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| United States Patent |
5,960,445
|
|
Tamori
, et al.
|
September 28, 1999
|
Information processor, method of updating a program and information
processing system
Abstract
BIOS updating is performed after saving an old BIOS to a spare storage
area. A current version BIOS stored in a first bank of a flash ROM is
moved to a second bank of the flash ROM, and a new BIOS supplied from a
home server to a network interface card is stored in the first bank to
complete BIOS updating. If the new BIOS does not run well, the old BIOS in
the second bank of the flash ROM is moved to the first bank through a RAM
to be reinstalled.
| Inventors:
|
Tamori; Hirofumi (Tokyo, JP);
Hiraoka; Daisuke (Kanagawa, JP);
Enoki; Koji (Kanagawa, JP)
|
| Assignee:
|
Sony Corporation (Tokyo, JP)
|
| Appl. No.:
|
842841 |
| Filed:
|
April 17, 1997 |
Foreign Application Priority Data
| Current U.S. Class: |
707/203; 707/202; 713/2; 713/100; 717/172 |
| Intern'l Class: |
G06F 017/30 |
| Field of Search: |
707/201,202,203
348/473,10
714/6
395/653,652,712
713/2,100
|
References Cited [Referenced By]
U.S. Patent Documents
| 5432927 | Jul., 1995 | Grote et al. | 395/652.
|
| 5437018 | Jul., 1995 | Kobayashi | 713/2.
|
| 5530943 | Jun., 1996 | Gericke et al. | 713/2.
|
| 5544356 | Aug., 1996 | Robinson et al. | 707/205.
|
| 5548338 | Aug., 1996 | Ellis et al. | 348/473.
|
| 5619250 | Apr., 1997 | McClelland et al. | 348/10.
|
| 5666530 | Sep., 1997 | Clark et al. | 707/201.
|
| 5752042 | May., 1998 | Cole et al. | 395/712.
|
| 5794054 | Aug., 1998 | Le et al. | 395/728.
|
| 5835760 | Nov., 1998 | Harmer | 395/652.
|
| 5835761 | Nov., 1998 | Ishii et al. | 395/653.
|
| 5838981 | Nov., 1998 | Gotoh | 395/712.
|
| 5864698 | Jan., 1999 | Krau et al. | 395/652.
|
| 5870520 | Feb., 1999 | Lee et al. | 714/6.
|
Other References
IBM Technical Disclosure Bulletin, vol. 38, No. 7, Jul. 1995, New York, US,
p. 551, XP000521789, "Recovery Method for Damaged Firmware."
|
Primary Examiner: Black; Thomas G.
Assistant Examiner: Rones; Charles L.
Attorney, Agent or Firm: Limbach & Limbach L.L.P.
Claims
What is claimed is:
1. A program updating method of updating a current basic program stored in
a main area of storage means by replacing the current basic program with a
new basic program on the basis of an updating program stored in a common
area of the storage means, said method comprising the steps of:
copying to the spare area of the storage means the current basic program
read out from the main area; and
finally writing the new basic program to the main area on the basis of the
updating program.
2. An information processor comprising:
storage means having a main area in which a current basic program is
stored, a common area in which an updating program describing a procedure
for updating the basic program is stored, and a spare area in which the
basic program is stored before it is updated; and
processing means for performing updating on the basis of the updating
program stored in the common area of said storage means, said updating
including copying to said spare area the current basic program read out
from said main area and finally writing a new basic program to said main
area.
3. An information processor according to claim 1, wherein said basic
program comprises a basic input/output system which is a group of
hardware-dependent control programs.
4. An information processor according to claim 1, further comprising
receiving means for receiving information supplied through a predetermined
transmission channel, said receiving means receiving a new basic program
as said information through the transmission channel, said processing
means performing updating on the basis of the updating program stored in
the common area of said storage means, said updating including copying to
the spare area of said storage means the current basic program read out
from the main area of said storage means and finally writing the new basic
program received by said receiving means to the main area of said storage
means.
5. An information processor according to claim 4, wherein said receiving
means receives information about video on-demand service through said
transmission channel.
6. An information processor according to claim 1, wherein said memory means
is formed of an electrically erasable and programmable read-only memory.
7. An information processor according to claim 6, wherein the main and
spare areas of said storage means are allotted as separate banks in one
logical address space, and one of the banks is alternatively selected by
bank changing to be addressed.
