KR20140042366A - Multi display device for smart phone - Google Patents

Abstract

The present invention relates to a multi-display device for a smartphone capable of transmitting the image data of the smartphone to an external monitor, executing the data for a touch position inputted from the external monitor by using wireless local area communication, and displaying the data for the touch position on the external monitor. The multi-display device comprises the smartphone which comprises a local area communication unit and the external monitor which displays the image data outputted from the smartphone through wired or local area communication and offers the data for the touch position inputted from a user to the smartphone through the local area communication. The smartphone is provided to mount an USIM card having a Zigbee module, thereby communicating with the external monitor. [Reference numerals] (100) Smartphone; (300) Zigbee USIM card; (400) USIM-Zigbee terminal; (500) MHL/VGA terminal; (600) Projector; (700) Remote control; (AA,CC,EE) Bluetooth/Zigbee; (BB,DD,FF) External monitor

Description

[0001] Multi-display device for smart phone [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention [0002] The present invention relates to a multiple display device, and more particularly, to a multiple display device for a smartphone capable of receiving input from an external monitor in a smartphone,

Published Japanese Patent Application No. 10-2012-0082223 discloses a digital TV interactive content remote control method and system using a smart phone.

In other words, it is a technology that uses a smart phone as a remote control for bidirectional contents of a digital TV by one-to-one mapping between a smartphone and a set-top box of a digital TV.

However, this technique can input various remote control signals to a digital TV using a smart phone, but the process is complex because a smart phone and a set-top box must be mapped using a digital TV network and a mobile communication network, Input from a TV (for example, touch data of a digital TV implemented by a touch screen, etc.) can not be input from a smart phone.

In addition, since a smart phone needs to use a mobile communication network to remotely control a digital TV, there is a problem of increasing traffic of a mobile communication network.

In addition, since an image of a smart phone having a limited display area can not be displayed on a digital TV, which is a large screen, a separate docking station must be provided, resulting in additional costs.

In order to solve the problems of the related art, the present invention provides a method for transmitting image data of a smartphone directly to an external monitor and inputting and receiving data on a touch position input from an external monitor using a short- It is another object of the present invention to provide a multiple display device for a smartphone which can display data on a touch position on an external monitor again.

According to another aspect of the present invention, there is provided a multi-

A smart phone equipped with a local communication unit;

And an external monitor for inputting and displaying image data output from the smartphone through wired or short distance communication and providing data on a touch position input from the user to the smartphone through local communication.

In addition, the smart phone is equipped with a universal subscriber identity module (USIM) card equipped with a Zigbee module in addition to a short-distance communication method using Bluetooth and Wi-Fi, and performs short-range communication with an external monitor.

According to the present invention, image data input from a smart phone is displayed on an external monitor, and data on a touch position input from an external monitor is supplied to a smart phone using a local communication network, There is a straightforward advantage.

In addition, since a plurality of frame buffer drivers output a plurality of image data from a smart phone, independent images can be displayed on a plurality of external monitors.

In addition, there is an advantage in that a short distance communication can be performed using a low-power occupancy module not implemented in a smart phone.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a view showing various implementations of a multi-display device for a smartphone of the present invention.
2 is a diagram showing a terminal structure of a general UICC;
3 is a diagram showing a wiring structure between a UICC and an occupancy module;
FIG. 4 is a diagram showing a data transmission / reception relationship between a UICC and an occupancy module; FIG.
5 is a diagram showing a transmission / reception structure by software between a UICC and a location module.
6 is a diagram showing a wiring structure between a UICC and a USB interface module.
FIG. 7 is a view showing a structure of a gender having an in-house module mounted thereon;
8 is a block diagram of a typical Android-based smartphone software.
Figure 9 shows a structure for display in a general application.
10 illustrates a structure of an application for multiple displays of the present invention.

The present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 shows various embodiments of the present invention. In FIG. 1, a solid line shows a signal transmission state by a wire, and a dotted line shows a wireless transmission state by a short distance communication.

1 (a) is a block diagram illustrating a method of displaying USB image data of the smartphone 100 on the external monitor 200 by connecting the smartphone 100 and the external monitor 200 to the USB, Data is transmitted to the smartphone 100 via a separate USB port or a Bluetooth or Wifi or Zigbee as a short distance communication means.

