KR930009744B1 - Memory card for portable electronic system - Google Patents

Abstract

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Description

Memory Cards for Portable Electronic Devices

1 is a perspective view showing the configuration of a laptop-type personal computer according to the first embodiment of the present invention.

2 is a plan view showing the configuration of the memory card according to the first embodiment.

3 is a perspective view showing the configuration of a laptop-type personal computer according to a second embodiment of the present invention.

4 is a block diagram showing a circuit configuration of a laptop personal computer according to the embodiment of FIG.

5 is a block diagram showing a configuration of a peripheral circuit of the memory card unit according to the second embodiment.

6 is a flowchart for explaining the operation according to the second embodiment.

* Explanation of symbols for main parts of the drawings

1: case unit 2: keyboard

3: flat panel display 3a: display panel

4 knob 5 connection member

6, 16: memory card unit 6a: card slot

7: FDD 8, 18: memory card

10, 20, 30: connector 11: high potential power terminal

12: memory circuit

The present invention relates to a memory card for use in a portable electronic device such as a laptop type personal computer or a word processor.

In recent years, portable electronic devices such as laptop type personal computers or word processors have been developed. In such a device, a device having a memory card unit other than, for example, a floppy disk device (FDD) has been developed as an external storage device. In such a device, a memory card unit is held in the apparatus main body, and a memory card used as a storage medium is inserted to function as an external storage device. The memory card is composed of, for example, a card base of a plate-like member made of plastic. In this card base, a memory circuit composed of an integrated circuit (LSI) is provided. At the distal end of the card base, a plurality of terminals (connectors composed of contact holes) are electrically connected to the memory circuit.

The memory card unit has a box-type case for storing a memory card inserted from a card slot provided in a case unit constituting the apparatus main body. The box-shaped case is provided with connectors corresponding to a plurality of terminals of the memory card. The connector is electrically connected to a circuit (external memory control circuit) of the printed circuit board, and electrically connects the memory card and the printed circuit board.

By the way, when inserting a memory card into a memory card unit, it may insert back to a card slot with the front and back reversed. Even when such an abnormal insertion is made, the plurality of terminals formed at the front end of the memory card are electrically connected to the connector of the unit. However, when each terminal of the reversely inserted memory card is connected to each terminal of the connector of the unit, it is not connected to each terminal of the corresponding connector which is set in advance, but is connected to each separate terminal. Thus, for example, an abnormal circuit constituted by connecting the high potential power terminal of the connector and the data input / output terminal of the memory card is configured. When such an abnormal circuit is configured, an abnormal current flows into the memory circuit of the memory card or the circuit on the apparatus main body (for example, the data processing circuit installed on the printed circuit board) so that one side of the memory circuit or the circuit on the apparatus main body or Obstacles may occur on both sides.

On the other hand, in the device having the above-described memory card unit, the memory storage capacity of the memory card is considerably smaller than the disk used for FDD, for example. This makes it practically ineffective to use a memory card as an external storage medium instead of an FDD disk. The memory card is used only in a field suitable for a small amount of storage, and its use conditions are restricted.

SUMMARY OF THE INVENTION An object of the present invention is that in a portable electronic device such as a personal computer having a memory card unit, even when the memory card is inserted back into the unit, a failure occurs in one or both of the memory circuit of the memory card or various circuits of the device An object of the present invention is to provide a device that can reliably prevent a situation.

It is still another object of the present invention to use a memory card as a relatively large amount of external storage medium and to make a practically excellent external storage system.

The memory card of the present invention comprises a card base constituting a card body and having a memory circuit; Data input / output connected to the memory circuit by electrically connecting the memory circuit and an external device, provided on a flat surface of the tip end of the card base connected to the external device, and having a power supply terminal connected to the memory circuit as a center. Each of the terminal, the address terminal, and the terminal for the control signal line is provided with connector means having respective terminals arranged symmetrically.

In the case of such a memory card, when the card is reversely inserted with the front and back sides of the memory card reversed, each terminal provided in the card is always connected to each terminal preset in advance with respect to the connector of the external device. Therefore, in the case of reverse insertion, it is possible to prevent a situation in which each terminal installed on the card is connected to each terminal of an abnormal connector and constitutes an abnormal circuit.

Moreover, the control unit which performs the operation control of the apparatus of this invention; A case unit constituting a main body of the apparatus and incorporating the control unit; A plurality of memory card units arranged inside the case unit to respectively accommodate a plurality of memory cards functioning as an external storage medium of the apparatus; Card interface means for electrically connecting with each of the memory cards housed in each of the memory card units and configuring an interface between the control unit and each of the memory cards.

By using such a plurality of memory cards, it is possible to realize a large capacity of an external storage system composed of a memory card. Therefore, an external storage system constituted by a practically excellent large capacity memory card can be configured without being limited to the small capacity of the single memory card.

