Source: https://patents.google.com/patent/JP4238580B2/en
Timestamp: 2020-01-20 14:17:07
Document Index: 620936799

Matched Legal Cases: ['art 6', 'art 6', 'art 6', 'art 6', 'art 6', 'art 6', 'art 6', 'art 6', 'art 6']

JP4238580B2 - Data storage device and data recording system - Google Patents
Data storage device and data recording system Download PDF
JP4238580B2
JP4238580B2 JP2003002653A JP2003002653A JP4238580B2 JP 4238580 B2 JP4238580 B2 JP 4238580B2 JP 2003002653 A JP2003002653 A JP 2003002653A JP 2003002653 A JP2003002653 A JP 2003002653A JP 4238580 B2 JP4238580 B2 JP 4238580B2
JP2003002653A
JP2004213574A (en
淳子 佐々木
拓己 岡上
茂生 荒木
2002-11-15 Priority to JP2002332699 priority Critical
2003-01-08 Application filed by ソニー株式会社 filed Critical ソニー株式会社
2003-01-08 Priority to JP2003002653A priority patent/JP4238580B2/en
2004-07-29 Publication of JP2004213574A publication Critical patent/JP2004213574A/en
2009-03-18 Publication of JP4238580B2 publication Critical patent/JP4238580B2/en
2023-01-08 Anticipated expiration legal-status Critical
The present invention relates to a removable data storage device that is detachably attached to a host device.And data recording systemAbout.
As an application using a NAND flash memory, a so-called removable small IC memory device called a memory card is known (for example, see Patent Document 1). The memory card can store various digital data such as still image data, moving image data, audio data, and music data. For example, portable information terminals, desktop computers, notebook computers, mobile phones, audio devices, home appliances Used as an external storage medium in a host device such as a device.
In recent years, development of NAND type flash memory has progressed, and the capacity has been increased rapidly. In accordance with this, the amount of data that can be stored in one memory card is rapidly increasing.
However, the upper limit of the recording capacity of the memory card is limited by the applied file system. Even if a flash memory with an increased capacity is applied to a memory card, the upper limit of the recording capacity cannot be exceeded in order to be compatible with a conventional file system. Therefore, if it is desired to use the capacity of the memory card beyond the upper limit of the management capacity of the conventional file system, a new file system must be applied to the memory card.
However, when using a memory card to which a new file system is applied, it is usually necessary to change the operation system of the host device. Changing the operation system of the host device is a very troublesome task and a heavy burden.
Therefore, when providing a large-capacity memory card that exceeds the management capacity of the conventional file system, it is desirable to be able to use the memory card without changing the system to the host device.
In addition, when managing data recorded in a memory card, it may be convenient to divide the storage area in one memory card into a plurality of parts and recognize the divided areas as independent devices. For example, when work data and private data are stored in the same memory card, the storage area of one memory card is divided into a plurality of parts, and work data and private data are completely separated. It is very convenient to handle it as if it were stored on a device.
As a memory card in consideration of the above, a switch-switching type memory card has been proposed in which a plurality of flash memories are provided inside and the flash memory can be switched and used by an external changeover switch ( For example, see Patent Document 2.) In this switch-switching type memory card, a plurality of internal recording areas can be recognized as independent devices by the host device by switching external switches. Also, with this switch-switchable memory card, the total recording capacity in one package can be made larger than the upper limit of the file system management capacity.
Japanese Patent Laid-Open No. 340575
Japanese Patent Laid-Open No. 233439
However, in such a conventional switch-switchable memory card, if the switch is switched while it is mounted on the host device, the host cannot recognize the device, and in the worst case, recorded data is not stored. It will be destroyed.
Further, in such a conventional switch-switching type memory card, the user cannot determine which flash memory is currently selected when it is mounted on the host device. In other words, if it becomes impossible to know which recording area is selected after being mounted on the host device, it is necessary to remove the memory card from the host device and check the state of the switch.
The present invention has been made in view of the above circumstances, and in a removable data storage device that is detachably attached to a host device, the host device is switched by switching a plurality of internal storage areas with a switch. Allows each recording area to be recognized as an independent device, and the above switches can be switched while attached to the host device.Provided data storage device and data recording systemThe purpose is to do.
The data storage device according to the present invention is a removable data storage device that is detachably attached to a host device. The data storage device according to the present invention is provided with a plurality of nonvolatile memories and a plurality of contacts, and the contacts are switched by a user's operation, and the one nonvolatile memory corresponding to the switched contacts is stored in the data storage device. Data transmission / reception between the first switch to be selected, the second switch for switching the contact in conjunction with the switching operation of the first switch, and the host device when mounted on the host device And a controller that operates based on data transmitted through the interface unit and reads / writes data from / to one nonvolatile memory selected by the first switch. ing.
The interface unit is provided with a detection terminal for allowing the host device to determine that the apparatus is installed. The host device determines that the apparatus is attached when the detection terminal is connected to the ground, and determines that the apparatus is not attached when the detection terminal is open.
Further, the first switch is provided with a contact that does not select any nonvolatile memory at an intermediate position of switching from a contact that selects an arbitrary nonvolatile memory to a contact that selects another nonvolatile memory. The second switch connects the detection terminal to the ground when the first switch is switched to a contact for selecting any nonvolatile memory, and the first switch is any nonvolatile memory. When the contact point is not selected, the detection terminal is opened.
In the data storage device as described above, the plurality of internal nonvolatile memories are switched by the first switch, thereby causing the host device to recognize each recording area as an independent device. Further, in this data storage device, the first switch has a contact that does not select any nonvolatile memory at an intermediate position of switching from a contact that selects an arbitrary nonvolatile memory to a contact that selects another nonvolatile memory. When the second switch is switched to a contact that selects one of the nonvolatile memories, the detection terminal is connected to the ground.To detect that a data storage device is installed in the host device.When the first switch is switched to a contact that does not select any nonvolatile memory, the detection terminal is opened.To detect that the data storage device is not installed in the host device..
According to the present inventionData recording systemIs a host device and removable data storage that can be detachably attached to the host deviceDevice. The data storage device is provided with a plurality of non-volatile memory means in which stored data is not erased even when detached from the host device, and a plurality of contacts, and the contacts are switched by a user operation. A first switch for selecting one of the non-volatile memory means corresponding to the selected and switched contact, a second switch for switching the contact in conjunction with the switching operation of the first switch, and a host device An interface unit that transmits / receives data to / from the host device when attached to the host device, and operates based on data transmitted through the interface unit, and one non-volatile selected by the first switch A controller for reading and writing data to and from the memory means. The interface unit is provided with a detection terminal for causing the host device to determine that the data storage device is installed. The first switch is provided at a position where the operation unit of the first switch can be operated by the user even when the data storage device is mounted on the host device, and from a contact for selecting an arbitrary nonvolatile memory means A contact that does not select any nonvolatile memory means is provided at an intermediate position for switching to a contact that selects another nonvolatile memory means. The second switch connects the detection terminal to the ground when the first switch is switched to the contact for selecting any one of the nonvolatile memory means, and the data storage device is attached to the host device. And when the first switch is switched to a contact that has not selected any nonvolatile memory means, the detection terminal is opened, and the host device is detected that the data storage device is not installed. . The host device detects that the data storage device is attached when the detection terminal is connected to the ground, and detects that the data storage device is not attached when the detection terminal is open.