8. An information processing system comprising:
information providing means for providing information through a
predetermined transmission channel; and
information processing means for performing updating on the basis of an
updating program stored in a common area of storage means, said updating
including copying to a spare area of the storage means a current basic
program read out from a main area of the storage means and finally writing
to the main area of the storage means a new basic program supplied through
said transmission channel.
9. A program updating method of updating a current basic program stored in
a main area of storage means by replacing the current basic program with a
new basic program on the basis of an updating program stored in a common
area of the storage means, said method comprising the steps of:
saving to a temporary storage area the current basic program read out from
the main area;
writing the current basic program saved to the temporary storage area to a
spare area of the storage means;
collating the current basic program written to the spare area of the
storage means with the current basic program saved to the temporary
storage area;
writing to the temporary storage area a new basic program supplied from an
external source and thereafter writing the new basic program to the main
area of the storage means; and
collating the new basic program written to the main area of the storage
means with the new basic program written to the temporary storage area.
Description
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to an information processor, a method of
updating a program and an information processing system and, more
particularly, to an information processor, a program updating method and
an information processing system suitable for updating a program such as a
basic input/output system (BIOS) via a network.
2. Description of the Related Art
Networks of a kind represented by the Internet have been developed, to
which network users can connect personal computers or the like to obtain
various kinds of information.
A connection to the Internet or the like can be made through a
communication network such as an analog telephone network or the
Integrated Services Digital Network (ISDN). Recently, it has become
possible to gain access to networks including the Internet through cables
of a cable television (CATV) system.
For access to a network such as the Internet, an information processor
having a transmitting and receiving circuit for transmission and reception
through a predetermined communication network is used.
FIG. 9 shows an example of such an information processor using a modem 105
and capable of transmission and reception through an analog telephone
circuit. A central processing unit (CPU) 101 executes various processings
in accordance with programs stored in a flash electrically erasable
programmable ROM (hereinafter referred to simply as "flash ROM") 102.
Necessary data for execution of various processings performed by the CPU
101 and other data are suitably stored in a RAM 103. The CPU 101 receives
data transmitted from the analog telephone circuit by using the modem 105.
The CPU 101 processes the received data and displays, for example,
received image data on a display unit (not shown) through a display
interface 106.
A basic input/output system (BIOS), which is run by the CPU 101 when the
processor is started up, and which is a basic program (a group of
hardware-dependent control programs) for setting a configuration of the
RAM 103 or initialization of a floppy disk drive 104, is stored in the
flash ROM 102 as well as the programs for processing data supplied through
the modem 105. The flash ROM 102 is an electrically erasable and
programmable nonvolatile memory in which stored contents can be changed.
The flash ROM 102 of such an erasable and programmable type is used to
enable the BIOS to be updated according to a change in the specifications
of units connected to the processor or according to updating of the
operating system (OS) of the processor.
The BIOS in this information processor is updated as described below.
First, a predetermined program for updating the BIOS is started and the
BIOS stored in the flash ROM 102 is recorded on a floppy disk by the
floppy disk drive 104. Thereafter, the floppy disk is taken out and
another floppy disk on which a new BIOS is recorded is inserted into the
floppy disk drive 104, and the new BIOS is stored in the flash ROM 102.
The step of recording the former BIOS on a floppy disk in this updating
process is performed for the purpose of reinstalling the former BIOS if
updating of the BIOS ends in failure, for example, if the floppy disk on
which the new BIOS is recorded has such a defect that the new BIOS cannot
be read out, or if the program of the new BIOS has a defect (bug) and
cannot run normally.
However, BIOS updating is performed in a different manner in the case of an
information processor having no floppy disk drive, e.g., a set top box
(STB) used for access to a network such as the Internet through a cable of
a CATV system. For example, in such an information processor, an external
terminal unit is connected to a predetermined terminal provided in the
information processor, and a BIOS is saved to the terminal unit before it
is updated. For such BIOS updating, complicated operations are required.
SUMMARY OF THE INVENTION
In view of the above-described circumstances, an object of the present
invention is to provide an information processor, a program updating
method and an information processing system arranged to save a current
BIOS in a spare storage area before updating of the BIOS in order to
enable the BIOS to be immediately reinstalled if writing of a new BIOS
ends in failure and to prevent the old BIOS from being lost by an
operation error or the like.
