data for automatically focusing the focus lens, and color shift due to the color temperature of the light source. It includes AWB (Auto White Balance) data for automatic correction.

The MUX 330 applies either the output signal of the DSP 310 or the output signal of the NTSC / PAL decoder 220 to any one of the CODEC 340 and the GUI generator 350.

The CODEC 340 compresses the input data into a predetermined format and expands the compressed data again if necessary. Specifically, the CODEC 340 compresses the MPEG4 format when the input data is moving picture data, and compresses the JPEG data in the JPEG format when the input data is still picture data.

The GUI generating unit 350 stores graphic data such as a menu screen necessary for building a GUI environment, and the GUI generating unit 350 outputs an image output from the MUX 330 under the control of the first control unit 360. You can combine menu screens. The menu screen is a graphic screen provided for the user's convenience when selecting a function of the portable multi-function device.

The first control unit 360 is a 32-bit Reduced Instruction Set Computing (RISC) processor that controls the overall operation of the main control block 300. In detail, the first control unit 360 controls the operations of the CODEC 340 and the GUI generation unit 350, and converts the AE data and the AF data from the ODM data received from the ODM 320 to the second control unit 233. To pass.

In addition, the first controller 360 may interface with various external devices through the system bus 380. The system bus 380 includes a memory card interface 371 for interfacing with the memory card 251, a CF interface 373 for interfacing with the HDD 255 through the TIC 253, a PC or a printer as an external device. The USB interface unit 261, the DMA 375, and the audio signal processor 270 for interfacing with the control unit are connected.

The operation unit 231 is a user interface device for receiving operation commands related to function selection and operation control of the portable multi-device. The operation unit 231 has a photo button 231a, a zoom switch 231b, a shooting button 231c, an operation mode selection switch 231d, a menu button 231e, a menu dial 231f, and a mode button described with reference to FIG. 2C. 231 g and the like are provided.

The second control unit 233 receives an operation command related to function selection and operation control from the user through the operation unit 231 and transmits it to the first control unit 360. In addition, the second controller 233 controls the lens driver 213 based on the AE data and the AF data received from the first controller 360.

The flash memory 235 stores a system program necessary for the operation of the device, such as a booting program required by the first controller 360, and important data and applications to be stored even when the power is turned off.

The display unit 240 displays an image output from the main control block 300. The display unit 240 performing such a function includes an NTSC / PAL encoder 241 and a liquid crystal display (LCD) 243.

The NTSC / PAL encoder 241 converts the video signal output from the main control block 300 into an NTSC or PAL video signal and applies it to the LCD 243 and an external device TV.

The LCD 243 is a display device that displays an image received from the NTSC / PAL encoder 241.

The storage unit 250 stores image data received from the main control block 300. The storage unit 250 performing such a function includes a memory card 251, a TIC 253, and an HDD 255.

The memory card 251 is a recording medium for storing image data applied from the main control block 300 and is a type of a removable IC memory card that can be mounted / removed in a portable composite device.

The transition IC (TIC) 253 is used to provide a compact flash interface between the CF interface unit 373 and the HDD 255, and is highly versatile and has excellent compatibility. That is, the HDD 255 is converted into the compact flash interface through the TIC 253 and then connected to the main control block 300.

The HDD 255 is a recording medium that stores image data applied from the main control block 300.

The USB interface unit 261 performs an interface with a PC or a printer, which is an external device.

The SDRAM 263 functions as a buffer that stores data and the like necessary for the operation of the portable multi-device.

The audio signal processor 270 performs a predetermined signal processing process on the audio signal input from the outside and applies the signal to the main control block 300 and the predetermined signal processing on the audio signal received from the main control block 300. Perform the process and output to the external audio device. The audio signal processor 270 performing such a function includes a microphone 271 and an audio CODEC 273.

The microphone 271 converts an acoustic signal input from the outside into an electrical signal.