Hereinafter, a first embodiment of the present invention will be described with reference to the drawings.

The apparatus of this embodiment is a laptop type personal computer as shown in FIG. This personal computer has a keyboard 2 and a flat panel display unit 3 based on the case unit 1 constituting the apparatus main body. The keyboard 2 is provided in the front part of the case unit 1, and is provided with the some key switch. The front part of the case unit 1 is formed with a handle part 4 for carrying the device body. The display unit 3 includes, for example, a display panel 3a of liquid crystal dosplay (LCD), and is mounted on the rear portion of the case unit 1. The display unit 3 is connected to the case unit 1 by a connecting member 5 which is free to rotate. When the computer is not in use by this connecting member 5, the display panel 3a is rotated in a direction close to the keyboard 2 so that the display unit 3 is closed on the front part of the case unit 1.

The memory card unit 6 and the floppy disk drive (FDD) unit 7 are incorporated in the side portion of the case unit 1. The memory card unit 6 is provided in the shaft portion of the front portion of the case unit 1 and is disposed below the keyboard 2.

The memory card unit 6 has a box-shaped case for storing the memory card 8 inserted from the card slot 6a formed in the side portion of the case unit 1.

The memory card 8 has a memory circuit in which the main body is formed of, for example, a card base of a plastic plate-like member, and is formed of an integrated circuit (LSI) in the card base. The memory circuit is read only memory (ROM) or read / write memory (RWM), and is composed of so-called RAM.

As shown in FIG. 2, a connector 10 having a plurality of terminals (contact holes) is provided at the tip end of the card base. The connector 10 has a high potential power terminal 11 at the center thereof and has a plurality of other terminals arranged symmetrically about the high potential power terminal 11. The high potential power terminal 11 is a terminal for supplying a power supply voltage (for example, 5V) required for the operation of the memory circuit 12 installed in the card 8. This power supply is installed inside the case unit 1 and is used as a power supply for operation of the entire computer.

The control signal terminal C ₂ , data input / output terminals D _{0 to} D ₇ , address terminals A _{4 to} A ₇ , and grounding terminals GND ₂ , GND ₃ ) is disposed. On the other side, control signal terminals C ₁ , data input / output terminals D _{8 to} D ₁₅ , address terminals A _{0 to} A ₃ , and ground terminals GND ₀ and GND ₁ are arranged. Each of these terminals is connected to the memory circuit 12.

The memory card unit 6 has a connector 20 corresponding to the connector 10 of the memory card 8. This connector 20 has each connection board according to each terminal of the card 8, and is connected to the printed circuit board provided in the case unit 1. As shown in FIG. The printed circuit board is equipped with various LSIs such as a central processing unit (CPU) and a card interface (C-IF) necessary for the operation of a computer.

As shown in FIG. 1, the memory card 8 is inserted into the card slot 6a of the case unit and stored in the memory card unit 6. In this unit 6, the connector 10 of the memory card 8 and the connector 20 of the unit 6 are connected. As a result, the memory card 8 is electrically connected to the printed circuit board provided in the case unit 1. Therefore, the CPU installed in the printed circuit board can access the memory card 8 through the C-IF. In other words, the CPU can use the memory card 8 as an external storage unit in the same way as the FDD.

Here, when the memory card 8 is inserted back into the card slot 6a with the front and back inverted when the memory card 8 is inserted into the memory card unit 6, the connector of the unit 6 in the case of such an abnormal reverse insertion ( 20) The connector 10 of the card 8 is connected so that each terminal of the right and left centering | focusing on the high potential power supply terminal 11 mutually changed positions. That is, the control signal terminal C ₂ , the data input / output terminals D _{0 to} D ₇ , the address terminals A _{4 to} A ₇ , and the ground terminals GND ₂ and GND ₃ are normal control signal terminals ( C ₁ ), the data input / output terminals D _{8 to} D ₁₅ , the address terminals A _{0 to} A ₃ , and the ground terminals GND ₀ and GND ₁ are connected to each pin of the connector 20 to be connected. . However, since the high potential power terminal 11 is disposed at the center portion of the connector 10, it is connected to the corresponding pin of the connector 20 as in the normal insertion case. This does not cause such a situation that when the card 8 is inserted upside down, the voltage from the power supply of the case unit 1 is supplied to the input / output terminal of data other than the high potential power supply terminal 11, for example.

Each terminal other than the high potential power terminal 11 is arranged symmetrically about the high potential power terminal 11. Therefore, even if each terminal is connected to the reverse of normal by the reverse insertion of the card 8, it is connected to the pin of the connector 20 corresponding to each terminal of the same type, respectively.