To achieve the above-described object, according to one aspect of the
present invention, there is provided an information processor comprising
storage means having a main area in which a current basic program is
stored, a common area in which an updating program describing a procedure
for updating the basic program is stored, and a spare area in which the
basic program is stored before it is updated, and processing means for
performing updating on the basis of the updating program stored in the
common area of the storage means, the updating including copying to the
spare area the current basic program read out from the main area and
finally writing a new basic program to the main area.
According to another object of the present invention, there is provided a
program updating method of updating a current basic program stored in a
main area of storage means by replacing the current basic program with a
new basic program on the basis of an updating program stored in a common
area of the storage means, the method comprising the steps of copying to
the spare area of the storage means the current basic program read out
from the main area, and finally writing the new basic program to the main
area on the basis of the updating program.
According to still another aspect of the present invention, there is
provided an information processing system comprising information providing
means for providing information through a predetermined transmission
channel, and information processing means for performing updating on the
basis of an updating program stored in a common area of storage means, the
updating including copying to a spare area of the storage means a current
basic program read out from a main area of the storage means and finally
writing to the main area of the storage means a new basic program supplied
through the transmission channel.
BRIEF DESCRIPTION OF THE DRAWINGS
FIG. 1 is a diagram showing the configuration of an information providing
system to which an information receiving system of the present invention
is applied;
FIG. 2 is a diagram showing the configuration of an information processor
in home 5-1 shown in FIG. 1;
FIG. 3 is a block diagram showing the internal configuration of home server
11 shown in FIG. 2;
FIG. 4 is a block diagram showing the internal configuration of personal
computer 12-1 shown in FIG. 2;
FIG. 5 is a block diagram showing the internal configuration of STB 16
shown in FIG. 2;
FIG. 6 is a block diagram showing the internal configuration of flash ROM
91 shown in FIG. 5;
FIGS. 7A-7C are diagrams showing the relationship between a logical address
space and a physical address space in flash ROM 91 shown in FIG. 5;
FIG. 8 is a flowchart showing the operation of STB 16 at the time of BIOS
updating;
FIG. 9 is a block diagram showing an example of an information processor
having a recording unit; and
FIGS. 10 through 18 are diagram for explaining the operation of STB 16 at
the time of BIOS updating.
DESCRIPTION OF THE PREFERRED EMBODIMENT
FIG. 1 is a diagram showing the configuration of an information providing
system which is an embodiment of the information processing system of the
present invention. Servers 1-1 and 1-2 (information providing means)
provide information consisting mainly of images and sounds accompanying
the images or other kinds of data and relating to video on-demand (VOD)
services to homes 5-1 to 5-6 through networks. As networks in this system,
a cable television network 2, the Integrated Services Digital Network
(ISDN) 3, an analog telephone circuit 4 are used.
For example, the server 1-1 provides information to a cable television
center 2-1 or 2-2 through the cable television network 2. The cable
television center 2-1 provides the provided information to the homes 5-1
and 5-2 of subscribers for the cable television system. Similarly, the
cable television center 2-2 provides information to the homes 5-1, 5-3,
and 5-4 of subscribers for the corresponding cable television system.
The server 1-1 also provides information through the ISDN 3 or the analog
telephone circuit 4. From each of the homes 5-1 to 5-6, the server 1-1 can
be accessed through the ISDN 3 or the analog telephone circuit 4, and each
home can be provided with information through this network or circuit.
The server 1-2 also provides various kinds of information to the homes 5-1
to 5-6, as does the server 1-1.
This video transmission system may be such that trunks corresponding to
transmission channels are formed of optical fibers, optical fiber nodes
covering 300 to 500 homes are provided, and hybrid fiber coaxes (HFCs),
i.e., coaxial cable for information transmission are used between the
optical fiber nodes and the homes. Alternatively, a fiber-to-the-curve
(FTTC) system may be formed in which information is transmitted to a
pedestal (repeater) covering 24 homes or so, i.e., a vicinal area about
one home through an optical fiber and is transmitted form the pedestal to
each home through a coaxial cable, or a fiber-to-the-home (FTTH) system
may be formed in which information is transmitted to homes through optical
fibers.