The audio CODEC 273 converts an analog signal input from the microphone 271 or an external audio device into a digital signal, compresses it into data of a predetermined format, and applies it to the main control block 300. In addition, the audio CODEC 273 expands the compressed data received from the main control block 300, converts the compressed data into an analog signal, and transmits the converted analog signal to an external audio device.

The power supply unit 200 receives power from the outside, and applies the received power to modules provided in the portable composite device or supplies the battery to a battery (not shown). As shown in FIG. 3, there are two paths through which the power supply unit 200 receives power from the outside, which will be described later.

Hereinafter, the cradle will be described in detail with reference to FIGS. 4A to 4C. Figure 4a is a perspective view showing the front of the cradle, Figure 4b is a perspective view showing the rear of the cradle, Figure 4c is a view showing a case where the portable composite device is mounted on the cradle.

As shown in Figure 4a, the front of the cradle 400, the support 410 for supporting the portable composite device corresponding to the main body, the power button 421 for selecting whether to power on / off, the LCD of the main body A menu button 423 for displaying a menu screen on the display 243, a remote control signal receiving unit 425 for receiving a remote control signal, connected to the cradle connecting terminal 133 of the main body, supplies power to the main body, and external devices It is provided with a main body connecting terminal 427 for transmitting an image received from.

Support 410 may be implemented in a transparent acrylic, one side of the transparent acrylic is in contact with the LED (not shown), the light emitted from the LED is projected to the transparent acrylic. LEDs can emit light of different colors, depending on the current mode. Specifically, when the portable composite device is in a power-on state, red light is emitted, when the portable composite device is being charged, orange light is emitted, and when charging is completed, blue light is emitted.

And, as shown in Figure 4b, the cradle 400 is connected to the power supply cable that is supplied with power through the battery slot 430, a power supply (not shown) for seating the battery when only charging the battery A terminal 441, an AV output terminal 443, a super video image output terminal 445, an AV input terminal 447, and a super video image input terminal 447 are provided.

Meanwhile, FIG. 4C illustrates a case in which the portable composite device is mounted on the cradle 400.

Hereinafter, the power supply unit 200 of the portable composite apparatus shown in FIG. 3 will be described in detail with reference to FIGS. 5 to 8. For convenience of understanding, in addition to the power supply unit 200, the cradle 400, the first adapter 510 and the second adapter 520, which are not provided in the portable composite device, are further illustrated. 5 is a detailed block diagram of the power supply unit 200 of FIG. 3.

Referring to FIG. 5, it can be seen that there are two paths through which the power supply unit 200 receives power from the outside. One is a path for directly receiving external power through the first adapter 510, and the other is a path for receiving external power through the second adapter 520 and the cradle 400.

The first adapter 510 converts an external AC power source (AC 100 to 220V) into DC 8.4V and outputs the power to the power supply unit 200 of the portable composite apparatus.

The second adapter 520 converts an external AC power source (AC 100 to 220V) into DC 8.4V and outputs the cradle 400.

The cradle 400 receives the DC power output from the second adapter 520 through the power supply cable connection terminal 441, and outputs it to the power supply unit 200 of the portable composite apparatus through the main body connection terminal 427. .

The power supply unit 200 receives a DC power output from the first adapter 510 or a DC power output from the cradle 400. The power supply unit 200 selects any one of the DC power sources that can be input and applies it to the modules provided in the portable composite device. The power supply unit 200 performing such a function includes a power supply cable connection terminal 117, a cradle connection terminal 133, an input power switching unit 280, and a DC / DC converter 290.

The power supply cable connection terminal 117 receives the DC power output from the first adapter 510 and transfers it to the input power switching unit 280.

The cradle connection terminal 133 receives the DC power output from the cradle 400 and transfers it to the input power switching unit 280.

The input power switching unit 280 selects any one of DC powers input through the power supply cable connection terminal 117 and the cradle connection terminal 133 and applies the selected DC power to the DC / DC converter 290. do.

