U.S. patent application number 12/206906 was filed with the patent office on 2009-01-08 for broadcast system.
Invention is credited to Tadao Kusudo, Yoshihiro MIMURA, Tomonori Nakamura, Shigeaki Watanabe.
Application Number | 20090013368 12/206906 |
Document ID | / |
Family ID | 19040820 |
Filed Date | 2009-01-08 |
United States Patent
Application |
20090013368 |
Kind Code |
A1 |
MIMURA; Yoshihiro ; et
al. |
January 8, 2009 |
BROADCAST SYSTEM
Abstract
A broadcast system BS includes a broadcast apparatus 1 and a
reception apparatus 2. The broadcast apparatus 1 first receives and
stores therein a proxy request PR including at least an identifier
assigned to the reception apparatus 2 and a command to be
transmitted to the reception apparatus 2. Moreover, the broadcast
apparatus 1 extracts the set of the identifier of the reception
apparatus 2 and the command for the reception apparatus 2 from the
proxy request PR stored therein, and assembles a command packet
from the set of the identifier and the command. Then, the broadcast
apparatus 1 generates a stream in which the assembled command
packet is multiplexed, and sends it out to a broadcast channel. The
reception apparatus 2 separates the command packet from the stream
sent out to the broadcast channel, and restores the set of the
identifier and the command of the reception apparatus 2. Then, the
reception apparatus 2 determines whether or not the disassembled
command is destined for the present reception apparatus based on
the pre-stored identifier of the present reception apparatus and
the disassembled identifier of the reception apparatus 2. If so,
the reception apparatus 2 stores therein the command destined for
the present reception apparatus. The reception apparatus 2 executes
the command, which has bee stored as described above.
Inventors: |
MIMURA; Yoshihiro;
(Edinburgh, GB) ; Watanabe; Shigeaki; (Kyoto,
JP) ; Kusudo; Tadao; (Osaka, JP) ; Nakamura;
Tomonori; (Neyagawa, JP) |
Correspondence
Address: |
WENDEROTH, LIND & PONACK L.L.P.
2033 K. STREET, NW, SUITE 800
WASHINGTON
DC
20006
US
|
Family ID: |
19040820 |
Appl. No.: |
12/206906 |
Filed: |
September 9, 2008 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
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11727728 |
Mar 28, 2007 |
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12206906 |
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10482799 |
Jan 5, 2004 |
7218611 |
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PCT/JP02/06715 |
Jul 3, 2002 |
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11727728 |
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Current U.S.
Class: |
725/118 ;
375/E7.024 |
Current CPC
Class: |
H04N 21/235 20130101;
H04N 21/26233 20130101; H04N 21/6543 20130101; H04N 21/435
20130101; H04N 21/643 20130101; H04N 21/42684 20130101; H04N
21/25866 20130101; H04N 21/4753 20130101; H04N 21/6433 20130101;
H04N 21/41407 20130101; H04N 21/4348 20130101; H04N 21/4227
20130101; H04N 21/4334 20130101; H04N 21/4335 20130101; H04N 21/472
20130101 |
Class at
Publication: |
725/118 |
International
Class: |
H04N 7/173 20060101
H04N007/173 |
Foreign Application Data
Date |
Code |
Application Number |
Jul 5, 2001 |
JP |
2001-204330 |
Claims
1-26. (canceled)
27. A reception apparatus for receiving a stream from a broadcast
apparatus, wherein, the broadcast apparatus broadcasts, over a
pre-assigned broadcast channel, a stream obtained by multiplexing
together a command packet and a set of a video packet and an audio
packet, the command packet being assembled from an identifier
assigned to the reception apparatus and a command to be transmitted
to the reception apparatus, and the set of the video packet and the
audio packet forming a program to be broadcast from a predetermined
broadcast start time to a predetermined broadcast end time; the
reception apparatus comprises: a first tuner section for setting a
receiving frequency band thereof to a broadcast channel specified
by a user so as to receive a stream sent over the set broadcast
channel; an AV packet separation section for separating the video
packet and the audio packet from the stream received by the first
tuner section; a second tuner section for setting a receiving
frequency band thereof to a broadcast channel used for broadcasting
a command packet destined for the present reception apparatus so as
to receive a stream sent over the set broadcast channel; an
apparatus identifier storage section for storing the identifier of
the present reception apparatus; a command filtering section for
determining whether or not an identifier multiplexed in the stream
received by the second tuner section matches the identifier of the
present reception apparatus stored in the apparatus identifier
storage section; a command packet separation section for separating
a command multiplexed in the stream received by the second tuner
section if it is determined by the command filtering section that
the identifiers match each other; a command storage section for
storing the command separated by the command packet separation
section; and a command execution section for executing the command
stored in the command storage section; and the tuner sections, the
apparatus identifier storage section, the command filtering
section, the command storage section, the command execution section
and the command packet separation section operate if a power supply
provided in the reception apparatus is on standby, and the AV
packet separation section operates if the power supply is not on
standby.
28. A reception method used in a reception apparatus for receiving
a stream from a broadcast apparatus, wherein, the broadcast
apparatus broadcasts, over a pre-assigned broadcast channel, a
stream obtained by multiplexing together a command packet and a set
of a video packet and an audio packet, the command packet being
assembled from an identifier assigned to the reception apparatus
and a command to be transmitted to the reception apparatus, and the
set of the video packet and the audio packet forming a program to
be broadcast from a predetermined broadcast start time to a
predetermined broadcast end time; the reception method comprises: a
first reception step of receiving a stream sent over a broadcast
channel specified by a user; an AV packet separation step of
separating the video packet and the audio packet from the stream
received in the first reception step; a second reception step of
receiving a stream sent over a broadcast channel used for
broadcasting a command destined for the reception apparatus; a
command filtering step of determining whether or not an identifier
multiplexed in the stream received in the second reception step
matches an identifier pre-assigned to the reception apparatus; a
command packet separation step of separating a command from the
stream received in the second reception step if it is determined in
the command filtering step that the identifiers match each other; a
command storage step of storing the command separated in the
command packet separation step; and a command execution step of
executing the command stored in the command storage step; and the
second reception step, the command filtering step, the command
packet separation step, the command storage step and the command
execution step are performed if a power supply provided in the
reception apparatus is on standby, and the AV packet separation
step is performed when the power supply is not on standby.
Description
TECHNICAL FIELD
[0001] The present invention relates to a broadcast system, and
more particularly to a broadcast system in which a broadcast
apparatus transmits to a reception apparatus a command for a unit
to be controlled, the command being transmitted in a broadcast
format.
BACKGROUND ART
[0002] FIG. 26 is a block diagram illustrating an overall
configuration of a conventional broadcast system. The broadcast
system of FIG. 26 is disclosed in Japanese Laid-Open Patent
Publication No. 10-155131, and includes a communication terminal
apparatus TA1, a server BSV as the broadcast apparatus, a
communication terminal apparatus TA2 as the reception apparatus,
and a video tape recorder VTR as the unit to be controlled. The
communication terminal apparatus TA1 transmits information
"recording scheduling request" to the server BSV, which is
communicably connected to the communication terminal apparatus TA1
via the Internet INT. In response to the recording scheduling
request sent from the communication terminal apparatus TA1, the
server BSV transmits personal recording schedule information, as an
example of the command, to the communication terminal apparatus TA2
over a text television channel CH. The communication terminal
apparatus TA2, capable of receiving televised programs and text,
receives a video signal sent over an ordinary broadcast channel,
and supplies the received signal to the video tape recorder VTR,
which is communicably connected to the communication terminal
apparatus TA2. Furthermore, the communication terminal apparatus
TA2 sets a recording schedule requested by the communication
terminal apparatus TA1 in the video tape recorder VTR according to
the personal scheduled recording information sent from the server
BSV over the text television channel CH.