The external monitor 200 is a bidirectional USB monitor in which a touch input, that is, a touch screen, is implemented. The external monitor 200 provides data on the input touch position to the smartphone 100 via Bluetooth or a satellite, And the USB image data is output to the external monitor 200 via the USB again.

When the external monitor 200 does not have a short-range wireless communication function, data on the touch position is converted into a short-range wireless communication signal through the USB-Bluetooth / Wi-Fi gender 800 and then provided to the smartphone 100.

Currently, most of the current smartphone 100 has only the Bluetooth function, and when it performs the short distance communication through Bluetooth, a lot of power consumption is consumed.

In order to solve such a disadvantage, in the present invention, it is possible to communicate between the external monitor 200 and the smartphone 100 through a low cost local communication means.

Accordingly, in the present invention, the GPS module is mounted on the USIM card inserted in the smartphone 100 so as to enable direct communication between the smartphone 100 and the external monitor 200.

The USIM card is a universal user identification module that has a function of storing personal information and data of a user who uses a mobile phone. A UICC standard circuit is implemented as a UICC. The UICC includes a CPU, a ROM, a RAM, an EEPROM, / O circuit.

In addition, an application program or other data can be stored as long as the capacity of the memory permits.

In the present invention, touch location data received from the external monitor 200 is transmitted to the USIM card by a short distance wireless (WAN) connection by connecting a UICC with a UICC module and connecting the wireless input / output terminal (SWIO) The communication data is received from the position module and transmitted to the smartphone 100 through the UICC and the image data output from the smartphone 100 is transmitted to the external monitor 200 through the UICC and the position module.

Of course, in the smartphone 100, USB image data is output to the external monitor 200 via USB, and the touch position data input from the external monitor 200 can be transmitted to the smartphone 100 through the position module and the UICC There will be.

The communication software is stored in an application form in the microcomputer of the outdoor module or the CPU or the smartphone 100 of the UICC so that the communication protocol can be processed.

FIG. 2 is a diagram showing a standard terminal of a UICC, a smart card circuit mounted on a general USIM card. UICC is responsible for all the personal data of the middle level and security and integrity in a manner adopted by both sides of the GSM and UMTS (CDMA) And generally has several hundred kbytes of storage capacity.

The UICC includes a power supply terminal C1, a reset terminal C2, a clock terminal C3, a ground terminal C5, a single wire protocol (SWP) terminal C6, an input / output terminal C7, (C4) and (C8). In recent years, the optional terminals C4 and C8 have been allocated to the USB terminal, and the USB interface has been extended to provide a 12Mbps USB interface.

Here, the SWP terminal (C6) is defined to enable half-duplex data communication, and is defined for an interface of a contactless front-end (CFL) device.

Accordingly, in the present invention, the SWP terminal C6 is connected to the GPS module, and the GPS communication with the external monitor 200 is enabled through the USIM card.

3 is a diagram showing a connection relationship between the UICC 310 and the GPS module 320 mounted on the USIM card. The power terminal C1 of the UICC 310 is connected to the power terminal Vcc of the GPS module 320, And the ground terminal C5 is also connected to the ground terminal Gnd of the directivity module 320. [

In addition, the SWP terminal C6 is connected to the wireless transmitting / receiving terminal SWIO of the satellite module 320. [

UICC is a standardized specification and operates by its own software for personal information authentication and telephone number recording used in a smart phone. However, in order to perform data communication with the geo-module 200 as in the present invention, Should be implemented.

4, the UICC 310 is set as a slave and set as a master of the geo-module 320. When data is transmitted from the geo-module 320 to the UICC 310, the wireless transmission / reception terminal SWIO And transmits data in the form of a current pulse when transmitting data from the UICC 310 to the GPS module 320. [

As shown in FIG. 5, communication software can be implemented in the UICC 310 to communicate with the position module 320. The physical layer at the bottom is a serial communication method between the SWP terminal and the SWIO terminal. Exchange of APDUs is performed between the APDU processing unit 311 of the UICC 310 and the HDLC (High Level Data Link Control) of the geo-module 320 in the transport layer, which is the upper layer.