Hereinafter, a removable small IC memory device to which the present invention is applied will be described as an embodiment of the present invention.
A small IC memory device described as an embodiment of the present invention is hereinafter referred to as a memory card. The data processing apparatus to which the memory card is connected is hereinafter referred to as a host device.
First, the memory card according to the first embodiment will be described.
FIG. 1 is an external perspective view of the host device and the memory card.
The memory card 1 has a nonvolatile semiconductor memory (IC memory) inside. The nonvolatile semiconductor memory can retain data even when the card is removed from the host device. The memory card 1 can store various digital data such as still image data, moving image data, audio data, and music data in an internal semiconductor memory. The memory card 1 functions as an external storage medium of the host device 2 such as an information portable terminal, a desktop computer, a notebook computer, a mobile phone, an audio device, and a home appliance. The memory card 1 is used in a state where it is inserted into a slot 3 provided in the host device 2. The user can freely insert and remove the memory card 1 from the slot 3 manually. Therefore, for example, the memory card 1 inserted into a certain host device can be extracted and inserted into another host device, so that it can be used for data exchange between different host devices.
FIG. 2 is a perspective view of the memory card 1 according to the first embodiment as viewed from the front side, and FIG. 3 is a perspective view of the memory card 1 according to the embodiment of the present invention as viewed from the back side.
The memory card 1 has a thin plate shape in which the main surfaces (the front surface 1a and the back surface 1b) are substantially rectangular. The memory card 1 has a length of the main surface in the longitudinal direction of about 50 mm, a length of the main surface in the short side direction of about 21.45 mm, and a thickness of about 2.8 mm. Further, the main surface of the memory card 1 is distinguished into a front surface 1a and a back surface 1b. At one end in the longitudinal direction of the back surface 1b, 10 planar electrodes (connection terminal group 4) are provided in a line in the short side direction. Further, a guard 5 rising vertically from the back surface 1b is provided between the electrodes to prevent contact of a finger or the like to the connection terminal.
The memory card 1 is provided with a slide switch 6. The slide switch 6 is provided at a position where the user can switch from the outside even when the memory card 1 is inserted into the host device 2. For example, as shown in FIGS. 2 and 3, the slide switch 6 is provided on the end surface 1 c on the opposite side to the end in the longitudinal direction where the connection terminal group 4 is provided. The end face 1 c is exposed from the slot 3 even when the memory card 1 is inserted into the slot 3 of the host device 2. For this reason, if the slide switch 6 is provided on the end face 1c, even if the memory card 1 is inserted into the host device 2, the user can switch from the outside.
The slide switch 6 has a movable part 6a that can slide. The movable part 6a is X in the figure.1, X2It is free to move in the direction. The slide switch 6 is provided with a point where the movable part 6a is fixed within the movable range of the movable part 6a. The points at which the movable portion 6a is fixed are one end in the movable range, the other end in the movable range, and the three points in the middle of the movable range. In other words, the slide switch 6 is a switch that switches these three points in order. In the memory card 1, the internal IC memory can be switched by switching the slide switch 6, and the details of the function will be described later.
A slot 3 is formed in the host device 2. The slot 3 has a concave shape corresponding to the memory card 1, and the memory card 1 can be inserted. Further, the slot 3 can hold the memory card 1 so that the memory card 1 is not dropped when the memory card 1 is inserted. The slot 3 is provided with a connection terminal group composed of 10 contacts at positions corresponding to the 10 planar electrodes of the memory card 1. Therefore, when the memory card 1 is inserted into the slot 3 from the direction of the connection terminal group 4 (by inserting the memory card 1 in the Y direction in FIG. 2), the connection terminals in these slots 3 and the memory The connection terminals of the card 1 are electrically connected.
FIG. 4 shows an internal block configuration diagram of the memory card 1.
The connection terminal group 4 of the memory card 1 and the connection terminal group provided in the slot 3 of the host device 2 include a serial data terminal SD, a bus state terminal BS, a clock terminal CLK, and an insertion / extraction detection terminal INS. Yes. When the memory card 1 is connected to the host device 2, these terminals are connected to each other. Serial data recorded in the IC memory in the memory card 1 or serial data read from the IC memory is transmitted to the serial data terminal SD, and various control data are also transmitted. A bus state signal indicating the state of serial data transmitted via the serial data terminal SD is transmitted to the bus state terminal BS. A clock signal indicating the clock timing of serial data transmitted via the serial data terminal SD is transmitted to the clock terminal CLK.
The insertion / extraction detection terminal INS is a terminal provided to determine from the host device 2 side whether the memory card 1 is inserted into the host device 2 or not. The detection of insertion / extraction of the memory card 1 by the host device 2 will be described in detail later.
Further, the connection terminal group 4 is provided with a power supply terminal VCC and a ground terminal VSS (not shown). The power supply terminal VCC is a terminal for supplying power from the host device 2 to the memory card 1 that does not have an internal power supply. The ground terminal VSS is a terminal for sharing the ground level of the memory card 1 and the host device 2 when the memory card 1 is inserted into the host device 2.
The memory card 1 includes a controller 11, a first IC memory 12-1, a second IC memory 12-2, a first switch 13, and a second switch 14 inside.
When the memory card 1 is inserted in the host device 2, the controller 11 receives serial data and buses from the host device 2 via the serial data terminal SD, the bus state terminal BS, and the clock terminal CLK. Transfers state signals and clock terminals. The controller 11 controls data writing and reading with respect to the first IC memory 12-1 and the second IC memory 12-2 based on serial data (actual data and control data) supplied from the host device 2. I do. Further, the controller 11 has a control terminal CNT, and generates a memory control signal indicating the timing of writing and reading data to the IC memory from the control terminal CNT. The controller 11 sets the memory control signal to Low when writing to and reading from the first IC memory 12-1 and the second IC memory 12-2, and performs memory control when writing and reading are not performed. Let the signal be High.
The first IC memory 12-1 and the second IC memory 12-2 are nonvolatile semiconductor memories such as a NAND flash memory. The first IC memory 12-1 and the second IC memory 12-2 are each configured as an independent device (IC). Both the first IC memory 12-1 and the second IC memory 12-2 are connected to the controller 11 via a bus (address bus, data bus, and control bus) 14.
The first IC memory 12-1 and the second IC memory 12-2 are provided with a chip select terminal CS. The first IC memory 12-1 and the second IC memory 12-2 are configured to write data from the controller 11 when the signal (chip select signal) supplied to the chip select terminal is LOW. Reading is possible, and writing and reading of data from the controller 11 are not accepted when HIGH.