[0003] Next, technical problems of the conventional broadcast
system will be described.
[0004] First, while the above publication discloses only one
communication terminal apparatus TA2, an actual broadcast system
accommodates a number of communication terminal apparatuses TA2.
Nevertheless, the server BSV simply sends personal scheduled
recording information that arrives at the server BSV while
multiplexing it with other signals on the text television channel
CH. Therefore, a communication terminal apparatus TA2 may possibly
receive personal scheduled recording information which was directed
to another communication terminal apparatus TA2. Furthermore, there
are a plurality of servers BSV, and they are assigned different
text television channels CH. Moreover, the communication terminal
apparatus TA2 receives personal scheduled recording information
sent over one of the plurality of text television channels CH that
is specified by the user. Therefore, in order to reliably perform
the scheduled recording, a communication terminal apparatus TA2
needs to be set to a text television channel CH being used by a
server BSV when the personal scheduled recording information from
the server BSV arrives at the communication terminal apparatus TA2.
Therefore, if the appropriate text television channel CH is not
selected, the communication terminal apparatus TA2 fails to receive
the personal scheduled recording information from the server BSV,
thus failing to perform the scheduled recording. As can be seen
from the above, the first problem of the conventional broadcast
system is that the reception apparatus is likely to fail to
accurately receive only those commands that are destined for
itself.
[0005] Next, while the above publication discloses only one
communication terminal apparatus TA1, as with the communication
terminal apparatus TA2, personal scheduled recording information
arrives at the server BSV from a plurality of communication
terminal apparatuses TA1 in an actual broadcast system. Due to the
nature of scheduled recording, personal scheduled recording
information needs to arrive at the communication terminal apparatus
TA2 before the start of the program requested by the communication
terminal apparatus TA1. However, the conventional server BSV simply
sends personal scheduled recording information that arrives at the
server BSV. Therefore, the second problem is that the personal
scheduled recording information may not arrive at the communication
terminal apparatus TA2 before the start of the program to be
recorded by scheduled recording.
[0006] Therefore, a first object of the present invention is to
provide a broadcast system in which the reception apparatus can
receive only those commands that are destined for itself with a
higher reliability. Moreover, a second object of the present
invention is to provide a broadcast system in which a command sent
from the broadcast apparatus arrives at the reception apparatus by
a predetermined time.
DISCLOSURE OF THE INVENTION
[0007] To achieve the first and second objects above, the present
invention has the following aspects. A first aspect of the present
invention is directed to a broadcast apparatus for broadcasting a
stream to a reception apparatus, comprising: a request reception
section for receiving a proxy request including an identifier
assigned to the reception apparatus, a command to be transmitted to
the reception apparatus, and an execution start time of the command
to be transmitted to the reception apparatus; a timer for keeping a
current time; a request determination section for determining
whether or not to accept the proxy request received by the request
reception section by using the execution start time included in the
received proxy request and the current time kept by the timer; a
proxy request storage device for storing the proxy request that is
determined by the request determination section to be acceptable; a
command extraction section for extracting a set of an identifier of
the reception apparatus and a command for the reception apparatus
from the proxy request stored in the proxy request storage device a
plurality of times at a predetermined time interval; a command
packet assembler for assembling a command packet from the set of
the identifier and the command extracted by the command extraction
section; a multiplexer for generating a stream in which the command
packet assembled by the command packet assembler is multiplexed;
and a transmitter for sending out the stream generated by the
multiplexer to a broadcast channel. The request determination
section includes: a first time calculation section for calculating
a first amount of time required from when each command packet is
sent out until the command packet arrives at the reception
apparatus; a second time calculation section for calculating a
second amount of time required from when a first command packet is
assembled until a last command packet, including the same set of
the identifier and the command as the first packet, is assembled; a
reference time calculation section for calculating a reference time
by which the proxy request from the reception apparatus should
arrive at the present reception apparatus, based on the execution
start time included in the proxy request received by the request
reception section and the first and second amounts of time
calculated by the first and second time calculation sections,
respectively; and a determination section for determining that the
proxy request received by the request reception section is
unacceptable if the current time kept by the timer is after the
reference time calculated by the reference time calculation
section.
[0008] A second aspect of the present invention is directed to a
reception apparatus for receiving a stream from a broadcast
apparatus, wherein the broadcast apparatus broadcasts, over a
pre-assigned broadcast channel, a stream in which a command packet
is multiplexed, the command packet being assembled from an
identifier assigned to the reception apparatus and a command to be
transmitted to the reception apparatus. The reception apparatus
includes: a tuner section for receiving the stream sent over the
broadcast channel; an apparatus identifier storage section for
storing the identifier of the present reception apparatus; a
command filtering section for determining whether or not the
identifier multiplexed in the stream received by the tuner section
matches the identifier of the present reception apparatus stored in
the apparatus identifier storage section; a command storage section
for storing the command multiplexed in the stream received by the
tuner section if it is determined by the command filtering section
that the identifiers match each other; a command execution section
for executing the command stored in the command storage section; a
power supply that can be set to two states of ON and standby; a
specified channel storage section for storing, as a specified
broadcast channel, information indicating a broadcast channel
assigned to the broadcast apparatus; and a power supply monitoring
device for monitoring the state of the power supply to transmit a
control signal including a specified broadcast channel stored in
the specified channel storage section to the tuner section after
the power supply transitions from ON to standby. The tuner section
sets a receiving frequency band thereof to the specified broadcast
channel included in the control signal from the power supply
monitoring device. The tuner section, the apparatus identifier
storage section, the command filtering section, the command storage
section, the command execution section, the power supply monitoring
device and the specified channel storage section operate if the
power supply is on standby.
[0009] A third aspect of the present invention is directed to a
broadcast method for broadcasting a stream to a reception
apparatus, comprising: a request reception step of receiving a
proxy request including an identifier assigned to the reception
apparatus, a command to be transmitted to the reception apparatus,
and an execution start time of the command to be transmitted to the
reception apparatus; a request determination step of determining
whether or not to accept the proxy request received in the request
reception step by using the execution start time included in the
received proxy request and a current time kept in the broadcast
apparatus; a proxy request storage step of storing the proxy
request that is determined in the request determination step to be
acceptable; a command extraction step of extracting a set of an
identifier of the reception apparatus and a command for the
reception apparatus from the proxy request stored in the proxy
request storage step a plurality of times at a predetermined time
interval; a command packet assembling step of assembling a command
packet from the set of the identifier and the command extracted in
the command extraction step; a multiplexing step of generating a
stream in which the command packet assembled in the command packet
assembling step is multiplexed; and a send-out step of sending out
the stream generated in the multiplexing step to a broadcast
channel. The request determination step includes: a first time
calculation step of calculating a first amount of time required
from when each command packet is sent out until the command packet
arrives at the reception apparatus; a second time calculation step
of calculating a second amount of time required from when a first
command packet is assembled until a last command packet, including
the same set of the identifier and the command as the first packet,
is assembled; a reference time calculation step of calculating a
reference time by which the proxy request from the reception
apparatus should arrive at the broadcast apparatus, based on the
execution start time included in the proxy request received in the
request reception step and the first and second amounts of time
calculated in the first and second time calculation steps,
respectively; and a determination step of determining that the
proxy request received in the request reception step is
unacceptable if the current time is after the reference time
calculated in the reference time calculation step.