As a result, an application for software communication, that is, software, may be executed by the CPU of the UICC 310, or alternatively may be implemented as an application in the microcomputer of the position module 320 or the smartphone 100.

6 is a diagram showing another example in which USB terminals IC_DM ((IC_DM)) of the directivity USB module 330 are used as IC-USB data signals in which USB 2.0 is modified by using the option terminals C4 and C8 allocated to the USB terminals IC_DP).

Of course, the power supply terminal C1 and the ground terminal C5 of the UICC 310 are connected to the power supply terminal IC_VDD and the ground terminal GND of the directivity USB module 330, respectively.

At this time, only the signal of the physical layer matches the IC-USB signal.

As shown in FIG. 7, the touch position data received through the position-and-space circuit 410 may be transmitted to the smart (smart) terminal via the microcomputer 420 via a separate USB port, The USB image data output from the smartphone 100 can be transferred to the external monitor 200 through the navigator 400. [

That is, since only one USB terminal is usually implemented in the smartphone 100, when the USB terminal is used in the MHL mode between the external monitor 200 and the smartphone 100, communication via the direct gender is impossible, If the smartphone 100 has a separate USB port. When the external monitor 200 separately has a USB port for transmitting touch data, the smartphone 100 can be connected only when there is a separate USB port.

If the external monitor 200 sends only touch data to the USB signal and the smartphone 100 can not receive USB data at the same time because only the USB / MHL port is connected to the external monitor 200, the USB-Bluetooth / WiFi- (200) to convert the signal into a short distance wireless signal and connect it to a smartphone.

1B is a block diagram illustrating a mobile high definition link (MHL) image data output from the smartphone 100 to an external monitor 200 constituted by a general monitor capable of touch input, The MHL / VGA gender 500 is provided between the smartphone 100 and the external monitor 200 when the position data is received by the smartphone 100 using short-range communication such as Bluetooth or public service, The VGA gender 500 converts the MHL image data into VGA image data and outputs the image data to the external monitor 200.

1 (a), the touch position data of the external monitor 200 may be connected to the USIM card 300 or the navigator 400, which is connected to the wired via USB or by using the local communication, And provides it to the smartphone 100.

If the external monitor 200 sends only touch data to the USB signal and the smartphone 100 can not receive USB data at the same time because only the USB / MHL port is connected to the external monitor 200, the USB-Bluetooth / WiFi- (200) to convert the signal into a short distance wireless signal and connect it to a smartphone.

Accordingly, the smartphone 100 executes the program by reflecting the input signal, and outputs the MHL image data corresponding thereto.

1C shows the MHL image data output from the smartphone 100 to an external monitor 200 configured as a bi-directional touch smart monitor capable of touch input, and the touch position data of the external monitor 200 uses USB And is received by the smartphone 100 through a wired connection or by a short distance communication such as Bluetooth or satellite service.

In order to input touch data to the smartphone 100 via the USB, the smartphone 100 must have a separate USB port in addition to the USB / MHL port.

Of course, when the external monitor 200 sends only touch data to the USB signal and the smartphone 100 can not receive USB data at the same time because of the USB / MHL port alone, the USB-Bluetooth / WiFi- (200) to convert the signal into a short distance wireless signal and connect it to a smartphone.

The smart monitor can directly display the MHL image data output from the smartphone 100. Since the USB terminal is being used as the MHL terminal when the MHL image data is being transmitted to the external monitor 200, The touch location data is input from the smartphone 100 using the short distance communication.

Since the MHL signal output from the smartphone 100 typically shares a signal with the USB terminal, the MHL image data is output to the external monitor 200 through the USB terminal provided in the smartphone 100. [

1 (a), the touch position data output from the external monitor 200 using the local communication is input via the USIM card 300 or the navigator 400 on which the position module is mounted, (100).

When the USB terminal is additionally provided in the smartphone 100 so that MHL image data and USB data can be processed at the same time, the touch position data of the external monitor 200 is directly transmitted to the smart phone 100).

Accordingly, the smartphone 100 executes the program by reflecting the input signal, and outputs the MHL image data to the external monitor 200.

1D is a diagram illustrating an example in which the projector 600 is connected to an external monitor and the MHL image data output from the smartphone 100 is provided to the projector 900 to implement a large screen.