In addition, the input power switching unit 280 blocks the DC power inputted through the power supply cable connecting terminal 117 to flow back to the cradle connecting terminal 133, the DC power input through the cradle connecting terminal 133. The backflow to the power supply cable connection terminal 117 is blocked.

The DC / DC converter 290 converts the DC power applied from the input power switching unit 280 into a predetermined DC voltage and applies it to the modules provided in the portable composite apparatus.

Hereinafter, the input power switching unit 280 will be described in detail with reference to FIG. 6. FIG. 6 is a detailed block diagram of the input power switch 280 of FIG. 5. For convenience of understanding, FIG. 6 further illustrates a power supply cable connection terminal 117, a cradle connection terminal 133, and a DC / DC converter 290 in addition to the input power switching unit 280.

Referring to FIG. 6, the input power switching unit 280 includes a first transient current blocking unit 281, a first switching unit 283, an input power selecting unit 285, a second transient current blocking unit 287, and A second switching unit 289 is provided.

The first transient current blocking unit 281 transfers the DC power input through the power supply cable connection terminal 117 to the first switching unit 283. On the other hand, when the transient current is input, the first transient current blocking unit 281 is blocked, thereby preventing the transient current from being transferred to the first switching unit 283.

The first switching unit 283 applies a DC power input through the first transient current blocking unit 281 to the DC / DC converter 290. In addition, the first switching unit 283 blocks the DC power output from the second switching unit 289 from flowing back to the first transient current blocking unit 281. The first switching unit 283 performing such a function includes a first reverse current blocking switch 283a, a first power supply switching unit 283b, and a first switching control unit 283c.

When the DC power is input to the power supply cable connection terminal 117, the first switching control unit 283c turns the first reverse current blocking switch 283a and the first power supply switching unit 283b into 'turn-on' (Turn). -On) '. On the other hand, when DC power is not input to the power supply cable connection terminal 117, the first switching controller 283c turns the first back-flow cutoff switching unit 283a and the first power supply switching unit 283b to 'turn-'. Turn-Off '.

The first reverse current blocking switch 283a applies the DC power input through the first transient current blocking unit 281 to the first switching controller 283c. This is to apply driving power to the first switching control unit 283c.

In addition, when the first reverse power cut-off switching unit 283a is 'turned on', the first reverse power cut-off switching unit 283a transfers the input DC power to the first power supply switching unit 283b.

When the first power supply switching unit 283b is 'turned on', the first power supply switching unit 283b applies the DC power received from the first reverse current blocking switch 283a to the DC / DC converter 290.

On the other hand, when the first power supply switching unit 283b receives the DC power output from the second switching unit 289 when it is 'turned off', the first power supply switching unit 283b applies it to the first switching control unit 283c. This is to apply driving power to the first switching control unit 283c.

In addition, when the first reverse power cut-off switching unit 283a is 'turned off', the DC power output from the first power supply switching unit 283b flows back to the first transient cut-off unit 281. Block it.

The second transient current blocking unit 287 transfers the DC power input through the cradle connection terminal 133 to the second switching unit 289. On the other hand, when the transient current is input, the second transient current blocking unit 287 is cut off to prevent the transient current from being transferred to the second switching unit 289.

The second switching unit 289 applies a DC power input through the second transient blocking unit 287 to the DC / DC converter 290. In addition, the second switching unit 289 blocks the DC power output from the first switching unit 283 from flowing back to the second transient current blocking unit 287. The second switching unit 289 performing the above function includes a second reverse current blocking switch 289a, a second power supply switching unit 289b, and a second switching control unit 289c.

When the DC power is input to the cradle connection terminal 133, the second switching controller 289c 'turns on' the second reverse current blocking switch 289a and the second power supply switching unit 289b. On the other hand, when the DC power is not input to the cradle connecting terminal 133, the second switching controller 289c 'turns off' the second reverse current cut-off switching unit 289a and the second power supply switching unit 289b. Let's do it.