As described above, in the case of the memory card 8 of the present invention, even when the memory card unit 6 is reversely inserted into the memory card unit 6, the high potential power terminal 11 is connected to the connector of the unit 6 as in the normal state. Is connected to (20). In addition, each terminal other than the high potential power terminal 11 is connected to the connector 20 corresponding to each terminal of the same kind, respectively. Therefore, in the case of reverse insertion as in the case of a conventional card, for example, an abnormal circuit constituted by connecting a high potential power terminal on the connector 20 side of the unit 6 and a data input / output terminal of the memory card is connected. Can be prevented by the present invention. Such abnormal circuits can be prevented from forming, so that when the memory card 8 is inserted back, abnormal current flows to the memory circuit 12 or the printed circuit board on the computer side, for example, a CPU or the like. Or it can prevent the situation which a fault generate | occur | produces on both sides.

In the first embodiment, although the high potential power terminal 11 is disposed in the center of the connector 10 of the memory card 8, the high potential power terminal 11 is not limited thereto. Instead, a ground terminal may be used. Therefore, the high potential power terminal 11 is disposed at any one of the ground terminals GND ₀ and GND ₃ . As a matter of course, the control signal terminals C ₁ and C ₂ , the data input / output terminals D _{0 to} D ₁₅ , and the address terminals A _{0 to} A ₇ are respectively provided with power terminals (for high potential power terminals or ground). As long as it is symmetrical about a terminal, you may arrange | position in any position.

Next, a second embodiment of the present invention will be described with reference to FIGS. 3 to 6.

The apparatus of this embodiment is a laptop type personal computer of the same embodiment as the first embodiment as shown in FIG. This personal computer is provided with the memory card unit 6 provided in the side part of the case unit 1, and the other memory card unit 16 provided in the side part of the display unit 3. As shown in FIG.

The memory card unit 16 has a box-shaped case for storing the same memory card 18 as that of the memory card 8.

The memory card 18, like the memory card 8, has a main body composed of a card base of a plate-like member made of plastic, for example, and has a memory circuit made of an integrated circuit (LSI). The memory circuit consists of ROM or RWM. When the memory card 18 is inserted into the card slot 18a provided in the side part of the display unit 3, it is connected to the connector (connector 30 of FIG. 5) of the unit 16. As shown in FIG. The connector of the unit 16 is connected to the printed circuit board provided in the case unit 1.

The computer has a CPU 31 for executing data processing, a system bus 60, and a card interface (C-IF) 61 inside the case unit 1 as shown in FIG. The CPU 31 is connected to the C-IF 61 via the system bus 60. The C-IF 61 is an interface for transferring data, addresses and various control signals between the CPU 31 and each of the memory cards 8 and 18. The C-IF 61 is electrically connected to the connectors 20 and 30 provided in each of the units 6 and 16 for storing the respective memory cards 8 and 18. The CPU 31, the system bus 60 and the C-IF 61 are mounted on a printed circuit board.

The computer also stores a program of the CPU 31 and the like, which is a ROM 32, a RAM 33 for storing data necessary for data processing of the CPU 31, a direct memory access controller (DMAC) 34, Programmable interval controller (PIG) configurable by program, PIT (programmable interval timer) 36 configurable by program, RTC (real-time clock) 37 with electronics for its own operation A backup RAM (BK-RAM) 38 used as a data storage area for realizing the function of resume is provided. The backup power supply VBK is supplied to the RAM 33 and the BK-RAM 38 from the power supply circuit 40 even when the supply of the commercial AC power supply AC serving as the main power supply of the device is stopped.

The power supply circuit 40 has a power control circuit (PC-CPU), and is a circuit for supplying operating power to various circuits of a computer by receiving a DC voltage having a predetermined potential from the AC adapter 39. The AC adapter 39 is a circuit that rectifies and smoothes the input AC and outputs a DC voltage having a predetermined potential. The PC-CPU has the ability to monitor the entire internal power supply of the device. The power supply circuit 40 includes a main battery (M-BATT) 41a that is a rechargeable battery, a cartridge type, and a sub-battery (S-BATT) 41b that is a rechargeable battery and is incorporated in the case unit 1. The current voltage (backup power supply VBK) at a predetermined potential is supplied from each of the? The power supply control interface (PS-IF) 49 connects the power supply circuit 40 and the CPU 31 via the system bus 60.

In addition, the computer is a printer controller (PRT-CONT) 42, which is an interface of a printer (PRT) 51, which is an external device, a UART (Universal Asynchronous Receiver Transmitter) 43, which is an input / output interface with an external device, and a keyboard (KB). A keyboard controller (KB) 44 and a display controller (DISP-CONT) 45, which are interfaces of (2), are provided. The UART 43 is connected with an interface 52 according to, for example, RS-232C. The DISP-CONT 45 is a control circuit that performs display operation control of the display panel 3a of the LCD and the CRT display device (CRT) 53. The DISP-CONT 45 executes display operation control in accordance with the display data stored in the video RAM (VRAM) 46. The computer also includes a ROM 47 which stores character pattern data necessary for display operation of a display device or printing operation of a printer, a ROM 48 which is a dictionary memory necessary for the function of a word processor, and an extended storage device. An expansion connector 50 for connecting is provided.

