`Shinohara
`
`USOO5687346A
`[11] Patent Number:
`[45] Date of Patent:
`
`5,687,346
`Nov. 11, 1997
`
`[54] PC CARD AND PC CARD SYSTEM WITH
`DUAL PORT RAM AND SWITCHABLE
`REWRITABLE ROM
`
`7/1996 Fletcher 61 a1. ....................... .. 395/309
`5,537,558
`8/1996 Nakajima et a1. .
`364/443
`5,544,087
`5,574,929 11/1996 Pieterse et a1. ....................... .. 395/800
`
`[75] Inventor: Takayuki Shinohara, Itami, Japan
`
`[73] Assignee: Mitsubishi Denki Kabushiki Kaisha,
`Tokyo Japan
`
`Exa ' —F ank J. A ta
`P '
`.
`nmary
`mmer .r
`s.
`Attome); Agent, or F1rm-—Leydig, Vo1t & Mayer, Ltd.
`
`[21] Appl. No.: 535,639
`[22] Filed:
`Sep. 28, 1995
`30
`F _ A H ? Pri _ D m
`[
`]
`orelgn pp ca on
`Duty 3
`Sep.30, 1994
`[JP]
`Japan .................................. .. 6-237858
`[51] Int. Cl.6 .................................................... .. G06F 13/00
`[52] us. Cl. .................. .. 395/430; 395/200.08; 395/280;
`395/311; 395/442; 395/458; 395/476; 364/DIG. 1
`[58] Field of Search ............................. .. 395000.08, 280,
`395/311, 430, 442, 453, 476
`,
`References Cited
`US. PATENT DOCUMENTS
`
`[56]
`
`[57]
`
`ABSTRACT
`
`The present invention relates to a PC card comprising: a
`CPU;amem0ry storinganoperating programfor said CPU;
`interface means connected to a host system for performing
`con?guration under the control of said host system and
`exchanging data with Said host system; anda dual POItRAM
`connectcd bctwecn Said CPU and Said imrfmve means for
`storing at a time all of data inputted from and outputting to
`said host system through said interface means, wherein said
`data being accessed sequentially by said CPU. This inven
`tion resides in a PC card system comprising the PC card and
`a host System.
`
`5,359,570 10/1994 Hsu et a1. ........................ .. 365/23001
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`8 Claims, 6 Drawing Sheets
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`US. Patent
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`Nov. 11, 1997
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`US. Patent
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`Nov. 11, 1997
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`Nov. 11, 1997
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`Nov. 11, 1997
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`Nov. 11, 1997
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`5,687,346
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`Exhibit 2016 - Page 06 of 12
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`Exhibit 2016 - Page 06 of 12
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`US. Patent
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`Nov. 11, 1997
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`Exhibit 2016 - Page 07 of 12
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`Exhibit 2016 - Page 07 of 12
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`
`1
`PC CARD AND PC CARD SYSTEM WITH
`DUAL PORT RAM AND SWITCHABLE
`REWRITABLE ROM
`
`5,687,346
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`2
`accesses the PC card 1, and in detail, to the attribute memory
`6 through the address bus 2, control bus 3, and data bus 4 to
`read attribute information from the PC card 1. In addition,
`based on the content of the attribute information, the host
`system 100 selects a function that the host system 100 wants
`to execute, that is, the I/O functions. Additionally, the host
`system 100 initializes the I/O register 9 through the address
`decoder 8 by using the con?guration register 7. Thereby, the
`host system 100 is connected to the card inner bus 11
`through the I/O register 9, and the PC card 1 is con?gured
`so as to be able function as an 110 card.
`Once the PC card 1 is con?gured, the PC card responds
`only to the I/O access to the address in the I/O register 9
`which the host system 100 designates. Speci?cally, when the
`host system 100 sets parameters and inputs a command to
`each address in the I/O register 9 which is designated in the
`address bus 2, the CFU 12 starts processing according to the
`parameters and the command. Until the CPU 12 completes
`the processing, the PC card 1 continues to send a busy
`signal, to the host system 100 using a status register (not
`shown), which indicates that the PC card 1 is in a busy state.