The second countercurrent power cut-off switching unit 289a applies the DC power input through the second transient current blocking unit 287 to the second switching control unit 289c. This is to apply driving power to the second switching controller 289c.

In addition, when the second countercurrent power cut-off switching unit 289a is 'turned on', the second reverse current power cut-off switching unit 289a transfers the input DC power to the second power supply switching unit 289b.

When the second power supply switching unit 289b is 'turned on', the second power supply switching unit 289b applies the DC power received from the second reverse current blocking switch 289a to the DC / DC converter 290.

On the other hand, when the second power supply switching unit 289b is 'turned off', when the DC power output from the first switching unit 283 is input, the second power supply switching unit 289b applies it to the second switching control unit 289c. This is to apply driving power to the second switching controller 289c.

In addition, when the second reverse power cut-off switching unit 289a is 'turned off', the DC power output from the second power supply switching unit 289b flows back to the second transient cut-off unit 281. Block it.

When the DC power is input to both the power supply cable connection terminal 117 and the cradle connection terminal 133, the input power selector 285 is a DC / DC converter applied to the power supply cable connection terminal 117. Control to be applied to (290).

Specifically, when the DC power is input to the power supply cable connection terminal 117, the input power selector 285 controls the second switching controller 289c to control the second reverse power cut-off switching unit 289a and the second power. By controlling the power supply switching unit 289b to be 'turned off', the DC power input to the cradle connection terminal 133 is controlled so as not to be applied to the DC / DC converter 290.

Hereinafter, a circuit in which the input power switch 280 illustrated in FIG. 6 is specifically implemented will be described in detail with reference to FIG. 7. 7 is a circuit diagram of the input power switching unit 280 of FIG. In FIG. 7, the power supply cable connection terminal 117, the cradle connection terminal 133, and the DC / DC converter 290 are further illustrated in addition to the input power switching unit 280 for convenience of understanding.

The first transient current blocking unit 281 includes a fuse F1, and one end of the F1 is connected to the terminal 117b of the power supply cable connection terminal 117.

The first reverse power cut-off switching unit 283a includes a FET transistor Q1-1. The drain terminal of Q1-1 is connected to F1, and the gate terminal of Q1-1 is connected to the first switching control unit 283c. do.

The first power supply switching unit 283b includes a FET transistor Q1-2. The source terminal of Q1-2 is connected to the source terminal of Q1-1, and the gate terminal of Q1-2 is the first switching controller 283c. ).

The first switching controller 283c includes the BJT transistors Q3 and Q4 and the bias resistors R1, R2, and R3.

The base end of Q3 is connected to terminals 117a and R2 of the power supply cable connection terminal 117, the collector end is connected to R3, and the emitter end is grounded.

The base end of Q4 is connected to the collector end and R3 of Q3, and the collector end is connected to the gate end of Q1-1, the gate end of Q1-2, and R1, and the emitter end is grounded.

The second transient blocking unit 287 includes a fuse F2, one end of which is connected to the terminal 133b of the cradle connecting terminal 133.

The second reverse power cut-off switching unit 289a includes a FET transistor Q2-1, where the drain terminal of Q2-1 is connected to F2 and the gate terminal of Q2-1 is connected to the second switching control unit 289c. do.

The second power supply switching unit 289b includes a FET transistor Q2-2. The source terminal of Q2-2 is connected to the source terminal of Q2-1, and the gate terminal of Q2-2 is the second switching controller 289c. ).

The second switching controller 289c includes the BJT transistors Q5 and Q6 and the bias resistors R4, R5 and R6.

The base end of Q5 is connected to terminals 133a and R5 of the cradle connecting terminal 133, the collector end is connected to R6, and the emitter end is grounded.

The base end of Q6 is connected to the collector end and R6 of Q5, and the collector end is connected to the gate end of Q2-1, the gate end of Q2-2, and R4, and the emitter end is grounded.

The input power selector 285 includes a diode D. The positive terminal of D is connected to the base terminal of Q6, and the negative terminal of D is connected to the terminal 117a of the power supply cable connecting terminal 117. Connected.