In the embodiment shown in FIG. 1, the transmission capacity of the cable
television network 2 is larger than that of the ISDN 3, which is larger
than that of the analog telephone circuit 4. Accordingly, if the cable
television network 2 is used, moving images highest in quality and in
moving speed can be received in a real time manner at each home. In the
case of using the ISDN 3, ordinary moving images, which do not move so
quickly as those receivable through the cable television network 2, can be
received in a real time manner. However, moving images cannot be received
in a real time manner through the ISDN 3 if they move at an excessively
high speed. In contrast, in the case of using the analog telephone circuit
4, moving images cannot be received and only still images can be received
since the transmission capacity is small. Audio signals can be received in
a real time manner by using each of the above-described networks.
FIG. 2 shows the configuration of an information receiving system provided
in the home 5-1. Information processing systems (not shown) which are
basically the same as that provided in the home 5-1 are also provided in
the other homes.
A home server 11 connects to the cable television network 2, the ISDN 3 and
the analog telephone circuit 4 and connects at least one of these networks
to a personal computer 12-1, a personal computer 12-2, an STB 16
(information processing means) or a telephone set 18.
A keyboard 14-1 and a mouse 15-1 are connected to the personal computer
12-1 to input various instructions. Images output from the personal
computer 12-1 as desired are displayed on a display unit 13-1.
Similarly, a keyboard 14-2 and a mouse 15-2, and a display 13-2 are
connected to the personal computer 12-2.
The STB 16 receives image data supplied from the home server 11,
demodulates the received image data and outputs the demodulated data to a
television receiver 17 to display corresponding images. The STB 16 is also
used for a video on-demand (VOD) service for providing programs in
response to user's requests. The telephone set 18 enables telephonic
communication through the home server 11.
FIG. 3 shows the configuration of components of the home server 11. A CPU
31 executes various processings in accordance with programs stored in a
ROM 32. Necessary data for execution of various processings performed by
the CPU 31 and other data are suitably stored in a RAM 33. A hard disk
drive 34 records information on its internal hard disk and reproduces
information from the hard disk.
The home server 11 has various interfaces. Each of network interfaces 35 to
37 interfaces with the cable television network 2, the ISDN 3 or the
analog telephone circuit 4 for data exchange with the same. An STB
interface 38 interfaces with the STB 16 in an asynchronous transfer mode
(ATM). A computer interface 39 is connected to the personal computer 12-1
and interfaces for Ethernet communication. A computer interface 40 is
connected to the personal computer 12-2 and interfaces in accordance with
special protocols for the personal computer 12-2. A telephone interface 41
interfaces with the telephone set 18.
FIG. 4 shows the configuration of components of the personal computer 12-1.
A CPU 71 executes various processings in accordance with programs stored
in a ROM 72. Necessary data for execution of various processings performed
by the CPU 71 and other data are suitably stored in a RAM 73. A hard disk
drive 74 records information on its internal hard disk and reproduces
information from the hard disk. A floppy disk drive 75 executes processing
for recording information on a floppy disk or reproducing information from
a floppy disk.
A home server interface 76 interfaces with the home server 11. A keyboard
interface 77 and a mouse interface 78 interface with the keyboard 14-1 and
the mouse 15-1, respectively. A display interface 79 interfaces with the
display 13-1.
The personal computer 12-2 is constructed in the same manner as the
personal computer 12-1.
FIG. 5 shows the configuration of components of the STB 16, which is an
information processor, and which represents an embodiment the present
invention. A CPU 51 (processing means) executes various processings in
accordance with programs stored in a flash ROM 91 (storage means) mounted
on a flash ROM board 52. Necessary data for execution of various
processings performed by the CPU 51 and other data are suitably stored in
a RAM 53. A graphic controller 54 is supplied with graphic data from the
CPU 51 and outputs the graphic data to the television receiver 17 to
display the data. A Moving Picture Experts Group (MPEG) 2 video decoder 55
and an MPEG audio decoder 56 respectively decode video data and audio data
supplied from the home server 11 through a network interface card 57
(receiving means) by MPEG 2 and MPEG systems, and output the decoded data
to the television receiver 17 to display images and to radiate sounds.
The network interface card 57 is connected between the STB 16 and the home
server 11 to interface with the home server 11. A smart card interface 58
interfaces with a smart card 59, which is detachably attached to the STB
16 when necessary. Personal information of the card user, key information
for scrambling data, accounting information and the like are stored in the
smart card 59.