The first switch 13 is a switch that switches in conjunction with the slide switch 6 provided outside the housing. The first switch 13 has one fixed contact 13a and three movable contacts (a first movable contact 13b, a second movable contact 13c, and a third movable contact 13d). The first switch 13 connects the fixed contact 13 a and any one of the movable contacts 13 b to 13 d in conjunction with the sliding operation of the movable portion 6 a of the slide switch 6. The fixed contact 13a is connected to the control terminal CNT of the controller 11. The first movable contact 13 b is connected to the chip select terminal CS of the first IC memory 12-1 and is connected to the power supply terminal Vcc via the first pull-up resistor 15. The second movable contact 13 c is connected to the chip select terminal CS of the second IC memory 12-2 and is connected to the power supply terminal Vcc via the second pull-up resistor 16. The third movable contact 13d is in an open state without being connected to any terminal.
Such a first switch 13 connects the fixed contact 13a and the first movable contact 13b when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, and the slide switch 6 6 is switched to a fixed position on the other end side opposite to the one end side, the fixed contact 13a and the second movable contact 13c are connected, and the slide switch 6 is movable. When the portion 6a is switched to the center fixed position, the fixed contact 13a and the third movable contact 13d are connected.
Therefore, when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, the memory control signal from the controller 11 is supplied to the chip select terminal CS of the first IC memory 12-1. Thus, the High level is always supplied to the chip select terminal CS of the second IC memory 12-2. That is, when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, data is written to and read from only the first IC memory 12-1.
When the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side, a memory control signal from the controller 11 is supplied to the chip select terminal CS of the second IC memory 12-2. Therefore, the High level is always supplied to the chip select terminal CS of the first IC memory 12-1. That is, when the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side, data is written to and read from only the second IC memory 12-2.
When the movable portion 6a of the slide switch 6 is switched to the fixed position at the center, the chip select terminal CS of the first IC memory 12-1 and the second IC memory 12-2 is always at a high level. Is supplied. That is, when the movable part 6a of the slide switch 6 is switched to the center fixed position, both the first IC memory 12-1 and the second IC memory 12-2 write and read data. Is not done.
As described above, the first switch 13 operates in conjunction with the slide switch 6 so that one of the two internal IC memories is selected or two IC memories are selected. None of these are selected.
The second switch 14 is a switch that switches in conjunction with the slide switch 6 provided outside the housing. The contact configuration of the second switch 14 is the same as the contact configuration of the first switch 13. Specifically, the second switch 14 has one fixed contact 14a and three movable contacts (a first movable contact 14b, a second movable contact 14c, and a third movable contact 14d). Yes. The second switch 14 connects the fixed contact 14 a and any one of the movable contacts 14 b to 14 d in conjunction with the sliding operation of the movable portion 6 a of the slide switch 6. The fixed contact 14a is connected to the insertion / extraction detection terminal INS. The first movable contact 14b is connected to the ground. The second movable contact 14c is connected to the ground. The third movable contact 14d is not connected to any terminal and is open.
Such a second switch 14 connects the fixed contact 14a and the first movable contact 14b when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, and the slide switch 6 6 is switched to a fixed position on the other end side opposite to the one end side, the fixed contact 14a and the second movable contact 14c are connected, and the slide switch 6 is movable. When the portion 6a is switched to the center fixed position, the fixed contact 14a and the third movable contact 14d are connected.
Therefore, when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, the insertion / extraction detection terminal INS is connected to the ground. When the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side, the insertion / extraction detection terminal INS is connected to the ground. When the movable part 6a of the slide switch 6 is switched to the center fixed position, the insertion / extraction detection terminal INS is opened.
Here, the insertion / extraction detection determination performed by the host device 2 will be described.
The controller of the host device 2 monitors the voltage level of the insertion / extraction detection terminal INS, and the memory card 1 is inserted into the host device 2 so that data can be written and read. It is determined whether the memory card 1 is not inserted into the device 2 and data cannot be written or read.
The insertion / extraction detection terminal INS on the host device 2 side is pulled up to the power source Vcc via the pull-up resistor 17 as shown in FIG. Therefore, when the memory card 1 is not inserted, the voltage level of the insertion / extraction detection terminal INS on the host device 2 side becomes High. If the memory card 1 is inserted and the insertion / extraction detection terminal INS on the memory card 1 side is dropped to the ground, the voltage level of the insertion / extraction detection terminal INS on the host device 2 side becomes Low. Accordingly, if the memory card 1 is inserted and removed while the insertion / extraction detection terminal INS on the memory card 1 side is connected to the ground, the host device 2 monitors the voltage level of the insertion / extraction detection terminal INS, thereby 1 can be determined for insertion and extraction.
The controller of the host device 2 determines whether the memory card 1 is inserted or removed, and performs memory card mounting processing and demounting processing. Specifically, when the insertion / extraction detection terminal INS changes from Hihg to Low, the controller of the host device 2 performs processing (mount processing) for incorporating the file system of the memory card 1 on the operation system. As a result, the memory card 1 is recognized as an external storage device of the host device 2. In addition, when the insertion / extraction detection terminal INS changes from Low to High, the host controller of the host device 2 performs processing (demounting) for removing the file system of the memory card 1 incorporated in the operation system. At this time, for example, when the memory card 1 is removed while data is being written, the host device 2 performs a backup process of the data being written.
As described above, the host device 2 monitors the voltage level of the insertion / extraction detection terminal INS and performs processing for insertion and extraction of the memory card 1.
Incidentally, the second switch 14 switches the connection state of the insertion / extraction detection terminal INS in accordance with the switching of the moving position of the movable portion 6a of the slide switch 6.
The second switch 14 is used when the movable portion 6a of the slide switch 6 is switched to a fixed position on one end side, that is, the first IC memory 12-1 is selected by the first switch 13. If there is, the insertion / extraction detection terminal INS is connected to the ground. Therefore, when the memory card 1 with the slide switch 6 switched to one end is inserted into the host device 2, the host device 2 can detect that the memory card 1 has been inserted, Furthermore, data can be written to and read from the first IC memory 12-1.
Similarly, the second switch 14 is configured so that the second IC memory 12-2 is moved by the first switch 13 when the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side. When selected, the insertion / extraction detection terminal INS is connected to the ground. Therefore, when the memory card 1 with the slide switch 6 switched to the other end is inserted into the host device 2, the host device 2 can detect that the memory card 1 has been inserted, Furthermore, data can be written to and read from the second IC memory 12-2.
On the other hand, the second switch 14 is an insertion / extraction detection terminal when the movable part 6a of the slide switch 6 is switched to the center fixed position, that is, when no IC memory is selected by the first switch 13. INS is open. Therefore, when the memory card 1 with the slide switch 6 switched to the center fixed position is inserted into the host device 2, the host device 2 is made to detect that the memory card 1 is not inserted. Can do.