[0010] A fourth aspect of the present invention is directed to a
reception method used in a reception apparatus for receiving a
stream from a broadcast apparatus, wherein the broadcast apparatus
broadcasts, over a pre-assigned broadcast channel, a stream in
which a command packet is multiplexed, the command packet being
assembled from an identifier assigned to the reception apparatus
and a command to be transmitted to the reception apparatus. The
reception method includes: a reception step of setting a receiving
frequency band of a tuner of the reception apparatus to a
predetermined broadcast channel so as to receive a stream sent over
the set broadcast channel; a command filtering step of determining
whether or not the identifier multiplexed in the stream received in
the reception step matches an identifier pre-assigned to the
reception apparatus; a command storage step of storing the command
multiplexed in the stream received in the reception step if it is
determined in the command filtering step that the identifiers match
each other; a command execution step of executing the command
stored in the command storage step; and a control signal
transmission step of monitoring a state of a power supply of the
reception apparatus that can be set to two states of ON and
standby, and transmitting a control signal including a broadcast
channel assigned to the broadcast apparatus as a specified
broadcast channel to the tuner after the power supply transitions
from ON to standby. The receiving frequency band of the tuner is
set to the specified broadcast channel included in the control
signal from the control signal transmission step. The reception
step, the command filtering step, the command storage step, the
command execution step and the power supply monitoring step are
performed if the power supply is on standby.
[0011] A fifth aspect of the present invention is directed to a
reception apparatus for receiving a stream from a broadcast
apparatus, wherein the broadcast apparatus broadcasts, over a
pre-assigned broadcast channel, a stream obtained by multiplexing
together a command packet and a set of a video packet and an audio
packet, the command packet being assembled from an identifier
assigned to the reception apparatus and a command to be transmitted
to the reception apparatus, and the set of the video packet and the
audio packet forming a program to be broadcast from a predetermined
broadcast start time to a predetermined broadcast end time. The
reception apparatus includes: a first tuner section for setting a
receiving frequency band thereof to a broadcast channel specified
by a user so as to receive a stream sent over the set broadcast
channel; an AV packet separation section for separating the video
packet and the audio packet from the stream received by the first
tuner section; a second tuner section for setting a receiving
frequency band thereof to a broadcast channel used for broadcasting
a command packet destined for the present reception apparatus so as
to receive a stream sent over the set broadcast channel; an
apparatus identifier storage section for storing the identifier of
the present reception apparatus; a command filtering section for
determining whether or not an identifier multiplexed in the stream
received by the second tuner section matches the identifier of the
present reception apparatus stored in the apparatus identifier
storage section; a command packet separation section for separating
a command multiplexed in the stream received by the second tuner
section if it is determined by the command filtering section that
the identifiers match each other; a command storage section for
storing the command separated by the command packet separation
section; and a command execution section for executing the command
stored in the command storage section. The tuner sections, the
apparatus identifier storage section, the command filtering
section, the command storage section, the command execution section
and the command packet separation section operate if a power supply
provided in the reception apparatus is on standby. The AV packet
separation section operates if the power supply is not on
standby.
[0012] A sixth aspect of the present invention is directed to a
reception method used in a reception apparatus for receiving a
stream from a broadcast apparatus, wherein the broadcast apparatus
broadcasts, over a pre-assigned broadcast channel, a stream
obtained by multiplexing together a command packet and a set of a
video packet and an audio packet, the command packet being
assembled from an identifier assigned to the reception apparatus
and a command to be transmitted to the reception apparatus, and the
set of the video packet and the audio packet forming a program to
be broadcast from a predetermined broadcast start time to a
predetermined broadcast end time. The reception method includes: a
first reception step of receiving a stream sent over a broadcast
channel specified by a user; an AV packet separation step of
separating the video packet and the audio packet from the stream
received in the first reception step; a second reception step of
receiving a stream sent over a broadcast channel used for
broadcasting a command destined for the reception apparatus; a
command filtering step of determining whether or not an identifier
multiplexed in the stream received in the second reception step
matches an identifier pre-assigned to the reception apparatus; a
command packet separation step of separating a command from the
stream received in the second reception step if it is determined in
the command filtering step that the identifiers match each other; a
command storage step of storing the command separated in the
command packet separation step; and a command execution step of
executing the command stored in the command storage step. The
second reception step, the command filtering step, the command
packet separation step, the command storage step and the command
execution step are performed if a power supply provided in the
reception apparatus is on standby. The AV packet separation step is
performed if the power supply is not on standby.
BRIEF DESCRIPTION OF THE DRAWINGS
[0013] FIG. 1 is a schematic diagram illustrating an overall
configuration of a broadcast system BS according to one embodiment
of the present invention.
[0014] FIG. 2(a) and FIG. 2(b) are schematic diagrams illustrating
a data structure of a proxy request PR transmitted to a broadcast
apparatus 1 by a communication terminal apparatus 3 of FIG. 1.
[0015] FIG. 3 is a block diagram illustrating a detailed
configuration of the broadcast apparatus 1 of FIG. 1.
[0016] FIG. 4(a) and FIG. 4(b) are schematic diagrams illustrating
a series including a header packet Phd and Nmux command packets Pct
outputted from a command packet assembler 112 of FIG. 3.
[0017] FIG. 5(a) and FIG. 5(b) are schematic diagrams illustrating
a transport stream TS sent out from a TS transmitter 119 of FIG.
3.
[0018] FIG. 6 is a block diagram illustrating a detailed
configuration of a reception apparatus 2 of FIG. 1.
[0019] FIG. 7 is a schematic diagram illustrating an example of a
command Cct that should not be stored in a command storage section
211 of FIG. 2.
[0020] FIG. 8 is a schematic diagram illustrating a data structure
of an error message EM generated by an error message generation
section 213 of FIG. 2.
[0021] FIG. 9 is a block diagram illustrating a detailed
configuration of the communication terminal apparatus 3 of FIG.
[0022] FIG. 10(a) and FIG. 10(b) are sequence charts illustrating a
procedure for data communications performed in the broadcast system
BS of FIG. 1.
[0023] FIG. 11 is a flow chart illustrating the procedure of a
process in which an application execution section 32 of FIG. 9
generates and transmits the proxy request PR.
[0024] FIG. 12(a) and FIG. 12(b) are schematic diagrams
illustrating an example of an image to be displayed in step S11 of
FIG. 11.
[0025] FIG. 13(a) is a schematic diagram illustrating an example of
a data format of a command Cct that is stored in advance in the
application execution section 32 of FIG. 3, and FIG. 13(b) is a
schematic diagram illustrating an example of a generated command
Cct.
[0026] FIG. 14 is a flow chart illustrating the procedure of a
process performed when the broadcast apparatus 1 of FIG. 1 receives
the proxy request PR.
[0027] FIG. 15 is a schematic diagram illustrating an example of a
proxy request PRp stored in a request storage device 18 of FIG.
3.
[0028] FIG. 16 is a flow chart illustrating the procedure of a
process that the broadcast apparatus 1 of FIG. 1 performs when
transmitting the transport stream TS.
[0029] FIG. 17 is a schematic diagram illustrating the command
packet Pct of the same contents arriving at the reception apparatus
2 of FIG. 1 Nsc times at a time interval Tnv.
[0030] FIG. 18 is a flow chart illustrating the procedure of a
process that the reception apparatus 2 of FIG. 1 performs when
receiving the transport stream TS.
[0031] FIG. 19 is a flow chart illustrating the procedure of a
process that the communication terminal apparatus 3 of FIG. 1
performs when receiving the error message EM.