`The status register may be provided, for example, in the I/O
`register 9. When the CPU 12 completes the processing, it
`generates an interrupt signal to the host system 100 to
`request the next process. For example, if the command input
`to the I/O register 9 requires data, ?rst, the CPU 12 executes
`the command so as to determines whether the command
`requires data, while sending the busy signal to the host
`system 100. In addition, the CPU 12 generates an interrupt
`signal to the host system 100, and requests the data from the
`host system 100. In this time, after a host CPU (not shown)
`in the host system 100 outputs the command, the host CPU
`needs to wait the data output until the CPU 12 execute the
`command and requests the data.
`Regarding a known PC card, as described above, its I/O
`access speed depends on the processing speed of the CPU 12
`in the PC card 1. Therefore, the known PC card has a
`problem in that the host CPU (not shown) in the host system
`100 needs to wait until the CPU 12 completes processing.
`In addition, in a known PC card, even in the case that later
`or updated versions of software in the PC card 1 become
`necessary, there are only two options, one of which is to
`change the PC card to the new one, the other of which is to
`exchange the built-in ROM 13 by dismantling the PC card
`1. This inconvenience results from the fact that contents of
`the ROM 13 storing the software in the PC card, that is,
`instruction codes (operating program) for the CPU 12 can be
`written only in a manufacturing step, but it is impossible to
`rewrite the contents after shipping. Therefore, the known PC
`card has another problem that updating of the software is not
`easy.
`
`SUMMARY OF THE INVENTION
`
`The present invention provides a solution to the above
`described problems. Accordingly, an object of the present
`invention is to provide a PC card and PC card system in
`which it is possible to input to a PC card all of the
`infon'nation necessary for I/O operation at one time while
`making the I/O access speed between a host system and the
`PC card independent from the processing speed of a CPU in
`the PC card, and consequently, to provide the PC card and
`PC card system having upgraded processing speed as a
`whole system. Moreover, another object of the present
`invention is provide a PC card and a PC card system that can
`realize easy updating of software in the PC card without
`dismantling the PC card.
`
`65
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`BACKGROUND OF THE INVENTION
`1. Field of the Invention
`The present invention relates to a PC card and, more
`particularly, to a PC card incorporating a CPU. The present
`invention also relates to a PC card system.
`2. Description of the Related Art
`The use of external memory media for electronic equip
`ment such as personal computers, and card-shaped devices
`for realizing I/O functions, PC cards, which include memory
`cards and 110 cards, have become widespread. A PC card 1,
`as shown in FIG. 5, is usually inserted into a PC card slot
`102, and is electrically connected through a connector 1a to
`internal circuits (not shown) in a host system 100 such as a
`personal computer. Recently, standardization of speci?ca
`tion for the PC card 1 has been continued mainly by IElDA
`(Japan Electronic Industry Development Association) in
`Japan and PCMCIA (Personal Computer Memory Card
`International Association) in the USA (See IEIDA: PC Card
`Guideline Ver. 4.2, and PCMCIA: PC Card Standard Rel
`2.1).
`FIG. 6 is a block diagram illustrating the structure of a
`known PC card 1 for realizing I/O functions based on these
`standard speci?cations. As shown in FIG. 6, the above
`described connector 1a of the PC card 1 is provided with 68
`pins of socket contacts (not shown). These contacts are used
`as an address bus 2 where address data is input from the host
`system 100, a control bus 3 where control signals are input,
`a data bus 4 for exchanging data with the host system 100,
`and the like. In addition, a PC card interface circuit 5 is
`disposed in the PC card 1 in order to realize the standardized
`PC card interface. The PC card interface circuit 5 is com
`prises an attribute memory 6, a card con?guration register 7,
`and an address decoder 8. The attribute memory for 6 is a
`memory storing attribute information such as various func
`tions (memory functions, I/O functions, and the like) of the
`PC card 1 in a table, i.e. the functions that can be set. In
`addition, the card con?guration register 7 is a register for
`initializing an I/O register 9 which will be described later.