A joystick interface 60 interfaces with a game machine 61 connected to the
STB 16. An infrared ray (IR) remote commander interface 62 receives an
infrared ray (IR) signal from a remote commander 63 and outputs a
corresponding command to the CPU 51.
A BIOS (a group of hardware-dependent control programs in the operating
system run by the CPU 51), which is a group of basic programs run by the
CPU 51 at the time of a start-up of the information processor to set a
configuration of RAM 53 and to control data exchange with an external unit
such as game machine 61, is stored in the flash ROM 91 mounted on the
flash ROM board 52 along with the programs for processing data supplied
through the network interface card 57. The flash ROM 91 on the flash ROM
board 52 is an electrically erasable and programmable nonvolatile memory
in which stored contents can be changed, and which maintains stored
contents even after turning-off of the power supply. The flash ROM 91 of
such an electrically erasable and programmable type is used to enable the
BIOS to be updated according to one's need. A new BIOS is transmitted from
the server 1-1 or server 1-2 to be supplied to the STB 16 through a
predetermined communication circuit and through the home server 11 and is
received by the network interface card 57 of the STB 16.
FIG. 6 shows the configuration of the flash ROM board 52. The flash ROM 91
is an erasable and programmable nonvolatile memory for storing data in the
program form and other data. The flash ROM 91 is used as two banks: a bank
A 91a (main area) and a bank B 91b (spare area). The bank A 91a and the
bank B 91b are used as one logical address space by the CPU 51. That is,
as shown in FIG. 7A, two physical address spaces (bank A 91a and bank B
91b) are allotted in one logical address space. Contents (data such as
programs) (FIG. 7B) stored in the bank A 91a or contents (FIG. 7C) stored
in the bank B 91b are read out according to the bank changing operation of
a bank change circuit 92. Also, in the case of storing (writing) data such
as a program, the data is stored (written) in the bank A 91a or bank B 91b
according to the bank changing operation of the bank change circuit 92.
The bank change circuit 92 is circuit for converting a logical address
addressed by the CPU 51 into an actual physical address in the flash ROM
91 (bank A 91a or bank B 91b).
The bank A 91a of the flash ROM 91 stores a program such as a current new
BIOS while the bank B 91b stores a program such as a BIOS before updating
(old version). A part of the flash ROM 91 is used as a common area 91c
which can be accessed regardless of bank change. That is, the same storage
area (physical address) is designated with a predetermined logical address
regardless of bank change. In this area, data which is first read to the
memory when the processor is started up and a BIOS updating program are
stored and the contents of this area cannot be rewritten.
The bank change circuit 92 operates for changeover between the banks A and
B in the memory 91 according to a value held by a bank state register 93
formed of a hardware logic circuit to store data such as a program in a
storage area designated with addresses supplied via an address bus or to
read out data from a storage area. Data to be stored or output is input or
output through a data bus.
The bank state register 93 holds a value corresponding to one of the banks
A and B which is to be used. This value is supplied from the CPU 51 via
the bus. A BIOS and other programs ordinarily used are stored in the bank
A. Therefore, the bank state register 93 is holding the value
corresponding to the bank A except during a BIOS updating period. In this
embodiment, when the power supply for the STB is turned on, the bank state
register 93 is reset to the value corresponding to the bank A.
As described above, in the circuit on the flash ROM board 52, the bank A or
bank B of the memory section 91 is used according to the value held by the
bank state register 93, and data is read out mainly from the bank A except
during a BIOS updating period.
The operation of this embodiment of the invention at the time of updating a
BIOS in the flash ROM board 52 will next be described with reference to
the flowchart of FIG. 8 and the diagrams of FIGS. 10 to 18. In this
embodiment, no unit for driving a portable recording medium such as a
floppy disk is provided and, therefore, a new BIOS is supplied from the
network interface card 57 for BIOS updating. When the remote commander 63
or the like (e.g., server 1-1 or 1-2 as shown in FIG. 1) is operated to
input an instruction to perform BIOS updating, the CPU 51 starts
processing described below on the basis of the updating program stored in
the common area 91c.
First, in step S1, the CPU 51 reads out a current version BIOS which is to
be updated, and which has been stored in the bank A 91a of the flash ROM
91, and the CPU 51 temporarily stores (saves) the current BIOS in the RAM
53, as shown in FIG. 10.