[0032] FIG. 20 is a schematic diagram illustrating an example of a
command ACct that is written to the command storage section 211 by
performing step S416 of FIG. 18.
[0033] FIG. 21 is a flow chart illustrating the procedure of a
process that a command execution section 216 of FIG. 6 performs
when executing the command ACct stored in the command storage
section 211.
[0034] FIG. 22 is a block diagram illustrating a detailed
configuration of a first variant (reception apparatus 2a) of the
reception apparatus 2 of FIG. 1.
[0035] FIG. 23 is a block diagram illustrating a detailed
configuration of a dual tuner 41 of FIG. 22.
[0036] FIG. 24 is a block diagram illustrating a detailed
configuration of a second variant (reception apparatus 2b) of the
reception apparatus 2 of FIG. 1.
[0037] FIG. 25 is a flow chart illustrating the procedure of a
process that a command execution section 51 of FIG. 24 performs
when executing the command ACct stored in the command storage
section 211.
[0038] FIG. 26 is a schematic diagram illustrating a configuration
of a conventional broadcast system.
BEST MODE FOR CARRYING OUT THE INVENTION
[0039] FIG. 1 is a schematic diagram illustrating an overall
configuration of a broadcast system BS according to one embodiment
of the present invention. The broadcast system BS of FIG. 1
includes: a broadcast apparatus 1 owned by a broadcaster; a
reception apparatus 2 and a communication terminal apparatus 3
owned by the user; and a communication line 4. Briefly speaking,
the broadcast apparatus 1 receives and stores therein a proxy
request PR sent out from the communication terminal apparatus 3 via
the communication line 4. The proxy request PR includes a command
Cct to be transmitted to the reception apparatus 2, and is
information with which the communication terminal apparatus 3
requests the broadcast apparatus 1 to transmit the command Cct on
behalf of the user. In the present embodiment, the command Cct is,
for example, a command for scheduling for recording a program to be
broadcast (hereinafter referred to as a "broadcast program") from a
predetermined broadcast start time Tst to a predetermined broadcast
end time Tnd over a broadcast channel BCH that is assigned to the
broadcast apparatus 1.
[0040] FIG. 2(a) is a schematic diagram illustrating an example of
a data structure of the proxy request PR described above. In FIG.
2(a), the proxy request PR includes an apparatus identifier IDrt, a
password PW and the command Cct. The apparatus identifier IDrt is
an identifier pre-assigned to the reception apparatus 2, and is
typically composed of a string of numbers. The password PW is
composed of a string of characters or symbols, or a string of
characters and symbols, which is determined by the user. The
command Cct includes a scheduled recording command Crec, the
broadcast channel BCH used for transmitting a broadcast program to
be recorded by scheduled recording, and the broadcast start time
Tst and the broadcast end time Tnd of the broadcast program. In the
following description, a broadcast program to be recorded by
scheduled recording will be referred to as a "recording-scheduled
broadcast program". The broadcast start time Tst and the broadcast
end time Tnd also include information indicating the month and
date. FIG. 2(b) is a schematic diagram illustrating a specific
example of the proxy request PR illustrated in FIG. 2(a). In FIG.
2(b), the apparatus identifier IDrt is "211.155.15.1", the password
PW is "NAISHO", the broadcast channel BCH is "8", the broadcast
start time Tst is "19:00 June 21", and the broadcast end time Tnd
is "20:00 June 21".
[0041] The broadcast apparatus 1 of FIG. 1 generates a transport
stream (hereinafter simply referred to as a "stream") TS by
multiplexing the proxy request PR stored therein with video data Dv
and audio data Da, which are pre-stored therein. The broadcast
apparatus 1 transmits the generated stream TS to the reception
apparatus 2 over the broadcast channel BCH. In some cases, the
broadcast apparatus 1 may receive an unacceptable proxy request PR.
Such a proxy request PR is typically one that arrives at the
broadcast apparatus 1 after a reference time Tref to be described
later. The broadcast apparatus 1 discards such a proxy request PR.
Then, the broadcast apparatus 1 generates a request_rejected signal
RR which is information that indicates that the proxy request PR
was not accepted, and sends out the request_rejected signal RR to
the communication line 4. If the proxy request PR is accepted, the
broadcast apparatus 1 transmits a request_accepted signal RC which
is information that indicates the acceptance of the proxy request
PR, to the communication terminal apparatus 3 via the communication
line 4.
[0042] FIG. 3 is a block diagram illustrating a detailed
configuration of the broadcast apparatus 1 as described above. In
FIG. 3, the broadcast apparatus 1 includes a request reception
section 11, a timer 12, a request determination section 13, a
request discarding section 14, a request_rejected generation
section 15, a request_rejected transmission section 16, a request
writing section 17, a request storage device 18, a request_accepted
generation section 19, a request_accepted transmission section 110,
a command extraction section 111, a command packet assembler 112, a
broadcast program storage device 113, a video encoder 114, a video
packet assembler 115, an audio encoder 116, an audio packet
assembler 117, a multiplexer 118, and a TS transmitter 119.
[0043] The request reception section 11 receives the proxy request
PR sent out from the communication terminal apparatus 3 via the
communication line 4, and passes the proxy request PR to the
request determination section 13. The timer 12 keeps a current time
Tcr, and returns the current time Tcr to the request determination
section 13 in response to a request by the request determination
section 13. The request determination section 13 requests the timer
12 to send the current time Tcr each time the request determination
section 13 receives the proxy request PR from the request reception
section 11. Furthermore, the request determination section 13
determines whether or not to accept the received proxy request PR
based on the current time Tcr received from the timer 12. More
specifically, the request determination section 13 determines
whether or not the received current time Tcr is after the reference
time Tref to be described later. If the current time Tcr is after
the reference time Tref, the request determination section 13
determines that the proxy request PR is unacceptable, and passes
the proxy request PR to the request discarding section 14 as a
proxy request PRd. The request discarding section 14 discards the
received proxy request PRd, and gives the request_rejected
generation section 15 an instruction ISrr to generate the
request_rejected signal RR. In response to the reception of the
instruction ISrr, the request_rejected generation section 15
generates the request_rejected signal RR and passes it to the
request_rejected transmission section 16. The request_rejected
transmission section 16 sends out the received request_rejected
signal RR to the communication line 4.
[0044] If the request determination section 13 determines that the
current time Tcr is the same or before the reference time Tref, the
request determination section 13 accepts the received proxy request
PR and passes it to the request writing section 17 as a proxy
request PRp. The request writing section 17 writes the received
proxy request PRp to the request storage device 18, and gives the
request_accepted generation section 19 an instruction ISrc to
generate the request_accepted signal RC. In response to the
instruction ISrc, the request_accepted generation section 19
generates the request_accepted signal RC and passes it to the
request_accepted transmission section 110. The request_accepted
transmission section 110 sends out the received request_accepted
signal RC to the communication line 4.
[0045] Moreover, the command extraction section 111 periodically
selects a predetermined number Nmux of proxy requests PRp from the
request storage device 18, and periodically selects and reads out,
as an information set Icom, the apparatus identifier IDrt, the
password PW and the command Cct of each of the selected proxy
requests PRp. The broadcast system BS has a predetermined bandwidth
BWct for transmitting a command packet Pct assembled by the command
packet assembler 112. Nmux is a natural number equal to or greater
than 1, and the number is appropriately predetermined according to
the bandwidth BWct. Nmux is also the number of commands Cct to be
multiplexed in the stream TS each time the multiplexer 118 performs
step S33 (see FIG. 16). The command extraction section 111 passes
all of the read-out information sets Icom to the command packet
assembler 112. The command packet assembler 112 assembles one
command packet Pct per one information set Icom. Furthermore, the
command packet assembler 112 assembles one header packet Phd so
that the command packet Pct can be accurately separated at the
reception apparatus 2. Upon completion of the packet assembling
process described above, the command packet assembler 112 outputs
the header packet Phd and the command packet Pct in this order to
the multiplexer 118.