In the present invention, the use of FET transistors suppresses the 'line drop' phenomenon and prevents the power supply from flowing back by interconnecting the source terminals of the FET transistors having the same characteristics.

Hereinafter, when DC power is input to only one of the power supply cable connecting terminal 117 and the cradle connecting terminal 133 or when DC power is input to both, the operation of the input power switching unit 280 is performed. This will be described in detail with reference to FIGS. 7 and 8. 8 is a flowchart provided to explain a power supply method of a portable multi-function device according to an embodiment of the present invention.

First, when the DC power is input only to the power supply cable connection terminal 117 (S610), the input DC power is the first through the first transient current blocking unit 281 and the first reverse current blocking switch 283a It is applied to the switching controller 283c, and the applied power is used as the driving power of the first switching controller 283c (S620).

Specifically, DC power input through the terminal 117b of the power supply cable connection terminal 117 is transferred to the drain terminal (node a1) of Q1-1 through F1, and applied to the source terminal (node a2) of Q1-1. Is passed to node a6.

The first switching controller 283c 'turns on' the first reverse current blocking switch 283a and the first power supply switching unit 283b (S630).

Specifically, when a DC power input jack is inserted into the power supply cable connecting terminal 117, the terminal 117a 'and the terminal 117c' are short-circuited, and as a result, the terminal 117a is grounded. Therefore, the base end (node a8) of Q3 is also grounded so that Q3 is 'turned off'. Since the DC power source applied to the node a6 applies a bias voltage to the base terminal (node a7) of Q4 through R3, Q4 is 'turned on'.

When Q4 is 'turned on', the gate terminals (node a4 = node a5) of Q1-1 and Q1-2 are in a 'Low' voltage state, and Q1-1 and Q1-2 are 'turned on'.

Therefore, the DC power input to the power supply cable connection terminal 117 is applied to the DC / DC converter 290 through the first reverse current cutoff switching unit 283a and the first power supply switching unit 283b (S640). ).

Specifically, the DC power delivered to the node a1 is applied to the input terminal (node c) of the DC / DC converter 290 through Q1-1 and Q1-2. Accordingly, the DC power input to the power supply cable connection terminal 117 is applied to the DC / DC converter 290.

The DC power output from the first power supply switching unit 283b is applied to the second switching control unit 289c through the second power supply switching unit 289b, and the applied power is the second switching control unit 283c. It is used as a driving power of (S650).

Specifically, the DC power output from the drain terminal of Q1-2 and applied to the drain terminal of Q2-2 is transferred to the source terminal (node b3 = node b2) of Q2-2. The DC power applied to the node b2 is transmitted to the node b6.

The second switching controller 289c 'turns off' the second reverse current cut-off switching unit 289a and the second power supply switching unit 289b (S660).

Specifically, since the DC power source applied to the node b6 applies a bias voltage to the base terminal (node b8) of Q5 through R5, Q5 is 'turned on'.

When Q5 is 'turned on', since the bias voltage is not applied to the base terminal (node b7) of Q6, Q6 is 'turned off'. When Q6 is turned off, the gate terminal (node b4 = node b5) of Q2-1 and Q2-2, which receives DC power delivered to node b3 through R4, becomes 'High' voltage state and Q2-1 and Q2-2 is 'turned off'.

Therefore, the DC power output from the second power supply switching unit 289b is blocked from flowing back to the cradle connection terminal 133 through the second transient blocking unit 281 (S670).

Specifically, when Q2-1 is 'turned off', DC power output from the source terminal (node b3 = node b2) of Q2-2 is not applied to the drain terminal (node b1) of Q2-1. Therefore, the DC power input to the power supply cable connection terminal 117 does not flow back to the cradle connection terminal 133.

On the other hand, when the DC power is input only to the cradle connecting terminal 133 (S680), the input DC power is the second switching control unit through the second transient current blocking unit 287 and the second back current blocking switch 289a 289c, the applied power is used as the driving power of the second switching controller 289c (S690).