Furthermore, the slide switch 6 can be operated by the user while being inserted into the host device 2. Therefore, the movable portion 6a of the slide switch 6 can be moved from the fixed position on one end side to the fixed position on the other end side while being inserted into the host device 2. Similarly, it is also possible to move from the fixed position on the other end side to the fixed position on the one end side. That is, if the memory card 1 is inserted into the host device 2 and the slide switch 6 is switched, the IC memory for writing and reading data is changed from the first IC memory 12-1 to the second IC memory 12-1. Can be switched to or from the IC memory 12-2.
Furthermore, the movable portion 6a of the slide switch 6 is always centered when moved from the fixed position on one end side to the fixed position on the other end side, or moved in the opposite direction. The insertion / extraction detection terminal INS is once opened by the second switch 14. That is, when the movable portion 6a of the slide switch 6 is moved from the fixed position on one end side to the fixed position on the other end side, or moved in the opposite direction, the insertion / extraction detection terminal The INS is released from the state where it is connected to the ground, and then connected to the ground again.
Therefore, in such a memory card 1, when the memory switch 1 is operated with the memory card 1 inserted into the host device 2 and the IC memory to be selected is switched to another IC memory, the host device After the memory card 1 is once demounted for 2, it can be mounted again.
As a result, in the memory card 1 according to the first embodiment, even if the IC switch is switched by operating the slide switch 6 in the state of being inserted in the host device 2, it is temporarily extracted from the host device 2. It can be judged that it was done. Therefore, in this memory card 1, the IC memory can be switched safely without destroying the data being recorded.
In the memory card 1 of the first embodiment, the number of internal IC memories is two. However, in the present invention, the number of internal IC memories is not limited to two, and any number may be used as long as it is plural. But you can. However, when the number of IC memories increases, if the switch for selecting the IC memory is a slide switch, the operation by the user may become troublesome. In such a case, it is desirable to use, for example, a rotary switch 21 as shown in FIG. 5 as a switch for selecting an IC memory. However, also in this case, the first switch 13 and the second switch 14 operate in conjunction with the rotary switch 21, and as shown in FIG. When selected, the second switch 14 drops the insertion / extraction detection terminal INS to the ground. Further, when an operation of switching from an arbitrary IC memory to another IC memory is performed, the second switch 14 is configured to always open the insertion / extraction detection terminal INS.
Further, the memory card 1 of the first embodiment may be provided with a display unit for notifying the user of the selected IC memory. The display unit is provided at a position where the user can see the display even when the memory card 1 is inserted into the host device 2. For example, as shown in FIG. 7, the display unit is composed of a first light emitting diode 22 and a second light emitting diode 23, and these are arranged with respect to the longitudinal end where the connection terminal group 4 is provided. Provided on the opposite end. As shown in FIG. 8, the first light emitting diode 22 is connected in series with the first pull-up resistor 15, and the second light emitting diode 23 is connected in series with the second pull-up resistor 16. Connecting. Thus, the first light emitting diode 22 emits light when the first IC memory 12-1 is selected, and the second light emitting diode when the second IC memory 12-2 is selected. 23 emits light.
By providing a display unit for notifying the user of the selected IC memory in this way, in the memory card 1 of the first embodiment, by switching a plurality of internal IC memories with a switch, the host device 2 can recognize each IC memory as an independent device, and can make the user recognize the IC memory selected in the state of being mounted on the host device 2.
Further, the memory card 1 according to the first embodiment may be provided with a switch for preventing erroneous erasure. The erroneous erasure prevention switch is a switch for switching between a state in which data writing to the first IC memory 12-1 and the second IC memory 12-2 is prohibited and a state in which writing is permitted. The selection signal for the erroneous erasure prevention switch is given to the controller 11. The controller 11 controls the prohibition and permission of data writing to the first IC memory 12-1 and the second IC memory 12-2 according to the selection signal of the erroneous erasure prevention switch. As shown in FIG. 9, for example, the operation unit 25 of the erroneous erasure prevention switch is provided in the vicinity of the connection terminal group 4 on the back surface 1b of the housing. As described above, the operation unit 25 is provided on the back surface 1b of the casing, so that when the memory card 1 is inserted into the host device 2, the operation by the user can be disabled.
Next, the memory card according to the second embodiment will be described.
In the description of the memory card according to the second embodiment, the same components as those of the memory card 1 according to the first embodiment described above are denoted by the same reference numerals and detailed description thereof is omitted. .
FIG. 10 is a perspective view of the memory card 30 according to the second embodiment viewed from the back side.
Similar to the first embodiment, the memory card 30 has a nonvolatile semiconductor memory (IC memory) inside, and can store various digital data. The memory card 30 functions as an external storage medium for the host device 2. The memory card 30 is used in a state inserted in the slot 3 provided in the host device 2. The user can freely insert and remove the memory card 30 from the slot 3 manually. Therefore, for example, the memory card 30 inserted in a certain host device 2 can be extracted and inserted into another host device 2, so that it can be used for data exchange between different host devices.
The memory card 30 has a thin plate shape with the main surface (front surface 1a and back surface 1b) being substantially rectangular, and the configuration of the housing is the same as the memory card 1 of the first embodiment.
However, the memory card 30 of the second embodiment is different from the first embodiment in the mounting position of the slide switch 6 for switching the internal IC memory. The memory card 30 of the second embodiment is provided on the back surface 1b. Since the slide switch 6 is provided on the back surface 1b as described above, when the memory card 30 is inserted into the host device 2, the user cannot switch from the outside.
In addition, an IC for the controller 11 and a memory IC are provided inside the memory card 30. As shown in FIG. 11, the slide switch 6 has an IC disposition position, an IC, It is provided at a position between the memory location. By providing the slide switch 6 in this way, the distance from the changeover switch inside the card can be shortened, and the manufacture becomes easy.
FIG. 12 shows an internal block configuration diagram of the memory card 30.
The insertion / extraction detection terminal INS of the memory card 30 is a terminal provided for determining from the host device 2 side whether the memory card 30 is inserted into the host device 2 or not. In the memory card 30 of the second embodiment, the insertion / extraction detection terminal INS is connected to the ground.
The memory card 30 includes a controller 11, a first IC memory 31-1, a second IC memory 31-2, a third IC memory 33-3, and a memory changeover switch 32. Yes.
When the memory card 30 is inserted in the host device 2, the controller 11 receives serial data and a bus from the host device 2 via the serial data terminal SD, the bus state terminal BS, and the clock terminal CLK. Transfers state signals and clock terminals. Based on the serial data (actual data and control data) supplied from the host device 2, the controller 11 applies to the first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3. Data writing and reading are controlled. Further, the controller 11 has a control terminal CNT, and generates a memory control signal indicating the timing of writing and reading data to the IC memory from the control terminal CNT. The controller 11 sets the memory control signal to Low when writing to and reading from the first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3. When reading is not performed, the memory control signal is set to High.