[0046] FIG. 4(a) is a schematic diagram illustrating an example of
a series including a header packet Phd and command packets Pct
outputted from the command packet assembler 112, and FIG. 4(b) is a
schematic diagram illustrating a specific example of a series
including a header packet Phd and command packets Pct that is
outputted from the command packet assembler 112 if the command
extraction section 111 selects the proxy request PR illustrated in
FIG. 2(b) as the information set Icom.
[0047] The broadcast program storage device 113 typically stores a
plurality of sets of the video data Dv and the audio data Da. Each
set of the video data Dv and the audio data Da represents one
program. At the broadcast start time Tst of the program composed of
the video data Dv and the audio data Da, the video data Dv and the
audio data Da are read out from the broadcast program storage
device 113 and outputted to the video encoder 114 and the audio
encoder 116, respectively. The video encoder 114 encodes the
received video data Dv according to a predetermined video encoding
scheme to generate encoded video data Dcv. The video encoder 114
outputs the generated video data Dcv to the video packet assembler
115. The video packet assembler 115 assembles a video packet Pcv
from the received video data Dcv and outputs it to the multiplexer
118. The audio encoder 116 encodes the audio data Da outputted from
the broadcast program storage device 113 according to a
predetermined audio encoding scheme to generate encoded audio data
Dca. The audio encoder 116 outputs the generated audio data Dca to
the audio packet assembler 117. The audio packet assembler 117
assembles an audio packet Pca from the received audio data Dca and
outputs it to the multiplexer 118. The broadcast system BS has a
predetermined bandwidth BWav for transmitting the video packet Pcv
and the audio packet Pca. The video encoder 114 and the audio
encoder 116 described above perform their encoding processes
according to the bandwidth BWav.
[0048] The multiplexer 118 generates the stream TS by multiplexing
together the video packet Pcv from the video packet assembler 115,
the audio packet Pca from the audio packet assembler 117, and the
header packet Phd and the command packet Pct from the command
packet assembler 112. The multiplexer 118 outputs the generated
stream TS to the TS transmitter 119. The TS transmitter 119 sends
out the received stream TS to the broadcast channel BCH.
[0049] FIG. 5(a) is a schematic diagram illustrating an example of
the stream TS sent out from the TS transmitter 119, and FIG. 5(b)
is a schematic diagram illustrating the structure of the stream TS
that is outputted from the multiplexer 118 if the command packet
Pct illustrated in FIG. 4(b) is outputted by the command packet
assembler 112.
[0050] The reception apparatus 2 of FIG. 1 is typically a set-top
box which is placed indoors, and receives the stream TS sent over
the broadcast channel BCH. As a characteristic process of the
present embodiment, the reception apparatus 2 separates the command
Cct destined for itself, which has been multiplexed in the received
stream TS, and stores it in an internal command storage section 211
(see FIG. 6). Furthermore, the reception apparatus 2 executes a
scheduled recording from the broadcast start time Tst to the
broadcast end time Tnd, which are specified by the stored command
Cct. In the following description, the time period from the
broadcast start time Tst to the broadcast end time Tnd will be
referred to as a "scheduled time period TPrp". As the scheduled
recording is executed, the reception apparatus 2 separates the
video packet Pcv and the audio packet Pca of the
recording-scheduled broadcast program from the received stream TS
and stores them in an internal scheduled program storage device 218
(see FIG. 6) during the scheduled time period TPrp. If the command
Cct cannot be stored in the command storage section 211 for some
reason, the reception apparatus 2 generates an error message EM
notifying the communication terminal apparatus 3 that the command
Cct cannot be stored, and sends out the error message EM to the
communication line 4.
[0051] FIG. 6 is a block diagram illustrating a detailed
configuration of the reception apparatus 2 as described above. In
FIG. 6, the reception apparatus 2 includes a power supply 21, a
specified channel storage section 22, a power supply monitoring
device 23, a tuner 24, a command packet separation section 25, a
command packet disassembling section 26, an apparatus identifier
storage section 27, a password storage section 28, a command
filtering section 29, a determination/writing section 210, the
command storage section 211, an address storage section 212, an
error message generation section 213, a line connection section
214, a timer 215, a command execution section 216, an AV packet
separation section 217, the scheduled program storage device 218,
and a free space detection section 219.
[0052] The power supply 21 is typically set to one of three states
(ON, OFF and standby) by the user operating a switch (not shown) of
the reception apparatus 2. In the present embodiment, while the
power supply 21 is ON, the power supply 21 supplies the driving
voltage to all of the components illustrated in FIG. 6 (from the
specified channel storage section 22 to the free space detection
section 219). Note that FIG. 6 only shows a driving voltage Ecc to
the AV packet separation section 217 for the sake of simplicity.
While the power supply 21 is on standby, the power supply 21
supplies the driving voltage at least to all of the components
except for the AV packet separation section 217. What happens while
the power supply 21 is OFF will not be described herein as it is
irrelevant to the present embodiment.
[0053] The specified channel storage section 22 stores information
that represents the broadcast channel BCH specified by the user. In
the following description, the broadcast channel stored in the
specified channel storage section 22 will be referred to as a
"specified broadcast channel BCHr". The specified broadcast channel
BCHr will now be described in detail. In the present embodiment,
the broadcaster provides, in addition to the program broadcasting
service of broadcasting programs by using the broadcast apparatus 1
of FIG. 1, another service of transmitting the command Cct to the
reception apparatus 2 on behalf of the user (hereinafter referred
to as a "proxy service"). The specified broadcast channel BCHr is a
broadcast channel BCH assigned to a broadcaster that is contracted
by the user to render a proxy service for the user.
[0054] The power supply monitoring device 23 typically detects the
time at which the power supply 21 transitions from ON to standby.
After detecting the transition, the power supply monitoring device
23 generates a control signal CSfa and outputs it to the tuner 24.
The control signal CSfa is a signal instructing to set the
receiving frequency band of the tuner 24 to the specified broadcast
channel BCHr.
[0055] If the power supply 21 becomes ON, the tuner 24 sets the
receiving frequency band to the broadcast channel BCH, which is
specified by the user using an input device (not shown). Moreover,
in response to the reception of the control signal CSfa from the
power supply monitoring device 23, the tuner 24 extracts the
specified broadcast channel BCHr from the specified channel storage
section 22, and sets the receiving frequency band to the extracted
channel. Moreover, in response to the reception of a control signal
CSfb from the command execution section 216, the tuner 24 sets the
receiving frequency band to the broadcast channel BCH specified by
the control signal CSfb. The control signal CSfb is a signal
instructing to set the receiving frequency band of the tuner 24 to
the broadcast channel BCH notified by the command execution section
216 in order to execute a scheduled recording. The tuner 24
receives the stream TS transmitted over the set broadcast channel
BCH, and outputs the received stream TS to the command packet
separation section 25 and the AV packet separation section 217.
[0056] The command packet separation section 25 separates each
command packet Pct multiplexed in the received stream TS (see FIG.
5(a) and FIG. 5(b)) according to the preceding header packet Phd,
and passes the separated command packet Pct to the command packet
disassembling section 26. The command packet disassembling section
26 disassembles the received command packet Pct to restore the
information set Icom. The command packet disassembling section 26
passes the restored information set Icom to the command filtering
section 29.
