WO2011094959A1 - Electronic device with dual-role - Google Patents

Abstract

An electronic device with dual-role is disclosed. The device comprises an X86 system and an ARM (Advanced RISC Machines) system. The X86 system comprises an OTG (On-the-Go) sub-system, the ARM system is electrically connected with the OTG sub-system of the X86 system.

Description

 Dual mode electronic device

Technical field

 The utility model relates to a dual-mode electronic device, in particular to a dual-mode electronic device using an x86 architecture system and an ARM architecture system. Background technique

 With the development of technology, the current x86 architecture system and ARM architecture system are more and more widely used. However, due to the different system architectures of the two, the communication between the two is inconvenient, and it is often necessary to include a complete number of components, which correspondingly cause repeated investment and increase the volume of the product, making the integration between the two difficult. . Utility model content

 In view of the inconvenient communication and high integration cost of the existing x86 architecture system and the ARM architecture system, the utility model provides a dual-mode electronic device with an organic integrated x86 architecture system and an ARM architecture system.

 A dual mode electronic device comprising an x86 architecture system and an ARM architecture system, the x86 architecture system comprising an OTG (on-the-go) subsystem, the ARM architecture system and the x86 architecture system The OTG subsystem is electrically connected.

 As a further improvement of the above dual mode electronic device, the x86 architecture system further includes a first motherboard, and the OTG subsystem is disposed on the first motherboard.

 As a further improvement of the above dual mode electronic device, the x86 architecture system further includes a first motherboard, and the 0TG subsystem is disposed on the first motherboard.

 As a further improvement of the above dual mode electronic device, the x86 architecture system further includes an electronic component electrically coupled to the first motherboard.

 As a further improvement of the above dual mode electronic device, the electronic component is a magnetic head hard disk or a solid state hard disk.

 As a further improvement of the above dual mode electronic device, the electronic component is a wired network adapter or a wireless network adapter.

As a further improvement of the above dual mode electronic device, the ARM architecture system includes a second motherboard And the ARM architecture CPU, the second motherboard and the ARM architecture CPU are electrically connected, and the ARM architecture CPU only drives the ARM architecture system.

 As a further improvement of the above dual mode electronic device, the second main board is electrically connected to the electronic component through the OTG subsystem.

 As a further improvement of the above dual mode electronic device, the x86 architecture system further includes a first display screen, the first display screen being a liquid crystal display screen or an organic electroluminescent display screen.

 As a further improvement of the above dual mode electronic device, the ARM architecture system is an e-book system. As a further improvement of the above dual mode electronic device, the electronic book system further includes a second display screen, the second display screen being an electrophoretic display screen, an electromagnetic display screen or a touch display screen.

 The dual mode electronic device of the present invention organically integrates the x86 architecture system and the electronic book system of the ARM system architecture, and part of the key resources of the x86 architecture system can be shared with the electronic book system. The e-book system of the dual-mode electronic device thus breaks through the storage capacity limitation of the conventional e-book, and has a huge amount of book storage space. Further, the second display screen of the dual-mode electronic device adopts an electrophoretic display screen or an electromagnetic display screen, which can reduce eye fatigue caused by long-time reading, and protects vision, especially protecting children's vision. Very effective positive effect. Further, the e-book system uses the second CPU of the ARM system architecture as a main controller, and is specifically used to drive the e-book system, so that the e-book system has the advantage of low power consumption.

 In summary, the dual-mode electronic device of the present invention has the advantages of an organic integrated x86 architecture system and an ARM architecture system and key system resource sharing. DRAWINGS

 The drawing is a schematic diagram of main functional modules of a preferred embodiment of the dual mode electronic device of the present invention. detailed description

 The dual mode electronic device of the present invention will be described below with reference to the accompanying drawings.

Please refer to the accompanying drawings, which are schematic diagrams of main functional modules of a preferred embodiment of a dual mode electronic device of the present invention. The dual mode electronic device 100 includes an x86 architecture system 2 and an ARM (Advanced Reduced Instruction Set Machine) architecture system. 3. The x86 architecture system 2 is a general architecture, which is an x86 laptop architecture, including a first central processing unit (CPU) 20, a first motherboard 22, a first display screen 24, a data storage device 26, and an OTG (on- The-go) subsystem 28. The x86 architecture system 2 is described by Driven by a CPU 20, the first CPU 20 is a central processor designed for the x86 architecture, such as a variety of commercially available CPUs produced by Intel ^(TM ). The first CPU 20 may be packaged with the first motherboard 22 or may be separated from the first motherboard 22, that is, the first CPU 20 may be plugged into the first motherboard 22. The CPU socket (not shown) can also be pulled out from the CPU socket. The first motherboard 22 includes a plurality of other interfaces in addition to the CPU socket, such as a USB interface (not labeled), a VGA interface (not labeled), a DVI interface (not labeled), an HDMI interface (not labeled), and an IDE interface. (not shown), SATA interface (not labeled), and OTG interface (not labeled), etc., so that a plurality of devices are electrically connected to the first motherboard 22.

 The first display screen 24 is an internal screen of the dual-mode electronic device 100, and the first display screen 24 may be a liquid crystal display (LCD) or an organic electroluminescent display (OLED), which may be The VGA interface or the DVI interface is electrically connected to the first main board 22, and the first CPU 20 can drive the first display screen 24 through the first main board 22.