Specifically, DC power inputted through the terminal 133b of the cradle connecting terminal 133 is transferred to the drain terminal (node b1) of Q2-1 through F2, and applied to the source terminal (node b2) of Q2-1 to the node. is passed to b6.

The second switching controller 289c 'turns on' the second reverse current blocking switch 289a and the second power supply switching unit 289b (S700).

Specifically, when the DC power input jack is inserted into the cradle connecting terminal 133, the terminal 133a 'and the terminal 133c' are short-circuited, and as a result, the terminal 133a is grounded. Thus, the base end (node b8) of Q5 is also grounded so that Q5 is 'turned off'. In addition, since the DC power source applied to the node b6 applies a bias voltage to the base terminal (node b7) of Q6 through R6, Q6 is 'turned on'.

When Q6 is 'turned on', the gate terminals (node b4 = node b5) of Q2-1 and Q2-2 are in a 'Low' voltage state, and Q2-1 and Q2-2 are 'turned on'.

Accordingly, the DC power input to the cradle connection terminal 133 is applied to the DC / DC converter 290 through the second reverse current cutoff switching unit 289a and the second power supply switching unit 289b (S710).

Specifically, the DC power delivered to the node b1 is applied to the input terminal (node c) of the DC / DC converter 290 through Q2-1 and Q2-2. Accordingly, the DC power input to the cradle connection terminal 133 is applied to the DC / DC converter 290.

The DC power output from the second power supply switching unit 289b is applied to the first switching control unit 283c through the first power supply switching unit 283b, and the applied power is the first switching control unit 283c. It is used as a driving power of (S720).

Specifically, the DC power output from the drain terminal of Q2-2 and applied to the drain terminal of Q1-2 is transferred to the source terminal (node a3 = node a2) of Q1-2. The DC power applied to the node a2 is transmitted to the node a6.

The first switching controller 283c 'turns off' the first reverse current blocking switch 283a and the first power supply switching unit 283b (S730).

Specifically, since the DC power source applied to the node a6 applies a bias voltage to the base terminal (node a8) of Q3 through R2, Q3 is 'turned on'.

When Q3 is 'turned on', since no bias voltage is applied to the base terminal (node a7) of Q4, Q4 is 'turned off'. When Q4 is turned off, the gate terminal (node a4 = node a5) of Q1-1 and Q1-2, which has received DC power applied to node a3 through R1, becomes a 'High' voltage state, so that Q1-1 and Q1 -2 is 'turned off'.

Therefore, the DC power output from the first power supply switching unit 283b is blocked from flowing back to the power supply cable connection terminal 117 through the first transient current blocking unit 281 (S740).

Specifically, when Q1-1 is 'turned off', DC power output from the source terminal (node a3 = node a2) of Q1-2 is not applied to the drain terminal (node a1) of Q1-1. Therefore, the DC power input to the cradle connection terminal 133 does not flow back to the power supply cable connection terminal 117.

Meanwhile, when DC power is input to both the power supply cable connection terminal 117 and the cradle connection terminal 133 (S750), the input DC powers are respectively the first switching controller 283c and the second switching controller 289c. The applied powers are used as driving powers of the first switching controller 283c and the second switching controller 289c, respectively (S760).

Specifically, the DC power input through the terminal 117b is applied to the source terminal (node a2) of Q1-1 and delivered to the node a6, and the DC power input through the terminal 133b is the source terminal (node b2) of Q2-1. Is sent to node b6.

The first switching controller 283c 'turns on' the first reverse current blocking switch 283a and the first power supply switching unit 283b (S770).

Specifically, Q3 is 'turned off' and Q4 is 'turned on' so that the gate terminals (node a4 = node a5) of Q1-1 and Q1-2 are in a 'Low' voltage state, Q1-2 is 'turned on'.