[0057] The apparatus identifier storage section 27 and the password
storage section 28 store the apparatus identifier IDrt and the
password PW, respectively. Note that in the following description,
the apparatus identifier IDrt and the password PW that are stored
in the apparatus identifier storage section 27 and the password
storage section 28 will be referred to as a "local apparatus
identifier IDrt" and a "local password PW", respectively. The
command filtering section 29 filters information sets Icom received
from the command packet disassembling section 26 by using both of
the local apparatus identifier IDrt and the local password PW
stored in the apparatus identifier storage section 27 and the
password storage section 28, respectively. More specifically, the
command filtering section 29 determines that the received
information set Icom is valid only if the local apparatus
identifier IDrt and the local password PW completely match the
apparatus identifier IDrt and the password PW, respectively, which
are included in the information set Icom. In the present
embodiment, a valid information set Icom means a command packet Pct
that is generated from a proxy request PRr generated as intended by
the user and that is destined for the present reception apparatus.
Thus, an information set Icom whose apparatus identifier IDrt does
not match is regarded as not being destined for the present
reception apparatus, and an information set Icom whose password PW
does not match is regarded as not being one that has been generated
by the user operating the communication terminal apparatus 3. If
the command filtering section 29 determines that the received
information set Icom is valid, the command filtering section 29
extracts the command Cct from the information set Icom and passes
it to the determination/writing section 210. In contrast, if it is
determined that the information set Icom is invalid, the command
filtering section 29 discards the information set Icom.
[0058] The determination/writing section 210 determines whether or
not to write the received command Cct to the command storage
section 211. As illustrated in FIG. 2(a) and FIG. 2(b), the command
Cct includes the broadcast start time Tst and the broadcast end
time Tnd. The command storage section 211 stores a number of
commands Cct written by the determination/writing section 210.
Thus, in order to properly execute scheduled recordings, two
commands Cct whose scheduled time periods TPrp overlap each other
should not both be stored. For example, consider a case where a
command Cct that has "18:30 June 21" as the broadcast start time
Tst and "19:30 June 21" as the broadcast end time Tnd is already
stored in the command storage section 211, as illustrated in FIG.
7. In such a case, the command Cct set in the proxy request PR
illustrated in FIG. 2(b) should not be stored in the command
storage section 211. The reason is that these commands Cct have a
temporal overlap from 19:00 to 19:30 on June 21. From such a point
of view, the determination/writing section 210 extracts the
scheduled time period TPrp from the received information set Icom,
and determines whether or not the command storage section 211
already contains any scheduled time period TPrp that overlaps the
extracted scheduled time period TPrp. In the following description,
the determination process will be referred to as a "schedule
overlap determination process".
[0059] Moreover, the scheduled program storage device 218 stores
the video packet Pcv and the audio packet Pca in a storage area of
a finite capacity. Therefore, in order to properly execute a
scheduled recording, the scheduled program storage device 218 needs
to have a sufficient free space FS for storing the
recording-scheduled broadcast program specified by the command Cct.
From such a point of view, the free space detection section 219
detects the free space FS of the scheduled program storage device
218 in response to a request from the determination/writing section
210, and sends back the detected free space FS to the
determination/writing section 210. The determination/writing
section 210 estimates a capacity SS that is required for storing
the recording-scheduled broadcast program based on the scheduled
time period TPrp in the received information set Icom. The
determination/writing section 210 determines whether or not the
estimated capacity SS exceeds the free space FS from the free space
detection section 219. The determination process will hereinafter
be referred to as a "capacity determination process".
[0060] The determination/writing section 210 performs the schedule
overlap determination process and the capacity determination
process for the received command Cct. If both determination results
are "No", the determination/writing section 210 permits the command
Cct to be written, and writes the command Cct as a command ACct in
the command storage section 211. If at least one of the
determination results is "YES", the determination/writing section
210 discards the received command Cct without storing it in the
command storage section 211, and gives the error message generation
section 213 an instruction ISem to generate the error message
EM.
[0061] The command storage section 211 is a non-volatile memory
device, and stores the command ACct, as is apparent from the above.
The address storage section 212 stores an address Act specified by
the user. The address Act is an address uniquely identifying the
communication terminal apparatus 3, and is typically a string of
characters or numbers. In the present embodiment, it is assumed
that the address Act is "address@pop.ne.jp". In response to the
instruction ISem, the error message generation section 213 extracts
the address Act from the address storage section 212, and generates
the error message EM. The error message generation section 213
passes the generated error message EM to the line connection
section 214. The line connection section 214 connects itself to the
communication line 4 in response to the arrival of the error
message EM, and then sends out the received error message EM to the
communication line 4.
[0062] FIG. 8 is a schematic diagram illustrating an example of a
data structure of the error message EM generated by the error
message generation section 213. In FIG. 8, the error message EM is
shown to be in the form of electronic mail, and includes at least
the address Act and a body text MT indicating that the command Cct
could not be written to the command storage section 211.
[0063] The timer 215 keeps the current time Tcr, and passes the
current time Tcr to the command execution section 216 at a
predetermined time interval. The command execution section 216
accesses the command storage section 211 each time the current time
Tcr arrives from the timer 215. Then, the command execution section
216 searches for a command Cct whose broadcast start time Tst
matches the received current time Tcr from among all the commands
Cct in the command storage section 211. In the following
description, a command Cct that meets this condition will be
referred to as a "command ECct". Upon finding a command ECct, the
command execution section 216 starts executing the command ECct.
More specifically, the command execution section 216 first
generates a control signal CSon instructing to turn the power
supply 21 ON, and outputs it to the power supply 21. In response to
the received control signal CSon, the power supply 21 supplies the
driving voltage Ecc to the AV packet separation section 217.
Moreover, the command execution section 216 extracts the broadcast
channel BCH of the recording-scheduled broadcast program from the
command ECct, generates the control signal CSfb including the
extracted broadcast channel BCH, and outputs it to the tuner 24.
The tuner 24 sets the receiving frequency band to the broadcast
channel BCH specified by the received control signal CSfb to
receive the stream TS, as described above. Furthermore, the command
execution section 216 generates a recording instruction ISrec
instructing the AV packet separation section 217 to store the video
packet Pcv and the audio packet Pca separated from the received
stream TS in the scheduled program storage device 218. The command
execution section 216 outputs the generated recording instruction
ISrec to the AV packet separation section 217. The AV packet
separation section 217 operates as instructed by the recording
instruction ISrec. As a result, the scheduled program storage
device 218 starts storing the video packet Pcv and the audio packet
Pca separated by the AV packet separation section 217. In other
words, the recording of the recording-scheduled broadcast program
starts. Furthermore, the command execution section 216 terminates
the execution of the command ECct if it recognizes that the
broadcast end time Tnd of the command ECct matches the current time
Tcr received from the timer 215. More specifically, the command
execution section 216 generates a control signal CSsb instructing
to set the power supply 21 on standby, and outputs it to the power
supply 21. In response to the received control signal CSsb, the
power supply 21 transitions to standby, and stops supplying the
driving voltage Ecc to the AV packet separation section 217. As a
result, the recording of the recording-scheduled broadcast program
ends. Furthermore, as the power supply 21 is set on standby, the
power supply monitoring device 23 generates the control signal CSfa
as described above, and transmits it to the tuner 24.