In this case, since the touch function can not be implemented on the large screen to be displayed, the position data of the cursor and the execution command are input through the remote controller 700 capable of direct communication. The output signal of the remote controller 700 includes Is input to the USIM card 300 or the navigator 400 and provided to the smartphone 100.

Accordingly, the smartphone 100 executes the program by reflecting the input signal, and outputs the MHL image data to the projector 600.

Meanwhile, in order to support multiple displays in the smartphone 100 and to display independent screens on a plurality of external monitors, the smartphone 100 is provided with a plurality of frame buffer drivers.

FIG. 8 is a view showing a configuration example of a general Android-based smartphone application. The 'Window Manager' of the Application Framework is involved in the display, the 'Surface Manager' is involved in the Libraries, and the 'Display Driver' do.

An application can have multiple 'surfaces' or pictures, and there can be multiple applications at the same time.

However, since the current Android operating system assumes only one display device, even if there are a plurality of 'Surface' as shown in FIG. 9, 'Surface Flinger' combines them and outputs them to one frame buffer, The display is made by calling the driver.

Since this structure does not allow multiple displays, the present invention modifies Libraries and Linux Kernel for multiple displays as shown in FIG.

For multiple displays, Linux Kernel has multiple frame buffer drivers. At the Libraries level, 'Sugface Flinger' writes image data to be displayed on multiple frame buffer drivers according to the needs of the application.

At this time, the display mode is set by activating the environment setting program on the smartphone 100. In this case, a mode for outputting the screen of the smartphone itself or multi-display is set, and in case of multiple displays, .

100: Smartphone 200: External monitor
300: USIM card 310: UICC
320: Position module 400: Position gender
500: MHL / VGA Gender 600: Projector
700: Remote control

Claims (12)

A smart phone equipped with a local communication unit;
And an external monitor configured to receive and display image data output from the smart phone through wired or short-range communication, and to provide data on a touch location input from the user to the smart phone through short-range communication. .
The multi-display device of claim 1, wherein the smartphone is equipped with a Universal Subscriber Identity Module (USIM) card equipped with a Zigbee module and is communicative to an external monitor.
The multi-display device for a smartphone according to claim 1, wherein the smartphone is equipped with a gantry mounted with a position module, and communicates with an external monitor in a short distance.
The multi-display apparatus for a smartphone according to claim 1, wherein an MHL / VGA gender is included between the smartphone and the external monitor to convert MHL image data into VGA image data.
The multi-display device of claim 1, wherein the smartphone further comprises a separate USB port to be connected to an external monitor.
The smartphone according to claim 1, wherein the external monitor and the smartphone are provided with a USB-Bluetooth / WiFi gender which converts the USB signal output from the external monitor into a Bluetooth or Wi-Fi wireless signal and provides it to the smartphone. Multiple display device.
A smart phone equipped with a local communication unit;
A projector for receiving and displaying image data output from the smartphone through wired or short-range communication;
And a remote controller for providing a control signal of a screen displayed through short-range communication to the smart phone by short-range communication.
The multi-display device for a smartphone according to claim 7, wherein the smart phone is equipped with a USIM card equipped with a direct-by module.
The multi-display apparatus for a smartphone according to claim 7, wherein the smartphone is equipped with a gender equipped with a direct-visibility module to communicate with an external monitor.
The USIM card according to claim 2 or 8, wherein the USIM card is equipped with a Zigbee module to set a Universal Integrated Circuit Card (UICC) as a slave, the UIC module as a master, and the UICC of the UICC. A multi-display device for a smartphone, comprising a single wire protocol (SWP) terminal, a power terminal, and a ground terminal, respectively, connected to a wireless input / output terminal (SWIO), a power terminal, and a ground terminal of a GUID module.
The USIM card according to claim 2 or 8, wherein the USIM card is equipped with a Zigbee module to set a Universal Integrated Circuit Card (UICC) as a slave, the UIC module as a master, and the UICC of the UICC. A multi-display device for a smartphone, comprising: a USB terminal, a power terminal, and a ground terminal respectively connected to a USB terminal, a power terminal, and a ground terminal of a GUIB module.
The multi-display apparatus for a smartphone according to claim 1, wherein the smartphone is provided with a plurality of frame buffer drivers to output a plurality of image data.

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