`The connector 1a and PC card interface circuit 5 comprise
`interface means for performing con?guration of the PC card
`1 under the control of the host system 100 and exchanging
`data with the host system 100 (namely, performing inputting
`data from and outputting data to the host system 100).
`The U0 register 9 is connected to the PC card interface
`circuit 5 and data bus 4, and to a card inner bus 11 that is
`provided in the PC card 1, as shown in FIG. 6. In addition,
`a CPU 12 controlling I/O functions, ROM 13 storing instruc
`tion codes (operating program) for operating the CPU 12,
`RAM 14 storing data, an I/O port 15 for communicating
`with external equipment (not shown) such as communica
`tion equipment are connected to the card inner bus 11. ‘The
`I/O port 15 is connected to an external communication line
`104 provided in the above-described external equipment for
`communication through a back connector 16 which is
`mounted at the opposite side of the connector 1a.
`The operation of a PC card and a PC card system is
`described below. In a known PC card that is constructed as
`described above, based on the procedure de?ned in the
`standard speci?cation, an initialization generally known as a
`“con?guration” is performed. Hereinafter, the case where
`the PC card 1 is con?gured so as to be able to perform I/O
`functions will be described First, the host system 100
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`Exhibit 2016 - Page 08 of 12
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`10
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`20
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`25
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`3
`In accordance with a ?rst aspect, the present invention is
`directed to a PC card and a PC card system The PC card and
`PC card system comprises a CPU, a memory storing an
`operating program for the CPU an interface means con
`nected to a host system for performing con?guration under
`the control of the host system and performing data input
`from and data output to the host system, and dual port RAM
`connected between the CPU and interface means for storing
`all of the data input from or output to the host system
`through the interface means at a single time, the data being
`accessed sequentially by the CPU.
`In accordance with a second aspect, the present invention
`is directed to a PC card and a PC card system. The PC card
`and PC card system comprising memory composed of
`nonvolatile memory that is rewritable, and dedicated rewrit
`ing means connected between the memory and the interface
`means for rewriting the operating program under the control
`of the host system.
`In accordance with a third aspect, the present invention is
`directed to a PC card and a PC card system The PC card and
`PC card system comprising switching means connected
`between the dedicated rewriting means and memory for
`switching between connecting/disconnecting (make and
`break of connection) between the dedicated rewriting means
`and the memory.
`In accordance with a fourth aspect, the present invention
`is directed to a PC card and a PC card system. The PC card
`and PC card system comprises ?rst switching control signal
`output means for outputting a switching control signal to the
`switching means under the control of the host system
`In accordance with a ?fth aspect, the present invention is
`directed to a PC card and a PC card system The PC card and
`PC card system comprising input means for receiving an
`external signal input from the outside, and second switching
`control signal output means for outputting a switching
`control signal to the switching means according to the
`external signal input to the input means.
`According to a sixth aspect of the present invention, a PC
`card is provided with a back connector that includes input
`means.
`In the ?rst aspect of the present invention that is con
`structed as described above, when the host system inputs all
`of the information necessary for one I/O operation to the
`dual port RAM at a time, processing of the U0 operation is
`45
`transferred to the CPU in the PC card. The CPU in the PC
`card sequentially accesses the dual port RAM received the
`information, and advances processing while reading the
`information necessary for the I/O operation. In this time,
`since the host system has already input all of the information
`necessary for one I/O operation to the dual port RAM, the
`host system can move to another process without waiting
`processing completion of the CPU in the PC card
`In the second aspect of the present invention, since the
`memory storing the operating program for the CPU in the
`PC card comprises the nonvolatile memory that is electri
`cally rewritable, the operating program can be rewritten with
`the dedicated rewriting means under the control of the host
`system without dismantling the PC card even if an updated
`version of the operating program for the CPU becomes
`necessary after shipping.