[0064] The communication terminal apparatus 3 of FIG. 1 is
preferably a mobile phone that generates the proxy request PR as
described above through the operation by the user and sends it out
to a wireless channel WCH. The sent-out proxy request PR is
received by the base station on the communication line 4 via the
wireless channel WCH, and is then passed to the broadcast apparatus
1. Moreover, the base station on the communication line 4 sends
out, onto the wireless channel WCH, the request_rejected signal RR
or the request_accepted signal RC from the broadcast apparatus 1 or
the error message EM from the reception apparatus 2. If the
communication terminal apparatus 3 receives the request_rejected
signal RR or the request_accepted signal RC or the error message EM
from the wireless channel WCH, the communication terminal apparatus
3 outputs an image or a sound indicating the non-acceptance or
acceptance of the command Cct by the broadcast apparatus 1 or that
the reception apparatus 2 cannot execute the command Cct.
[0065] FIG. 9 is a block diagram illustrating a detailed
configuration of the communication terminal apparatus 3 as
described above. In FIG. 9, the communication terminal apparatus 3
includes an input device 31, an application execution section 32,
an apparatus identifier storage section 33, a password storage
section 34, a wireless transmission/reception section 35, an output
device 36, being a display device or a loudspeaker, and a target
identifier storage section 37.
[0066] The input device 31 is typically a keyboard. The user
operates the input device 31 to input information necessary for
performing data communications in the present broadcast system BS.
Although not shown in FIG. 9 for the sake of simplicity, the
inputted information includes the apparatus identifier IDrt and the
password PW as described above, as well as the broadcast channel
BCH, the broadcast start time Tst, and the broadcast end time Tnd.
These inputted information are sent to the application execution
section 32. The application execution section 32 includes a
processor, a ROM (Read Only Memory) and a RAM (Random Access
Memory), and stores a computer program for making a proxy request
(hereinafter referred to as a "proxy request program") 321 and an
email client program 322 in the ROM. The application execution
section 32 executes the proxy request program 321 to generate the
proxy request PR as described above, or to receive the
request_rejected signal RR or the request_accepted signal RC as
described above. Moreover, the application execution section 32
executes the email client program 322 to receive the error message
EM. The apparatus identifier storage section 33 and the password
storage section 34 store the apparatus identifier IDrt and the
password PW, respectively, which are sent from the application
execution section 32. The wireless transmission/reception section
35 performs a predetermined modulation or multiplexing operation on
the proxy request PR received from the application execution
section 32, and sends out the resultant signal to the wireless
channel WCH. Moreover, the wireless transmission/reception section
35 performs a predetermined demodulation or separation operation on
the request_rejected signal RR, the request_accepted signal RC or
the error message EM received from the wireless channel WCH, and
passes the resultant signal to the application execution section
32. Note that the target identifier storage section 37 will not be
described now, as it is a component that is needed in the second
variant to be described later.
[0067] Next, settings to be made before performing data
communications in the broadcast system BS will be described. The
user operates the input device 31 of the communication terminal
apparatus 3 to activate the application execution section 32 while
specifying the proxy request program 321. Then, the user operates
the input device 31 to input the apparatus identifier IDrt. The
application execution section 32 stores the inputted apparatus
identifier IDrt in the apparatus identifier storage section 33.
Furthermore, the user operates the input device 31 to input the
password PW. The application execution section 32 stores the
inputted password PW in the password storage section 34.
Furthermore, the user operates an input device (not shown) of the
reception apparatus 2 to input the same password PW as that stored
in the password storage section 34 and to input the address Act. As
a result of the input operation described above, the inputted
password is stored as the local password PW in the apparatus
identifier storage section 27 of the reception apparatus 2. The
inputted address Act is stored in the address storage section 212.
Note that the same apparatus identifier IDrt as that set in the
apparatus identifier storage section 33 is stored in the apparatus
identifier storage section 27 of FIG. 6 as the local apparatus
identifier IDrt before shipped from the factory, for example.
Furthermore, the user makes a contract with a broadcaster for a
proxy service. After the contract is made, the user or the
broadcaster operates an input device (not shown) of the reception
apparatus 2 of the user to input the broadcast channel BCH used by
the contracted broadcaster as the specified broadcast channel BCHr.
The inputted specified broadcast channel BCHr is stored in the
specified channel storage section 22.
[0068] Next, data communications to be performed in the present
broadcast system BS will be described in detail.
[0069] FIG. 10(a) and FIG. 10(b) are sequence charts illustrating a
procedure for data communications performed in the present
broadcast system BS. When the user realizes, while away from home,
that the user has forgotten to set a scheduled recording for a
recording-scheduled broadcast program, the user starts operating
the communication terminal apparatus 3. The user operates the input
device 31 of the communication terminal apparatus 3 to specify the
proxy request program 321. In response to the specification, the
application execution section 32 starts executing the proxy request
program 321. After the start of the execution, the application
execution section 32 generates the proxy request PR according to
information inputted by the user, and transmits it to the broadcast
apparatus 1 via the communication line 4 (sequence Q11 of FIG.
10(a) and FIG. 10(b)).
[0070] FIG. 11 is a flow chart illustrating the procedure of a
process in which the application execution section 32 generates and
transmits the proxy request PR. In FIG. 11, the application
execution section 32 generates image data on which the user can
specify items necessary for setting a scheduled recording, and
passes it to the output device 36. According to the received image
data, the output device 36 displays an image on which the user can
specify items necessary for setting a scheduled recording (step S11
of FIG. 11).
[0071] FIG. 12(a) is a schematic diagram illustrating an example of
an image displayed in step S11. As illustrated in FIG. 12(a), an
input box Cbch for the broadcast channel BCH over which the
recording-scheduled broadcast program is transmitted, an input box
Cst for the broadcast start time Tst of the recording-scheduled
broadcast program, and an input box Cnd for the broadcast end time
Tnd of the recording-scheduled broadcast program are displayed on
the screen of the output device 36 as input boxes for items
necessary for setting a scheduled recording. The user operates the
input device 31 to input the broadcast channel BCH, the broadcast
start time Tst and the broadcast end time Tnd in the input boxes
Cbch, Cst and Cnd, respectively, displayed on the output device 36.
It should be noted that the broadcast system BS actually
accommodates a plurality of broadcast apparatuses 1. Therefore,
what is set in the input box Cbch may not only be the broadcast
channel BCH of the broadcast apparatus 1 illustrated in FIG. 1, but
may also be the broadcast channel BCH of another broadcast
apparatus 1 (not shown). Moreover, the broadcast start time Tst
includes not only the time of start of the recording-scheduled
broadcast program but also the month and date thereof. This is also
true for the broadcast end time Tnd. Moreover, FIG. 12(b) is a
schematic diagram illustrating an example of the broadcast channel
BCH, the broadcast start time Tst and the broadcast end time Tnd to
be inputted in the input boxes Cbch, Cst and Cnd, respectively,
illustrated in FIG. 12(a). In FIG. 12(b), "8", "19:00 June 21" and
"20:00 June 21" are inputted in the input box Cbch, the input box
Cst and the input box Cnd, respectively.
[0072] The application execution section 32 receives the broadcast
channel BCH, the broadcast start time Tst and the broadcast end
time Tnd inputted by the user (step S12), and then generates the
command Cct using the received information (step S13). Step S13
will now be described in greater detail. FIG. 13(a) is a schematic
diagram illustrating a data format of the command Cct that is
provided in advance in the application execution section 32. In
FIG. 13(a), the command Cct includes the scheduled recording
command Crec and three fields in which the broadcast channel BCH,
the broadcast start time Tst and the broadcast end time Tnd are
set. In step S13, the application execution section 32 sets the
broadcast channel BCH, the broadcast start time Tst and the
broadcast end time Tnd received in step S12 in the three fields to
generate the command Cct. FIG. 13(b) is a schematic diagram
illustrating an example of the broadcast channel BCH, the broadcast
start time Tst and the broadcast end time Tnd set in the three
fields illustrated in FIG. 13(a). If information as illustrated in
FIG. 12(b) is inputted, "8", "19:00 June 21" and "20:00 June 21"
are set in the three fields of the command Cct as illustrated in
FIG. 13(b).