The input power selector 285 controls the second switching controller 289c so that the second reverse current cut-off switching unit 289a and the second power supply switching unit 289b are 'turned off', thereby connecting the cradle. The DC power input to the terminal 133 is controlled to not be applied to the DC / DC converter 290 (S780).

Specifically, since the negative terminal (node a8) of D is grounded, a voltage corresponding to the voltage drop (approximately 0.7 V) of D is applied to the base terminal (node b7 ') of Q6. Turn off. Since Q6 is 'turned off', the gate terminal (node b4 = node b5) of Q2-1 and Q2-2 is in a 'High' voltage state, and Q2-1 and Q2-2 are 'turned off'.

Therefore, only the DC power input to the power supply cable connection terminal 117 is applied to the DC / DC converter 290 through the first reverse current cut-off switching unit 283a and the first power supply switching unit 283b. (S790).

Hereinafter, when the DC power is also input to the power supply cable connection terminal 117 while the DC power is input to the cradle connection terminal 133, the operation of the input power switching unit 280 will be described in detail.

While the DC power is input to the cradle connection terminal 133, Q5 is 'turned off' and Q6 is 'turned on'. Since Q6 is 'turned on', Q2-1 and Q2-2 are 'turned on' so that DC power input to the cradle connection terminal 133 is applied to the DC / DC converter 290.

At this time, if DC power is also input to the power supply cable connecting terminal 117, the negative terminal (node a8) of D is grounded, and the voltage drop of D (about 0.7V) is applied to the base terminal (node b7 ') of Q6. Q6 is switched from the 'turn-on' state to the 'turn-off' state because a voltage corresponding to () is applied.

When Q6 switches to the "turn-off" state, since Q2-1 and Q2-2 also switch to the "turn-off" state, DC power input to the cradle connection terminal 133 is input to the DC / DC converter 290. This is not authorized. Instead, only the DC power input to the power supply cable connection terminal 117 is applied to the DC / DC converter 290.

On the other hand, when DC power is input to the cradle connection terminal 133 while the DC power is input to the power supply cable connection terminal 117, Q6 is maintained in the 'turn-off' state by D. Therefore, since the Q2-1 and Q2-2 also maintain the 'turn-off' state, DC power input to the cradle connection terminal 133 is not applied to the DC / DC converter 290, and the power supply cable connection terminal is not applied. Only the DC power input to 117 continues to be applied.

On the other hand, in the present embodiment, when DC power is input to both the power supply cable connection terminal 117 and the cradle connection terminal 133, only the DC power input to the electronic is applied to the DC / DC converter 290 Although described as, this is only an example. Therefore, in the above case, only the DC power input to the cradle connection terminal 133 may be applied to the DC / DC converter 290.

In this case, in Fig. 7, the (+) end of D should be connected to the base end (node a7) of Q4, and the (-) end should be connected to terminal 133a (node b8).

In addition, in the present embodiment, the portable composite apparatus has two power input units (connecting terminals) for receiving external power, and thus, two power supply paths are illustrated and described. However, this is only an example. Of course, the present invention can be applied to the case of three or more power supply paths.

As described above, according to the present invention, when there are a plurality of paths through which external power can be input to the portable composite apparatus, selective input between the plurality of external power sources is possible, thereby preventing collision of the plurality of external power sources. In addition, the backflow of the input external power source can be prevented, and the risk of short circuit inside the portable composite device is eliminated. In addition, the line drop phenomenon is suppressed to prevent unnecessary power consumption.

In addition, although the preferred embodiment of the present invention has been shown and described above, the present invention is not limited to the specific embodiments described above, but the technical field to which the invention belongs without departing from the spirit of the invention claimed in the claims. Of course, various modifications can be made by those skilled in the art, and these modifications should not be individually understood from the technical spirit or the prospect of the present invention.