`
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`BRIEF DESCRIPTION OF THE DRAWINGS
`The present invention will become more readily apparent
`from the following detailed description of the preferred
`embodiments of the present invention taken in conjunction
`with the accompanying drawings, in which:
`
`5,687,346
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`4
`FIG. 1 is a block diagram showing the structure of a PC
`card according to a ?rst embodiment of the present inven
`tion;
`FIG. 2 is a block diagram showing the structure of a PC
`card according to a second embodiment of the present
`invention;
`FIG. 3 is a partially enlarged diagram showing the
`memory and bus switch in FIG. 2;
`FIG. 4 is a block diagram showing the structure of a PC
`card according to a third embodiment of the present inven
`tion;
`FIG. 5 is a schematic perspective diagram showing a
`privately known PC card system composed of a host system
`and a PC card; and
`FIG. 6 is a block diagram showing the structure of a
`privately known PC card.
`‘
`
`DETAILED DESCRIPTION OF THE
`PREFERRED EMBODIMENTS
`
`EMBODIMENT l
`Hereinafter, an embodiment of the present invention will
`be described with reference to the drawings. FIG. 1 shows
`a block diagram of a PC card according to one embodiment
`of the present invention. In this embodiment, a dual port
`RAM 10 is provided The dual port RAM 10 can be accessed
`by a host CPU via a bus 20 comprising an address bus 2, a
`control bus 3, and a data bus 4, and also be accessed by a PC
`card inner bus 11. Here, the host CPU bus 20 is connected
`to 68 pins of socket contacts (not shown) provided in the
`connector 1a as shown in the known example'for connecting
`a host CPU (not shown) in a host system 100 to a PC card
`21. In addition, in this embodiment, similar to the known
`example (FIG. 6), the connector 1a and a PC card interface
`circuit 5 also comprise interface means for con?gming the
`PC card 1 under the control of the host system 100 and
`performing the input and output of data between the host
`system 100 and PC card 21. The other components are the
`same as those in the known example (FIG. 6), and hence
`description regarding them is omitted.
`Similarly to the known example, when the PC card 21 is
`con?gured as an 110 card, 110 access through an I/O register
`9 becomes available. However, as described above, I/O
`access speed through the I/O register 9 is limited by the
`processing speed of the CPU 12, and this causes the problem
`that the host CPU (not shown) in the host system 100 needs
`to wait during the processing time of the CFU 12. Therefore,
`in this embodiment, the dual port RAM 10 is provided
`between the host CPU bus 20 and the card inner bus 11. The
`RAM can be accessed by both of the host CPU (not shown)
`in the host system 100 and the CPU 12 in the PC card 21.
`Accordingly, the dual port RAM 10 makes it possible to
`receive set values of all of the parameters, command input,
`and data input in one high-speed write cycle, which are
`necessary for an I/O function requested by the host system
`100, without depending on the processing speed of the CPU
`12.
`Operation of this embodiment is described below. First,
`the PC card 21 is con?gured by the PC card interface circuit
`5 so that the PC card 21 may perform an I/O operation using
`the dual port RAM 10. When all of the information such as
`set values of parameters, command input, and data input,
`which are necessary for one I/O operation are input from the
`host CPU (not shown) in the host system 100 to the dual port
`RAM 10, processing of the I/O operation is transferred to the
`CPU 12. The CPU 12 sequentially accesses the dual port
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`Exhibit 2016 - Page 09 of 12
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`RAM 10 according to the instruction codes in a ROM 13,
`and advances and executes processing while reading the
`information necessary for the I/O operation. During the
`processing operation of the CPU 12, the PC card 21 remains
`busy. However, since the host system 100 has already input
`all of the information necessary for one I/O operation to the
`dual port RAM 10, the host CPU can move to another
`processing function without waiting for process operation
`completion in the CPU 12.