Next, in step S2, the CPU 51 changes the value of the bank state register
93 to change the bank A for the bank B.
In step S3, the CPU 51 erases the contents, i.e., an old version BIOS, in
the bank B of the flash ROM 91, as shown in FIG. 11. In step S4, the CPU
51 reads out the current version BIOS from the RAM 53 and stores the
current version BIOS in the bank B 91b, as shown in FIG. 12.
In step S5, the CPU 51 collates the current BIOS in the bank B 91b of the
flash ROM 91 with the current BIOS in the RAM 53, as shown in FIG. 13. In
step S6, the CPU 51 makes a determination as to whether these two groups
of memory contents are identical with each other. If NO, the CPU 51
returns the process to step S1 to again execute the operation of moving
the BIOS stored in the bank A 91a of the flash ROM 91 to the bank B 91b
via the RAM 53.
If the CPU 51 determines in step S6 that the two groups of BIOS data in the
RAM 53 and the bank B 91b of the flash ROM 91 are identical with each
other, it moves the process to step S8 to change the value of the bank
state register 93, thereby changing the bank B for the bank A.
Next, in step S9, the network interface card 57 receives a new BIOS
supplied via a predetermined communication network and the home server 11,
and the CPU 51 stores in the RAM 53 the new BIOS received by the network
interface card 57, as shown in FIG. 14.
In step S10, the CPU 51 erases the contents (current BIOS) of the bank A of
the flash ROM 91, as shown in FIG. 15. Thereafter, in step S11, the CPU 51
stores in the bank A 91a of the flash ROM 91 the new BIOS which is stored
in the RAM 53, as shown in FIG. 16.
In step S12, the CPU 51 collates the BIOS in the bank A 91a of the flash
ROM 91 with the BIOS in the RAM 53, as shown in FIG. 17. In step S13, the
CPU 51 makes a determination as to whether these two groups of memory
contents are identical with each other. If NO, the CPU 51 returns the
process to step S9 to again perform the operation of moving the new BIOS
stored in the RAM 53 to the bank A 91a of the flash ROM 91.
If the CPU 51 determines in step S13 that the two groups of BIOS data in
the RAM 53 and the bank A 91a of the flash ROM 91 are identical with each
other, it stops BIOS update processing with an update processing result
shown in FIG. 18.
As described above, an old BIOS in the bank A 91a of the flash ROM 91 is
moved to the bank B 91b in steps 51 to S7, and a new BIOS supplied via a
predetermined communication network is stored in the bank A 91a in steps
S8 to S13, thus performing BIOS updating. If the new BIOS does not run
well, a sequence of operations reverse to that shown as steps S1 to S7 is
performed to move the BIOS in the bank 91b of the flash ROM 91 to the bank
A 91a via the RAM 53, thereby reinstalling the former BIOS.
While in the above-described embodiment the flash ROM 91 having a plurality
of banks is used, a plurality of flash ROMs each having a single storage
area may be used in place of the flash ROM 91.
Any program (e.g., an operating system) other than the BIOS described above
as an updated program may also be updated in accordance with the present
invention. Further, flash ROMs may also be used in the home server 11, the
personal computers 12-1 and 12-2 and other components.
In the information processor and the program updating method of the present
invention for updating a current basic program stored in a main area of
storage means by replacing the current basic program with a new basic
program on the basis of an updating program stored in a common area of the
storage means, the current basic program read out from the main area is
copied to the spare area of the storage means, and the new basic program
is finally written to the main area on the basis of the updating program.
Thus, BIOS updating can be performed after saving an old BIOS to a spare
area even in an apparatus having no such a recording unit as a floppy
disk. Even in a case where BIOS writing ends in failure, the old BIOS can
be reinstalled immediately, thus preventing the BIOS from being lost by an
operation error or the like.
The information processing system of the present invention has information
providing means for providing information through a predetermined
transmission channel, and information processing means for performing
updating on the basis of an updating program stored in a common area of
storage means. This updating includes copying to a spare area of the
storage means a current basic program read out from a main area of the
storage means and finally writing to the main area of the storage means a
new basic program supplied through the transmission channel. If such a
system is used, BIOS updating can be performed by using a new BIOS
supplied through a network line such as a transmission channel after
saving an old BIOS to a spare area even in an apparatus having no such a
recording unit as a floppy disk.
* * * * *
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