Claims (17)

In the power supply device provided in the portable composite device capable of generating and storing the image data, and reproduce the stored image data, A first power input unit to which first external power is input; A second power input unit to which a second external power source is input; And Either one of the first and the second external power source is selectively applied to the portable composite device, and the second external power is blocked from flowing back to the first power input unit, and the first external power source is And an input power switching unit for blocking backflow to the second power input unit. The method of claim 1, The input power switching unit, A first switching unit configured to switch the first external power to the portable composite device; A second switching unit configured to perform a switching operation so that the second external power is applied to the portable composite device; And And an input power selector configured to control one of the first and second switching units to perform the switching operation when the first and second external powers are input together. . The method of claim 2, The first switching unit, A first power supply switching unit configured to switch the first external power to the portable composite device; A first reverse power cut-off switching unit which switches to block the second external power from flowing backward to the first power input unit; And A first control to control the switching operation of the first power supply switching unit when the first external power is input; and a control to perform the switching operation of the first reverse power cut-off switching unit when the second external power is input; Switching control unit; comprising a power supply. The method of claim 3, wherein The first power supply switching unit and the first backflow power cut-off switching unit are each provided with a FET transistor; And a source terminal of the FET transistor provided in the first power supply switching unit and a source terminal of the FET transistor provided in the first backflow interrupting switching unit are interconnected. The method of claim 3, wherein The second switching unit, A second power supply switching unit configured to switch so that the second external power is applied to the portable composite device; A second countercurrent power cut-off switching unit configured to switch to block the first external power from flowing back to the second power input unit; And A second controlling the switching operation of the second power supply switching unit to be performed when the second external power is input; and a second controlling of the switching operation of the second reverse power cut-off switching unit when the first external power is input; Switching control unit; comprising a power supply. The method of claim 5, The second power supply switching unit and the second backflow power cut-off switching unit are each provided with a FET transistor, And a source terminal of the FET transistor provided in the second power supply switching unit and a source terminal of the FET transistor provided in the second backflow interrupting switching unit are interconnected. The method of claim 5, The input power selector, And controlling the second switching control unit to stop the switching operation of the second power supply switching unit when the first external power is input. The method of claim 1, The first external power is directly input to the first power input unit, And the second external power is input to the second power input unit through a predetermined external device. The method of claim 8, The predetermined external device is a power supply device, characterized in that the portable composite device is seated, the cradle capable of transferring the input second external power to the portable composite device. A method of supplying power to a portable composite apparatus, comprising: generating and storing image data, reproducing the stored image data, and a first power input unit to which a first external power is input and a second power input unit to which a second external power is input. To a) receiving at least one of the first and second external power sources; b) if one of the first and second external power sources is input, applying the input external power to the portable composite device; c) if both the first and second external power sources are input, applying any one selected to the portable composite device; And d) blocking the second external power from flowing back to the first power input unit and blocking the first external power from flowing back to the second power input unit. The method of claim 10, B), If the first external power is input, applying the input first external power to the portable composite device; And And preventing the input of the first external power from flowing backward to the second power input unit. The method of claim 10, B), If the second external power is input, applying the input second external power to the portable composite device; And And blocking the input of the second external power from flowing backward to the first power input unit. The method of claim 10, C), When both the first and second external power sources are input, applying the first external power source to the portable composite device; Blocking the second external power from being applied to the portable composite device; And And blocking the first external power from flowing backward to the second power input unit. The method of claim 10, When the second external power is input while the first external power is applied to the portable composite device, blocking the second external power from being applied to the portable composite device; And And blocking the first external power from flowing backward to the second power input unit. The method of claim 10, If the second external power is input while the first external power is applied to the portable composite device, blocking the first external power from being applied to the portable composite device; Applying the second external power source to the portable composite device; And And blocking the second external power from flowing backward to the first power input unit. The method of claim 10, The first external power is directly input to the first power input unit, And the second external power is input to the second power input unit through a predetermined external device. The method of claim 16, The predetermined external device is a power supply method characterized in that the portable composite device is seated, the cradle capable of transferring the second external power input to the portable composite device.

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