`As described above, according to the present invention,
`the provision of the' dual port RAM 10 between the host
`CPU in the host system 100 and the CPU 12 makes one I/O
`operation in the viewpoint of the host CPU complete at
`high-speed without waiting for process completion of the
`CPU 12 in the PC card 21, and enables the host CPU to
`move to another processing. Therefore, processing function
`- speed, as a whole system composed of the host system 100
`and PC card 21, is upgraded.
`In addition, although, in FIG. 1, both of the known I/O
`register 9 and the dual port RAM 10 according to the present
`invention are illustrated, the I/O register 9 is not essential.
`Furthermore, of the I/O register 9 and dual port RAM 10 is
`used for the I/O operation, it can be selectable in time of the
`PC card 21. The PC card 51 according to the present
`invention can be used in the con?guration a known host
`system 100 where only con?guration using the I/O register
`9 is available. Therefore, general versatility of the PC card
`21 can be increased.
`EMBODIMENT 2
`FIG. 2 is a block diagram showing the structure of a
`second embodiment of the present invention, and FIG. 3 is
`a detailed diagram of a bus switch utilized in the second
`embodiment illustrated in FIG. 2. In this embodiment,
`nonvolatile memory 13A is provided, which is composed of
`electrically readable, writable and erasable memory such as
`?ash memory or EEPROM, instead of the ROM 13 in FIG.
`1. This change results in that the contents of the nonvolatile
`memory 13A can be rewritten by the host system 100. In
`addition, as shown in FIG. 3, a bus switch 31, which is
`connected to the inner card bus 11 and host CPU bus 20 and
`serves as switching means for switching between both of the
`buses, namely for switching connecting/disconnecting
`between the host CPU bus 20 and the nonvolatile memory
`13A, is connected to the nonvolatile memory 13A through
`an address input 17, a control input 18, and a data input 19.
`In this embodiment, the host CPU bus 20 includes an
`address bus 20a, a control bus 20b, a data bus 20c, and a
`below-described signal line 32 in addition to the address bus
`2, control bus 3, and data bus 4.
`In this embodiment, the address bus 20a, control bus 20b,
`and data bus 200 comprise dedicated rewriting means for
`connecting the nonvolatile memory 13A to the interface
`means comprised of the connector 1a and PC card interface
`circuit 5, and rewriting the contents of the nonvolatile
`memory 13A through the interface means under the control
`of the host system 100. In addition, in this embodiment, the
`switching means comprises the above-described bus switch
`31, switching between the card inner bus 11 and host CPU
`bus 20, for connecting one of them to the nonvolatile
`memory 13A. Alternatively, the switching means may com
`prise a switch simply switching between connecting/
`disconnecting between the host CPU bus and nonvolatile
`memory 13A. In addition, in that case, a prohibiting means
`for prohibiting access ?-om the card inner bus 11 may be
`provided, when needed.
`The inner card bus 11 comprises an address bus 11a, a
`control bus 11b, and a data bus 110. As shown in FIG. 3, the
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`bus switch 31 comprises a plurality of switches having input
`terminals 31a and 31b and I/O terminal 31c, to which the
`above-described address buses 20a and 11a, control buses
`20b and 11b, and data buses 20c and 11c are connected.
`Further, output terminals 31d and 31e and an I/O terminal
`31f are connected to the address input 17, control input 18,
`and data input 19. Here, the bus switch 31 or the switch 31
`comprises three switches corresponding to the address buses
`20a and 11a, control buses 20b and 11b, and data buses 20c
`and 110 for simpli?cation of the drawing. However, actually,
`the bus switch 31 comprises any number of switches cor
`responding to the particular application.