5 is a perspective view of a conceptual diagram when a plurality of memory cards 8 and 18 are used in the computer of the second embodiment.

The C-IF 61 has card identification circuits 70 and 71 for identifying whether the memory cards 8 and 18 are set in each unit 6 and 16 or not. The card identification circuit 70 is a circuit having a pull-up resistor 70a as shown in FIG. 5, and a memory card 8 is inserted into the unit 6 to be connected to the connector 20 thereof. The identification signal (low level voltage signal) ID ₁ is output to the CPU 31 from one end of the pull-up resistor 70a. Similarly, the card identification circuit 71 is a circuit having a pull-up resistor 71a. When the memory card 18 is inserted into the unit 16 and connected to the connector 30, the card identification circuit 71 is connected from one end of the pull-up device 71a. The identification signal (low level voltage signal) ID ₂ is output to the CPU 31. The CPU 31 identifies whether the memory cards 8 and 18 are set in each unit 6 and 16 in accordance with the identification signals ID ₁ and ID ₂ from the C-IF 61.

In addition, the CPU 31 executes an identification process for identifying the type (ROM or RWM) of each of the memory circuits 12 and 22 of the memory cards 8 and 18 set as shown in the flowchart of FIG. .

First, as shown in step S1, the CPU 31 accesses each of the memory cards 8 and 18 via the C-IF 61, and writes predetermined identification data at a predetermined address. Next, the CPU 31 accesses each of the memory cards 8 and 18 via the C-IF 61, and reads out the identification data recorded in step S1 from the predetermined address (step S2).

The CPU 31 compares the read data with the recorded identification data and determines whether or not the respective data are identical (step S3).

Here, as shown in FIG. 5, it is assumed that the ROM is installed in the memory card S, and the RWM is installed in the memory card 18. As shown in FIG. If the read data and the recorded identification data match (YES in step S3), the CPU 31 identifies that the corresponding memory card 18 is equipped with an RWM (step S7). On the other hand, the CPU 31 identifies that the ROM is set in the corresponding memory card 8 when each data is inconsistent (NO in step S3). That is, since identification data cannot be recorded in the ROM, the data read out at the predetermined address of the ROM and the identification data do not match.

If step S3 is NO, the CPU 31 reads data from the predetermined address of the corresponding memory card 8 (step S4). The CPU 31 determines whether or not the read data is identification data (ID data) previously stored in the ROM (step S5). In the case of identification data (YES in step S5), the CPU 31 identifies that the ROM is installed in the memory card 8 (step S6). On the other hand, when the data is not for identification (NO in step S5), the CPU 31 determines that neither the RWM nor the ROM is installed in the memory card 8, and there is some kind of failure (step S8). ).

In this way, the CPU 31 identifies the type of each of the memory circuits 12, 22 of the plurality of memory cards 8, 18, and executes memory control according to the type. Specifically, since the ROM is provided in the memory card 8, the CPU 31 performs a process of accessing the memory card and reading out various kinds of data (or programs) stored in advance.

In addition, since the RWM is installed in the memory card 18, the CPU 31 uses the memory card 18 as a memory, for example, an extended RWM. When the RWM is provided in each of the memory cards 8 and 18, the CPU 31 can use each card 8 and 18 as a single memory space.

Since a plurality of memory cards 8 and 18 can be used as described above, it can be used as a large capacity external storage device as a whole rather than a single memory card. Therefore, the memory card can be used as a practically excellent external storage medium corresponding to the disk of the FDD. As a result, in a single memory card, the use range is limited due to the small amount of storage, but according to the present invention, such a restriction can be removed.

Claims (3)

A card base constituting the card body and having a memory circuit; Data input / output connected electrically to the memory circuit, electrically connected to the memory circuit and an external device, provided on a flat surface of the tip portion of the card base connected to the external device, and having a power terminal connected to the memory circuit as a center. And a connector means having respective terminals in which each of the terminal, the address terminal, and the terminal for the control signal line is arranged symmetrically. 2. The connector according to claim 1, wherein the connector means has a high potential power terminal connected to the memory circuit as a center, and each of the data input / output terminal, the address terminal, the control signal line terminal, and the ground power supply terminal connected to the memory circuit are provided. And a terminal arranged symmetrically. 2. The connector according to claim 1, wherein the connector means has a ground power supply terminal connected to the memory circuit as a center, and each of data input / output terminals, address terminals, control signal line terminals, and high potential power terminals connected to the memory circuit is provided. And each terminal arranged symmetrically.

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