 The data storage device 26 provides a data storage function for the dual-mode electronic device 100, which may be a head-mounted hard disk (MHD) or a solid-state disk (SSD), and its storage capacity may be 40G to 720G, or even higher, so that it can be stored. A large amount of data such as videos, pictures, software programs, and books. The data storage device 26 can be electrically connected to the first motherboard 22 through the IDE interface or the S ATA interface, and the first CPU 20 can access the data storage device through the first motherboard 22 26 performs control operations such as reading and writing data.

 The ARM architecture system 3 is integrated with the x86 architecture system 2 in the dual mode electronic device 100, and includes a second CPU 30, a second motherboard 32, and a second display screen 34. The second CPU 30 is electrically connected to the second motherboard 32 and drives the ARM architecture system 3 through the second motherboard 32. In the present embodiment, the ARM architecture system 3 is an e-book system, and of course, it can be extended to applications other than e-books. The second CPU 30 is only used to drive the ARM architecture system 3, which is an ARM (Advanced Reduced Instruction Set Machine) architecture processor, as a 32-bit reduced instruction set processor architecture, which has low power consumption and Low cost and other characteristics. Therefore, the ARM architecture system 3 has the advantages of low power consumption and low cost.

The second main board 32 is electrically connected to the OTG subsystem 28. The OTG subsystem 28 can serve as a connection channel in the x86 architecture system 2 and the ARM architecture system 3, so that data can be exchanged between the two. That is, the dual mode electronic device 100 of the present embodiment uses the OTG subsystem 28 in the x86 architecture system 2, and then the ARM architecture system 3 passes the OTG subsystem 28 and the x86 architecture. System 2 is electrically connected such that the ARM architecture System 3 can share a number of electronic devices with the x86 architecture system 2 through the OTG subsystem 28, such as the data storage device 26, SD card, wired network adapter, and wireless network adapter.

 As described above, the ARM architecture system 3 shares the numerous electronic devices of the x86 architecture system 2, such as the data storage device 26, through the OTG subsystem 28. That is, the second CPU 30 of the ARM architecture system 3 can perform operations such as reading, writing, and the like on the data storage device 26 through the OTG subsystem 28.

 The second display screen 34 is electrically connected to the second main board 32, and the second CPU 30 drives the second display screen 34 through the second main board 32 to serve as the main body of the ARM architecture system 3. display screen. The second display screen 34 can employ an electrophoretic display screen or an electromagnetic display screen, which can make the reader read for a long time, and the degree of eye fatigue is moderated to the extent that the general liquid crystal display screen brings. In a further improved design, the second display screen 34 can also adopt a touch display screen.

 In the dual-mode electronic device 100 of the present invention, the x86 architecture system 2 and the ARM architecture system 3 are organically integrated, instead of a simple system overlay, and the ARM architecture system 3 can pass the OTG sub- System 28 shares the numerous resources of the x86 architecture system 2, saving on component recurring costs and a significant increase in product size. Further, the second display screen 34 adopts an electrophoretic display screen or an electromagnetic display screen, which can reduce eye fatigue caused by long-time reading, and has a very effective positive effect for protecting vision, especially protecting children's vision. In addition, the second CPU 30 has the characteristics of low power consumption and low cost, so the ARM architecture system 3 has the advantages of low power consumption and low cost.

 In summary, the dual-mode electronic device 100 of the present invention has the advantages of an organic integrated x86 architecture system 2 and an ARM architecture system 3 and key system resource sharing.

 The dual-mode electronic device 100 of the present invention can be applied not only to the organic integration of a notebook computer and an e-book, but also to a dual-mode system in which a plurality of x86 architecture systems and an ARM architecture system are mixed, such as MID (mobile internet) Device) product.

 The above is only a preferred embodiment of the present invention, and is not intended to limit the present invention. For those skilled in the art, various modifications and changes can be made in the present invention. Any modifications, equivalent substitutions, improvements, etc. made within the spirit and principles of this new utility shall be covered by this new type of protection.

Claims

Rights request

A dual-mode electronic device, comprising an x86 architecture system, wherein: the x86 architecture system comprises an OTG (on-the-go) subsystem, the dual-mode electronic device further comprising an ARM architecture system, the ARM The architecture system is electrically coupled to the 0TG subsystem of the x86 architecture system.

 2. The dual mode electronic device of claim 1, wherein: the x86 architecture system further comprises a first motherboard, and the 0TG subsystem is disposed on the first motherboard.

 3. The dual mode electronic device of claim 2, wherein: the x86 architecture system further comprises an electronic component, the electronic component being electrically coupled to the first motherboard.

 4. The dual mode electronic device according to claim 3, wherein: said electronic component is a magnetic head hard disk or a solid state hard disk.

 5. The dual mode electronic device of claim 3, wherein: the electronic component is a wired network adapter or a wireless network adapter.

 The dual-mode electronic device according to claim 3, wherein: the ARM architecture system comprises a second motherboard and an ARM architecture CPU, and the second motherboard and the ARM architecture CPU are electrically connected, the ARM The architecture CPU only drives the ARM architecture system.

 7. The dual mode electronic device of claim 6, wherein: the second motherboard is electrically connected to the electronic component through the OTG subsystem.

 8. The dual mode electronic device of claim 1, wherein: the x86 architecture system further comprises a first display screen, the first display screen being a liquid crystal display screen or an organic electroluminescent display screen.

 9. The dual mode electronic device of claim 1 wherein: said ARM architecture system is an e-book system.

 10. The dual mode electronic device according to claim 9, wherein: the electronic book system further comprises a second display screen, wherein the second display screen is an electrophoretic display screen, an electromagnetic display screen or a touch display screen .