`The bus switch 31 is provided with a signal line 32 that
`is a ?rst switching-control-signal output means for output
`ting a switching control signal under the control of the host
`system 100. The switching control signal switches the bus
`switch 31. The bus switch 31 performs switching with the
`switching control signal input from the host system 100
`through the signal line 32. In addition, the ?rst switching
`control-signal output means may be designed so that the
`switching control signal may be output with the other
`method except the control of the host system 100. Further,
`if, in case of using control of the host system 100, the
`switching control signal is output only when a predeter
`mined identi?cation code is input through the signal line 32
`from the host system 100, it can be prevented that the
`contents of the nonvolatile memory 13A are unintentionally
`rewritten due to an operational mistake and the like. The
`residual structure is similar to the above-described ?rst
`embodiment, and hence description regarding it is omitted.
`Operation of the embodiment is described subsequently.
`In this embodiment, as shown in FIG. 2, the address input
`17, control input 18, and data input 19 in the nonvolatile
`memory 13A are usually connected to the card inner bus 11
`by the bus switch 31, and are accessed through the card inner
`bus 11. However, if updated versions of the software for the
`PC card 21 become necessary, the host system 100 inputs the
`switching control signal to the bus switch 31 through the
`signal line 32 serving as the ?rst switching-control-signal
`output means. Therefore, the bus switch 31 switches to the
`address bus 20a, control bus 2%, and data bus 200. Further,
`the host system 100 directly accesses the nonvolatile
`memory 13A to rewrite the instruction codes (operating
`program) for the CPU 12 that is stored in the nonvolatile
`memory 13A.
`As described above, according to this embodiment, the
`contents of the nonvolatile memory 13A storing the oper
`ating program for the PC card 21 can be easily rewritten
`without dismantling the PC card 21, by storing the instruc
`tion codes (operating program) for the CPU 12 in the PC
`card 21 in the nonvolatile memory 13A that is electrically
`rewritable, and by enabling the input terminals 31a and 31b,
`and I/O terminal 310 , which are connected to the nonvola~
`tile memory 13A, to be switched to the host CPU bus 20 by
`the bus switch 31.
`EMBODIMENT 3
`FIG. 4 shows a modi?ed example of the above-described
`second embodiment. In the above-described second
`embodiment, the switching control signal output means 32
`is described as the signal line 32 connected between the host
`system 100 and bus switch 31. However, in this
`embodiment, as shown in FIG. 4, a back connector 16 and
`the bus switch 31 are connected through the signal line 34,
`and using a free pin (not shown) of the back connector 16,
`the switching control signal for switching the bus switch 31
`is input from the outside through the free pin and the signal
`line 34. Therefore, second switching-control-signal output
`
`Exhibit 2016 - Page 10 of 12
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`
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`5,687,346
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`10
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`25
`
`7
`means disposed in this embodiment comprises the free pin
`of the back connector 16 and the signal line 34. In addition,
`the free pin of the back connector 16 comprises input means
`for receiving an external signal. The residual structure is
`similar to the above-described second embodiment, and
`hence description regarding it is omitted.
`Originally, the contents of the nonvolatile memory 13A
`storing the operating program for the CPU 12 in the PC card
`21 should not be frequently rewritten, and troubles caused
`by end-user’s writing error may happen. Therefore, it should
`be con?gured such that end-users cannot rewrite the con
`tents. Then, as shown in this embodiment, the PC card is
`designed so that a signal is input from the free pin of the
`back connector 16, a special jig, such as a special connector
`in which a free pin which is usually free is not free, becomes
`necessary when contents of the nonvolatile memory 13A are
`written. Therefore, easy rewriting by end-users and troubles
`due to rewriting errors can be prevented.
`According to the above-mentioned ?rst aspect of the
`present invention, when the host system inputs all of the
`information necessary for an I/O operation to the dual port
`RAM at one time, processing of the I/O operation is trans
`ferred to the CPU in the PC card. The CPU in the PC card
`sequentially accesses the dual port RAM receiving the
`information, and advances processing while reading the
`information necessary for the I/O operation. In this time,
`since the host system has already input all of the information
`necessary for one I/O operation to the dual port RAM, the
`host system can move to another processing further without
`Waiting processing completion of the CPU in the PC card.