The first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 are nonvolatile semiconductor memories such as NAND flash memories. The first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 are each configured as an independent device (IC). The first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 are all connected to the controller 11 via a bus (address bus, data bus, and control bus) 14. Yes.
The first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 are provided with a chip select terminal CS. In the first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3, the signal (chip select signal) supplied to the chip select terminal is LOW. Data writing and reading from the controller 11 are enabled, and data writing and reading from the controller 11 are not accepted when HIGH.
The memory changeover switch 32 is a switch that switches in conjunction with the slide switch 6 provided outside the housing. The memory changeover switch 32 has one fixed contact 32a and three movable contacts (a first movable contact 32b, a second movable contact 32c, and a third movable contact 32d). The memory changeover switch 32 connects the fixed contact 32a and any one of the movable contacts 32b to 32d in conjunction with the sliding operation of the movable portion 6a of the slide switch 6. The fixed contact 32 a is connected to the control terminal CNT of the controller 11. The first movable contact 32b is connected to the chip select terminal CS of the first IC memory 31-1, and is connected to the power supply terminal Vcc via the first pull-up resistor 33. The second movable contact 32 c is connected to the chip select terminal CS of the second IC memory 31-2 and is connected to the power supply terminal Vcc via the second pull-up resistor 34. The third movable contact 32d is connected to the chip select terminal CS of the third IC memory 31-3, and is connected to the power supply terminal Vcc via the third pull-up resistor 35.
Such a memory changeover switch 32 connects the fixed contact 32a and the first movable contact 32b when the movable portion 6a of the slide switch 6 is switched to a fixed position on one end side, and the slide switch 6 When the movable part 6a is switched to the fixed position on the other end side opposite to the one end side, the fixed contact 32a and the third movable contact 32d are connected, and the movable part of the slide switch 6 is connected. When 6a is switched to the central fixed position, the fixed contact 32a and the second movable contact 32c are connected.
Therefore, when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, the memory control signal from the controller 11 is supplied to the chip select terminal CS of the first IC memory 31-1. Thus, the High level is always supplied to the chip select terminal CS of the second IC memory 31-2 and the third IC memory 31-3. That is, when the movable portion 6a of the slide switch 6 is switched to the fixed position on one end side, data is written to and read from only the first IC memory 31-1.
When the movable portion 6a of the slide switch 6 is switched to the center fixed position, a memory control signal from the controller 11 is supplied to the chip select terminal CS of the second IC memory 31-2, and the first The high level is always supplied to the chip select terminal CS of the IC memory 31-1 and the third IC memory 31-3. That is, when the movable part 6a of the slide switch 6 is switched to the central fixed position, data is written to and read from only the second IC memory 31-2.
When the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side, a memory control signal from the controller 11 is supplied to the chip select terminal CS of the third IC memory 31-3. Thus, the High level is always supplied to the chip select terminal CS of the first IC memory 31-1 and the second IC memory 31-2. That is, when the movable portion 6a of the slide switch 6 is switched to the fixed position on the other end side, data is written to and read from only the third IC memory 31-3.
As described above, the memory changeover switch 32 operates in conjunction with the slide switch 6 to select one of the three internal IC memories.
As described above, in the memory card 30 according to the second embodiment, the mounting position of the slide switch 6 for switching the internal IC memory is provided on the back surface 1b. By providing the slide switch 6 on the back surface 1b as described above, it becomes impossible for the user to switch from the outside when the memory card 30 is inserted into the host device 2. Therefore, in the memory card 30 of the second embodiment, a plurality of flash memories are provided inside the flash memory so that the flash memories can be switched by using an external changeover switch, and data is inserted into the host device 2. In the meantime, the switching by the user is prevented so that the recorded data is not destroyed.
Further, the memory card 30 of the second embodiment may be provided with a switch for preventing erroneous erasure. The erroneous erasure prevention switch switches between a state in which data writing to the first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 is prohibited and a state in which writing is permitted. Switch. The selection signal for the erroneous erasure prevention switch is given to the controller 11. The controller 11 prohibits and permits data writing to the first IC memory 31-1, the second IC memory 31-2, and the third IC memory 31-3 according to the selection signal of the erroneous erasure prevention switch. Take control. For example, the operation unit 25 is provided in the vicinity of the connection terminal group 4 on the rear surface 1b of the housing as shown in FIG. As described above, the operation unit 25 is provided on the back surface 1b of the housing, so that when the memory card 30 is inserted into the host device 2, the operation by the user can be disabled.
Further, the erroneous erasure prevention switch is provided, for example, on the end surface 1c on the opposite side of the operation portion 25 with respect to the end portion in the longitudinal direction where the connection terminal group 4 is provided as shown in FIG. It may be done. The end face 1 c is exposed from the slot 3 even when the memory card 1 is inserted into the slot 3 of the host device 2. For this reason, if the operation unit 25 of the erroneous erasure prevention switch is provided on the end face 1c, even if the memory card 1 is inserted into the host device 2, the user can switch from the outside.
Further, in the memory card 30 of the second embodiment, the arrangement position of the slide switch 6 may be provided in the vicinity of the connection terminal group 4 on the back surface 1b of the housing as shown in FIG. There has been proposed a conventional memory card called Memory ™ (trademark) having substantially the same external shape as the memory card 30 of the second embodiment. In this conventional memory card, an operation unit for an erroneous erasure prevention switch is provided in the vicinity of the connection terminal group on the back surface of the housing on the back surface 1b. The slide switch 6 of the memory card 30 shown in FIG. 15 is arranged at the same position as the erroneous erasure prevention switch provided in this conventional memory card and is composed of the same members. Therefore, the memory card 30 shown in FIG. 15 can realize a memory selection switch without having to change the external shape or switch shape of the conventional memory card. Therefore, the conventional memory card and the production line can be shared, and the cost due to the design change can be suppressed.
The IC memory provided in the memory card 30 has been described by taking a NAND flash memory as an example. However, in the present invention, data can be retained even after the memory card is removed from the host device. Any memory means may be used if possible. The memory card 30 is provided with a plurality of memory means, but a plurality of types of IC memories may be mixed. For example, a flash memory and a ROM may be mixed, and if a battery is provided in the memory card 30, a RAM may be included as memory means.
Next, a memory card according to the third embodiment will be described.
In the description of the memory card of the third embodiment, the same components as those of the memory card 1 of the first embodiment described above are denoted by the same reference numerals, and detailed description thereof is omitted. .
FIG. 16 is a perspective view of the memory card 40 according to the third embodiment as viewed from the front surface side, and FIG. 17 is a perspective view of the memory card 40 according to the third embodiment as viewed from the back surface side.
As in the first embodiment, the memory card 40 has a nonvolatile semiconductor memory (IC memory) inside and can store various digital data. The memory card 40 functions as an external storage medium for the host device 2. The memory card 40 is used while being inserted into the slot 3 provided in the host device 2. The user can freely insert and remove the memory card 40 from the slot 3 manually. Therefore, for example, the memory card 40 inserted into a certain host device 2 can be extracted and inserted into another host device 2, so that it can be used for data exchange between different host devices.
The memory card 40 has a thin plate shape in which the main surface (the front surface 1a and the back surface 1b) is substantially rectangular, and the configuration of the housing is the same as that of the memory card 1 of the first embodiment.
In the memory card 40, two IC memories, a first IC memory 12-1 and a second IC memory 12-2, are provided. In the memory card 40, the name of one of the two IC memories (for example, the first IC memory 12-1) is defined as “memory A”, and the other IC memory (for example, the second IC memory) is defined. The name of the IC memory 12-2) is defined as “memory B”.
On the main surface 1a of the memory card 40, a first mark 41 indicating the total capacity of the memory A and the memory B, a second mark 42 indicating the capacity of the memory A, and a capacity of the memory B are shown. The third mark 43 is described. In the memory card 40, since the data capacity of each IC memory is described outside the housing in this way, the user can recognize the data capacity of each IC memory. Such a mark indicating the data capacity of each IC memory may be written in the memory card 1 of the first embodiment and the memory card 30 of the second embodiment.
Further, a two-contact switching type first slide switch 44 is provided on the back surface 1 b of the memory card 40. The first slide switch 44 functions as a memory selection switch. In the first slide switch 44, a movable portion 44a operated by a user is movable in the longitudinal direction of the back surface 1b. Further, the first slide switch 44 is disposed at a substantially center in the longitudinal direction of the back surface 1b, and is disposed at a position close to one end side in the short side direction of the back surface 1b.
In such a first slide switch 44, when the movable portion 44a is moved to one end side (for example, the end portion on which the connection terminal group 4 is not provided), the memory A is selected. When the movable portion 44a is moved to the other end side (for example, the end on the side where the connection terminal group 4 is provided), the memory B is selected.
Further, in the vicinity of the first slide switch 44 on the back surface 1b of the memory card 40, the memory A is selected in which direction the operation unit 44a of the first slide switch 44 is moved, or A memory selection direction mark 45 for allowing the user to recognize whether the memory B is selected is described. Specifically, the selection direction mark 45 has a description indicating a corresponding memory name (“A” or “B”) in the vicinity of each moving position of the movable portion 44a. Such a selection direction mark may be described in the memory card 1 of the first embodiment and the memory card 30 of the second embodiment.
Further, a second slide switch 46 of a two-contact switching type is provided on the back surface 1b of the memory card 40. The second slide switch 46 functions as a switch for switching between a data writing prohibition state and a writing permission state with respect to the IC memory.
The second slide switch 46 has the same size and shape as the first slide switch 44. In the second slide switch 46, a movable portion 46a operated by a user is movable in the longitudinal direction of the back surface 1b. In the second slide switch 46, the back surface 1b is disposed in the longitudinal direction between the connection terminal group 4 and the first slide switch 44, and the back surface 1b is disposed in the short side direction of the first slide switch. 44 and the same position.
The second slide switch 46 enables writing when the movable portion 46a is moved to one end side (for example, the end portion on which the connection terminal group 4 is not provided). The movable portion 46a Is moved to the other end side (for example, the end on the side where the connection terminal group 4 is provided), the writing is prohibited.
FIG. 18 shows an internal block configuration diagram of the memory card 40 of the third embodiment.
The memory card 40 includes a controller 11, a first IC memory (memory A) 12-1, a second IC memory (memory B) 12-2, a memory changeover switch 47, and an erroneous erasure prevention switch. 48.
In the memory card 40, the insertion / extraction detection terminal INS is connected to the ground.
When the memory card 40 is inserted in the host device 2, the controller 11 receives serial data and a bus from the host device 2 via the serial data terminal SD, the bus state terminal BS, and the clock terminal CLK. Transfers state signals and clock terminals. The controller 11 controls data writing and reading with respect to the first IC memory 12-1 and the second IC memory 12-2 based on serial data (actual data and control data) supplied from the host device 2. I do. Further, the controller 11 has a control terminal CNT, and generates a memory control signal indicating the timing of writing and reading data to the IC memory from the control terminal CNT. The controller 11 sets the memory control signal to Low when writing to and reading from the first IC memory 12-1 and the second IC memory 12-2, and performs memory control when writing and reading are not performed. Let the signal be High.
The memory changeover switch 47 is a switch that switches in conjunction with the first slide switch 44 provided outside the housing. The memory changeover switch 47 has one fixed contact 47a and two movable contacts (a first movable contact 47b and a second movable contact 47c). The memory changeover switch 47 connects the fixed contact 47a and any one of the movable contacts 47b to 47c in conjunction with the sliding operation of the movable portion 44a of the first slide switch 44. The fixed contact 47a is connected to the control terminal CNT of the controller 11. The first movable contact 47 b is connected to the chip select terminal CS of the first IC memory 12-1, and is connected to the power supply terminal Vcc via the first pull-up resistor 15. The second movable contact 47 c is connected to the chip select terminal CS of the second IC memory 12-2 and is connected to the power supply terminal Vcc via the second pull-up resistor 16.
Such a memory changeover switch 47 connects the fixed contact 47a and the first movable contact 47b when the movable portion 44a of the first slide switch 44 is switched to a fixed position on one end side, When the movable portion 44a of the first slide switch 44 is switched to the fixed position on the other end side opposite to the one end side, the fixed contact 47a and the second movable contact 47c are connected.
Therefore, when the movable portion 44a of the first slide switch 44 is switched to the fixed position on one end side, the memory control signal from the controller 11 is sent to the chip select terminal of the first IC memory 12-1. The high level is always supplied to the chip select terminal CS of the second IC memory 12-2. That is, when the movable portion 44a of the first slide switch 44 is switched to the fixed position on one end side, data is written to and read from only the first IC memory 12-1. Is called.
When the movable portion 44a of the first slide switch 44 is switched to the fixed position on the other end side, the memory control signal from the controller 11 is sent to the chip select terminal of the second IC memory 12-2. The high level is always supplied to the chip select terminal CS of the first IC memory 12-1. That is, when the movable portion 44a of the first slide switch 44 is switched to the fixed position on the other end side, data is written to and read from only the second IC memory 12-2. Is called.
As described above, the memory changeover switch 47 operates in conjunction with the first slide switch 44 to select one of the two internal IC memories.
The erroneous erasure prevention switch 48 is a switch that switches in conjunction with the second slide switch 46 provided outside the housing. The erroneous erasure prevention switch 48 has one fixed contact 48a and two movable contacts (a first movable contact 48b and a second movable contact 48c). The erroneous erasure prevention switch 48 connects the fixed contact 48 a and any one of the movable contacts 48 b to 48 c in conjunction with the sliding operation of the movable portion 46 a of the second slide switch 46. The fixed contact 48 a is connected to the controller 11. The first movable contact 48 b is connected to the power supply terminal Vcc via the third pull-up resistor 49. The second movable contact 48c is connected to the ground.