`Therefore, the CPU can make one complete I/O operation in
`the viewpoint of the host CPU in shorter time, and hence the
`processing speed of the whole system can be upgraded.
`According to the second aspect of the present invention,
`since the memory storing the operating program for the CPU
`35
`in the PC card comprises the nonvolatile memory that is
`electrically rewriteable, the operating program can be
`rewritten with the dedicated rewriting means under the
`control of the host system without dismantling the PC card
`even if updated version of the operating program for the
`CPU become necessary after shipping.
`According to the third aspect of the present invention, by
`switching connecting/disconnecting (make and break of
`connection) between the dedicated rewriting means and the
`memory with the switching means, permission and prohi
`bition of rewriting of the operating program in the memory
`by the host system are controlled. Therefore, if switching by
`means of the switching means is not performed, the oper
`ating program usually cannot be rewritten, and hence rewrit
`ing of the operating program caused by malfunction can be
`prevented.
`According to the fourth aspect of the present invention,
`the ?rst switching control signal output means outputs a
`switching control signal to the switching means under the
`control of the host system, and thereby the switching means
`switches between connecting/disconnecting. Therefore, for
`example, if the PC card is designed so that the switching is
`performed only when a predetermined identification code is
`input it can be prevented that the operating program is
`inadvertently rewritten. In contrast, if such an identi?cation
`code is not set, the switching can be easily done. Hence,
`security and convenience of the PC card can be increased by
`setting the host system to the conditions corresponding to
`the working conditions.
`According to the ?fth aspect of the present invention, an
`external signal is input the input means provided in second
`switching control signal output means, and thereby the
`
`8
`switching control signal is output to the switching means
`according to the external signal input to the input means.
`Therefore, in comparison with switching under the control
`of the host system, rewriting of the operating program
`caused by malfunction can be prevented.
`According to the sixth aspect of the present invention, the
`PC card is provided with a back connector for connection to
`external communication equipment, and a free pin of the
`back connector comprises input means for inputting an
`external signal to the switching control signal output means.
`Therefore, using a special jig such as a special connector that
`a usually free pin is not free, the signal is input, and hence
`easy rewriting by end-users and troubles due to rewriting
`errors can be prevented.
`What is claimed is:
`1. A PC card comprising:
`a CPU;
`‘
`a nonvolatile, rewriteable memory for storing an operat
`ing program for said CPU;
`interface means connectable to a host system for con?g
`uring the PC card under control of the host system and
`for exchanging data with the host system;
`a bus connected to said interface means and connectable
`to said memory for rewriting the operating program in
`said memory under control of the host system;
`switching means connected between and to said bus and
`said memory for selectively connecting said memory to
`said bus and disconnecting said memory from said bus;
`and
`a dual port RAM connected between said CPU and said
`interface means for storing at one time all data input
`from and output to the host system through said inter
`face means, wherein the data stored in said dual port
`RAM is accessed sequentially by said CPU.
`2. The PC card according to claim 1, comprising ?rst
`switching-control-signal output means for outputting a
`switching control signal to said switching means under
`control of the host system.
`3. The PC card according to claim 1 comprising:
`input means for receiving an external signal input from a
`source external to said PC card; and
`second switching-control-signal output means connected
`between and to said input means and said switching
`means for supplying a switching control signal to said
`switching means according to the external signal input
`to said input means.
`4. The PC card according to claim 3 wherein said PC card
`comprises a back connector including said input means.
`5. A PC card system comprising:
`a host system; and
`'
`a PC card including:
`interface means connected to said host system for
`con?guring said PC card under control of said host
`system and for exchanging data with said host sys
`tem;
`a CPU;
`a nonvolatile, rewriteable memory for storing an oper
`ating program for said CPU;
`a bus connected to said interface means and connect
`able to said memory for rewriting the operating
`program in said memory under control of the host
`system;
`switching means connected between and to said bus
`and said memory for selectively connecting said
`memory to said bus and disconnecting said memory
`fr