Such an erroneous erasure prevention switch 48 connects the fixed contact 48a and the first movable contact 48b when the movable portion 46a of the second slide switch 46 is switched to the fixed position on one end side. When the movable portion 46a of the second slide switch 46 is switched to the fixed position on the other end side opposite to the one end side, the fixed contact 48a and the second movable contact 48c are connected. .
Therefore, the erroneous erasure prevention switch 48 can give High to the controller 11 when the movable portion 46a of the second slide switch 46 is switched to the fixed position on one end side, and is movable. When the portion 46 a is switched to the fixed position on the other end side, Low can be given to the controller 11. When the controller 11 receives a register read command for confirming the state of the memory card 40 from the host device 2, the controller 11 writes the state of the erroneous erasure prevention switch 48 to the internal register, and the contents of this register are transferred to the host via the serial data line. Return to device 2. Based on this content, the host device 2 determines whether the write is permitted from the write prohibited state.
As described above, in the memory card 40 of the third embodiment, the mounting position of the first slide switch 44 for switching the internal IC memory is provided on the back surface 1b. Since the first slide switch 44 is provided on the back surface 1b in this manner, it is impossible for the user to switch from the outside when the memory card 40 is inserted into the host device 2. Accordingly, in the memory card 40 of the third embodiment, a plurality of flash memories are provided inside, and the flash memories can be switched by using an external changeover switch, and data is inserted into the host device 2. In the meantime, the switching by the user is prevented so that the recorded data is not destroyed.
As a method of using the first to third memory cards as described above, when writing to and reading from one IC memory, authentication is performed with a password and writing to the other IC memory is performed. When reading is performed, the IC memory to be used may be distinguished depending on the presence or absence of security so that authentication by a password is not performed. In addition, personal data is recorded in one IC memory, and business data is recorded in the other IC memory, so that the IC memory to be used is distinguished depending on whether it is private data or public data. It may be. Further, when the host device 2 is a digital still camera, the data is recorded in one IC memory, and when the host device 2 is a personal computer, the data is recorded in the other IC memory. The IC memory to be used may be distinguished according to the two types.
In the present invention,By switching a plurality of internal nonvolatile memories with the first switch, the host device is made to recognize each recording area as an independent device. In addition, thisIn the present invention,A contact that does not select any nonvolatile memory is in the middle of switching from a contact that selects an arbitrary nonvolatile memory to a contact that selects another nonvolatile memory.On the first switchWhen the second switch is switched to a contact for selecting the non-volatile memory, the detection terminal is connected to the ground.To detect that a data storage device is installed in the host device.When the first switch is switched to a contact that does not select any nonvolatile memory, the detection terminal is opened.To detect that the data storage device is not installed in the host device..
For this reasonIn the present invention, even if the nonvolatile memory means is switched by operating the first switch with the data storage device attached to the host device, the host device is once attached / detached. Therefore, the nonvolatile memory means can be switched safely. Therefore, in the present invention, with the data storage device attached to the host device,Switching between multiple internal storage areas with a switchWhat you can doThus, the host device can recognize each recording area as an independent device, and the first switch can be switched in a state where the recording device is attached to the host device.
FIG. 1 is an external perspective view of a memory card and its host device according to a first embodiment.
FIG. 2 is a perspective view of the memory card according to the first embodiment viewed from the front side.
FIG. 3 is a perspective view of the memory card according to the first embodiment viewed from the back side.
FIG. 4 is an internal block diagram of the memory card according to the first embodiment.
FIG. 5 is a perspective view of a memory card provided with a rotary switch.
FIG. 6 is a diagram illustrating a switch configuration in a memory card provided with a rotary switch.
FIG. 7 is a perspective view of a memory card provided with a display unit.
FIG. 8 is a block diagram of the inside of a memory card provided with a display unit.
FIG. 9 is a perspective view of the memory card according to the first embodiment provided with an erroneous erasure prevention switch as seen from the back side.
FIG. 10 is a perspective view of a memory card according to a second embodiment viewed from the back side.
FIG. 11 is a diagram for explaining a mounting position of the slide switch 6 of the memory card according to the second embodiment.
FIG. 12 is an internal block diagram of a memory card according to a second embodiment.
FIG. 13 is a perspective view of a memory card according to a second embodiment provided with an erroneous erasure prevention switch as seen from the back side.
FIG. 14 is a perspective view of a memory card according to a second embodiment in which an erroneous erasure prevention switch is provided on a side surface portion, as viewed from the back side.
FIG. 15 is a perspective view of a memory card according to a second embodiment in which the mounting position of the slide switch is changed, as viewed from the back side.
FIG. 16 is a perspective view of a memory card according to a third embodiment viewed from the front side.
FIG. 17 is a perspective view of a memory card according to a third embodiment as viewed from the back side.
FIG. 18 is an internal block diagram of a portable memory card according to a third embodiment.
1,30,40 memory card, 2 host device, 6 slide switch, 11 controller, 12-1, 31-1 first IC memory, 12-2, 31-2 second IC memory, 31-3 third IC memory, 13 first switch, 14 second switch, 21 rotary switch, 22 first light emitting diode, 23 second light emitting diode, 32 memory changeover switch
In a removable data storage device that is detachably attached to a host device,
A plurality of non-volatile memory means in which stored data is not erased even when detached from the host device;
A plurality of contacts, a first switch that selects one of the non-volatile memory means corresponding to the switched contact;
A second switch for switching contacts in conjunction with the switching operation of the first switch;
An interface unit for transmitting / receiving data to / from the host device when mounted on the host device;
A controller that operates based on the data transmitted through the interface unit and reads and writes data to and from one nonvolatile memory means selected by the first switch;
The interface unit is provided with a detection terminal for allowing the host device to determine that the present apparatus is installed,
The first switch, the contact operating section of the first switch is provided in the operable position by the user even when the device to a host device is attached, to select any of the non-volatile memory means an intermediate position of the switching from the contact point to select another of the non-volatile memory means, any of the non-volatile memory means also is provided with a contact which is not selected,
The second switch when said first switch is switched to the contact for selecting one of said nonvolatile memory means connected to the detection terminal to ground, the present device to said host device is detected to be mounted, when said first switch is switched over to a contact that is not selected any of the above non-volatile memory means by opening the detection terminal, the present apparatus to said host device A data storage device that detects that it is not installed .
The nonvolatile memory means has a selection signal input unit to which a selection signal is input, and enables reading and writing of data according to the selection signal given to the selection signal input unit,
The controller and the plurality of nonvolatile memory means are connected by a common bus,
The first switch supplies the selection signal to one of said nonvolatile memory means corresponding to the contact when it is switched over to a contact for selecting the nonvolatile memory means, any of the non-volatile memory 2. A data storage device according to claim 1, wherein said selection signal is not supplied to any of said nonvolatile memory means when the means is switched to a non-selected contact.
2. The data storage device according to claim 1 , further comprising a display unit for displaying to the user the nonvolatile memory means selected by the first switch .
A false erasure prevention switch for switching between a write-inhibited state and a writable state for the nonvolatile memory means;
The controller does not perform a write operation in response to a write command to the nonvolatile memory means given from the host device when the erroneous erasure prevention switch is switched to the write prohibited state, and the erroneous erasure prevention switch 2. The data storage device according to claim 1, wherein when the state is switched to a possible state, a write operation is performed in accordance with a write command to the nonvolatile memory means given from the host device.
5. The data storage device according to claim 4, wherein the operation unit of the erroneous erasure prevention switch is provided at a position where the operation cannot be performed by the user when the device is mounted on the host device.
Provided with a thin plate-like housing in which the plurality of nonvolatile memory means and the controller are disposed,
Operation of the memory selector switch, the data storage device according to claim 1, wherein provided on the main surface of the thin plate-shaped housing.
7. A data storage device according to claim 6, wherein the data capacity of each nonvolatile memory means is described outside the casing.
Each non-volatile memory means is defined with a name for distinguishing from the other non-volatile memory means,
7. The data storage according to claim 6, wherein the name of the non-volatile memory means selected at the moving position is written in the vicinity of each moving position of the operation unit of the first memory selection switch outside the casing. apparatus.
Comprises three or more of the non-volatile memory means,
Operation of the memory selector switch, the data storage device according to claim 1, wherein the rotary switch.
The plurality of nonvolatile memory means, the data storage device according to claim 1, wherein is configured to include a different type of memory device.
A host device,
A removable data storage device detachably attached to the host device,
The data storage device is provided with a plurality of non-volatile memory means in which stored data is not erased even when detached from the host device, and a plurality of contacts. A first switch for selecting one of the nonvolatile memory means corresponding to the switched contact; a second switch for switching the contact in conjunction with the switching operation of the first switch; An interface unit that transmits / receives data to / from the host device when mounted on the host device, and operates based on the data transmitted through the interface unit, and is selected by the first switch A controller for reading and writing data to and from the one non-volatile memory means,
The interface unit is provided with a detection terminal for causing the host device to determine that the data storage device is mounted,
The first switch is provided at a position where the operation unit of the first switch can be operated by a user even when the data storage device is mounted on the host device, and the arbitrary first nonvolatile switch is connected to the first switch. A contact that does not select any nonvolatile memory means is provided at an intermediate position of switching from a contact to be selected to a contact that selects the other nonvolatile memory means,
The second switch connects the detection terminal to the ground when the first switch is switched to a contact for selecting any one of the nonvolatile memory means, and stores the data in the host device. When the first switch is switched to a contact not selected by any nonvolatile memory means, the detection terminal is opened, and the data is sent to the host device. Detect that the storage device is not installed,
The host device detects that the data storage device is attached when the detection terminal is connected to the ground, and if the data storage device is not attached when the detection terminal is open. Data recording system to detect.
JP2003002653A 2002-11-15 2003-01-08 Data storage device and data recording system Active JP4238580B2 (en)
JP2002332699 2002-11-15
JP2003002653A JP4238580B2 (en) 2002-11-15 2003-01-08 Data storage device and data recording system
EP03754012A EP1562199B1 (en) 2002-11-15 2003-10-07 Memory card with a plurality of memory chips and a changeover switch
CN 200380100108 CN100472642C (en) 2002-11-15 2003-10-07 Data memory
DE2003616462 DE60316462T2 (en) 2002-11-15 2003-10-07 Memory card with several memory chips and a switch
US10/499,646 US7490198B2 (en) 2002-11-15 2003-10-07 Data storage apparatus that includes a plurality of nonvolatile memories in which no data is erased after the data storage apparatus is removed from a host apparatus
EP07015398A EP1847947A3 (en) 2002-11-15 2003-10-07 Data memory
KR1020047010995A KR100985096B1 (en) 2002-11-15 2003-10-07 Data memory
EP07015399A EP1847948A3 (en) 2002-11-15 2003-10-07 Data memory
EP07015400A EP1847946A3 (en) 2002-11-15 2003-10-07 Data memory
PCT/JP2003/012846 WO2004047111A1 (en) 2002-11-15 2003-10-07 Data memory
JP2004213574A JP2004213574A (en) 2004-07-29
JP4238580B2 true JP4238580B2 (en) 2009-03-18
ID=32328305
JP2003002653A Active JP4238580B2 (en) 2002-11-15 2003-01-08 Data storage device and data recording system
US (1) US7490198B2 (en)
EP (4) EP1562199B1 (en)
JP (1) JP4238580B2 (en)
KR (1) KR100985096B1 (en)
CN (1) CN100472642C (en)
DE (1) DE60316462T2 (en)
WO (1) WO2004047111A1 (en)
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2003-01-08 JP JP2003002653A patent/JP4238580B2/en active Active
2003-10-07 WO PCT/JP2003/012846 patent/WO2004047111A1/en active IP Right Grant
2003-10-07 EP EP03754012A patent/EP1562199B1/en not_active Expired - Fee Related
2003-10-07 CN CN 200380100108 patent/CN100472642C/en not_active IP Right Cessation
2003-10-07 EP EP07015398A patent/EP1847947A3/en not_active Withdrawn
2003-10-07 DE DE2003616462 patent/DE60316462T2/en active Active
2003-10-07 EP EP07015399A patent/EP1847948A3/en not_active Withdrawn
2003-10-07 EP EP07015400A patent/EP1847946A3/en not_active Withdrawn
2003-10-07 US US10/499,646 patent/US7490198B2/en not_active Expired - Fee Related
2003-10-07 KR KR1020047010995A patent/KR100985096B1/en not_active IP Right Cessation
EP1562199B1 (en) 2007-09-19
EP1562199A1 (en) 2005-08-10
DE60316462D1 (en) 2007-10-31
CN1685436A (en) 2005-10-19
EP1847946A2 (en) 2007-10-24
CN100472642C (en) 2009-03-25
KR100985096B1 (en) 2010-10-04
KR20050084759A (en) 2005-08-29
WO2004047111A1 (en) 2004-06-03
US20050086433A1 (en) 2005-04-21
EP1847947A3 (en) 2008-07-23
EP1847948A3 (en) 2008-07-23
JP2004213574A (en) 2004-07-29
EP1847948A2 (en) 2007-10-24
US7490198B2 (en) 2009-02-10
EP1847946A3 (en) 2008-07-23
EP1847947A2 (en) 2007-10-24
DE60316462T2 (en) 2008-06-19
EP1562199A4 (en) 2006-03-08
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2005-10-14 A621 Written request for application examination
2009-01-15 FPAY Renewal fee payment (event date is renewal date of database)