[0073] After generating the command Cct as described above, the
application execution section 32 extracts the password PW and the
apparatus identifier IDrt from the password storage section 34 and
the apparatus identifier storage section 33 in this order (steps
S14 to S15). Then, the application execution section 32 adds the
extracted password PW and the extracted apparatus identifier IDrt
to the command Cct generated in step S13 to assemble the proxy
request PR (see FIG. 2(a)) (step S16). Note that, if the command
Cct illustrated in FIG. 13(b) is generated, the proxy request PR
illustrated in FIG. 2(b) is generated.
[0074] After the proxy request PR is generated, the application
execution section 32 controls the wireless transmission/reception
section 35 to establish a connection with the broadcast apparatus 1
(step S17). Note that the establishment of the connection is not
limited to after step S16 but may alternatively be before step S16.
After the connection is established, the application execution
section 32 sends out the generated proxy request PR to the
communication line 4 via the wireless transmission/reception
section 35 (step S18). The proxy request PR sent out as described
above is transmitted to the broadcast apparatus 1 via the
communication line 4 of FIG. 1 as illustrated in FIG. 10(a) and
FIG. 10(b).
[0075] FIG. 14 is a flow chart illustrating the procedure of a
process performed when the broadcast apparatus 1 receives the proxy
request PR. In FIG. 14, the request reception section 11 of the
broadcast apparatus 1 waits for the proxy request PR to arrive
(step S21), and passes the received proxy request PR to the request
determination section 13. The request determination section 13
determines whether or not to accept the received proxy request PR
(step S22). As described above, a proxy request PR including a
command Cct such that it is no use transmitting the proxy request
PR to the reception apparatus 2 may arrive at the broadcast
apparatus 1. A typical example of such a useless command Cct will
now be described. The broadcast start time Tst set in the command
Cct is the time at which the scheduled recording needs to be
started. Therefore, the command Cct needs to arrive at the
reception apparatus 2 by the broadcast start time Tst at the
latest. Where Ttf1 is the amount of time from when the command
packet Pct including the command Cct is sent out from the broadcast
apparatus 1 to when it arrives at the reception apparatus 2, Ttf1
can be approximated as follows.
Ttf1.quadrature.(NmuxSct+Shd)/BWct (1)
Nmux and BWct are as described above. Sct is the data size of the
command packet Pct. Shd is the data size of the packet header Phd.
Nmux, Sct, Shd and BWct are known values, and are assumed to be
constants in the present embodiment for the purpose of
illustration.
[0076] Moreover, as will be described later, one command packet Pct
is transmitted a predetermined number Nsc of times at a
predetermined time interval Tnv according to DSM-CC. DSM-CC will
not be further described in the present embodiment, as it is
defined in ISO/IEC13818-6. Moreover, Nsc is a natural number equal
to or greater than 2. Thus, it takes time Ttf2, which is
approximated in Expression (2) below, from when the command packet
Pct transmitted in the first transmission arrives at the reception
apparatus 2 to when the command packet Pct transmitted in the
Nsc.sup.th transmission arrives at the reception apparatus 2.
Ttf2.quadrature.Tnv(Nsc-1) (2)
[0077] Thus, the proxy request PR needs to arrive at the broadcast
apparatus 1 by the reference time Tref, which is calculated by
Expression (3) below.
Tref=Tst-(NscTtf1+Ttf2)-Tmg (3)
[0078] Tmg is a predetermined time margin that is determined
according to the design requirements of the broadcast system
BS.
[0079] If the proxy request PR arrives at the broadcast apparatus 1
after the reference time Tref described above, the broadcast
apparatus 1 cannot send out the command Cct a number Nsc of times
at the time interval Tnv by the broadcast start time Tst.
Therefore, the proxy request PR failing to meet this condition is
regarded as including a useless command Cct.
[0080] In order to determine whether or not the received proxy
request PR includes a useless command Cct as described above, the
request determination section 13 first extracts the broadcast start
time Tst from the proxy request PR received from the request
reception section 11 (step S221). Furthermore, the request
determination section 13 receives the current time Tcr from the
timer 12 (step S222). Then, the request determination section 13
substitutes the broadcast start time Tst obtained in step S221 into
Expression (3) above to calculate the reference time Tref (step
S223). Then, the request determination section 12 determines
whether or not the current time Tcr obtained in step S222 is after
the reference time Tref calculated in step S223 (step S224). If it
is determined "Yes", the request determination section 12 regards
the received proxy request PR as including a useless command Cct,
and passes the proxy request PR to the request discarding section
14 as the proxy request PRd. The request discarding section 14
discards the received proxy request PRd (step S23), and then gives
the request_rejected generation section 15 the instruction ISrr to
generate the request_rejected signal RR. In response to the
instruction ISrr from the request discarding section 14, the
request_rejected generation section 15 generates the
request_rejected signal RR as described above (step S24). The
request_rejected generation section 15 passes the generated
request_rejected signal RR to the request_rejected transmission
section 16. The request_rejected transmission section 16 transmits
the received request_rejected signal RR to the communication
terminal apparatus 3, with which a connection has been established
via the communication line 4 (step S25, sequence Q12 of FIG.
10(a)).
[0081] In the communication terminal apparatus 3, the wireless
transmission/reception section 35 receives the request_rejected
signal RR and passes it to the application execution section 32.
After step S18 as described above, the application execution
section 32 waits for the request_rejected signal RR or the
request_accepted signal RC to be sent from the broadcast apparatus
1 (step S19), and if the request_rejected signal RR is received as
in the current case, the application execution section 32 displays
a message that the proxy request PR cannot be accepted on the
output device 36 (step S110). Thus, the user of the communication
terminal apparatus 3 knows that the proxy request PR sent by the
user has not been accepted by the broadcast apparatus 1.
[0082] Reference is made again to FIG. 14. If it is determined "No"
in step S224, the request determination section 13 regards the
received proxy request PR as not including a useless command Cct,
and passes it to the request writing section 17 as the proxy
request PRp. The request writing section 17 writes the received
proxy request PRp to the request storage device 18 (step S26). As a
result, a new proxy request PRp is stored in the request storage
device 18, as illustrated in FIG. 15. Note that while the present
embodiment has been described assuming that the broadcast system BS
accommodates one communication terminal apparatus 3 and one
reception apparatus 2, the broadcast system BS actually
accommodates a number of communication terminal apparatuses 3 and
reception apparatuses 2. Furthermore, the same communication
terminal apparatus 3 may transmit a plurality of proxy requests PR
to the broadcast apparatus 1. Thus, in most cases, a plurality of
proxy requests PRp are stored in the request storage device 18, as
illustrated in FIG. 15. Note that if the request writing section 17
receives the proxy request PR illustrated in FIG. 2(b), it is
stored as the proxy request PRp as illustrated at the bottom of
FIG. 15.
[0083] The request writing section 17 further gives the
request_accepted generation section 19 the instruction ISrc to
generate the request_accepted signal RC. In response to the
instruction ISrc from the request writing section 17, the
request_accepted generation section 19 generates the
request_accepted signal RC as described above (step S27). The
request_accepted generation section 19 passes the generated
request_accepted signal RC to the request_accepted transmission
section 110. The request_accepted transmission section 110
transmits the received request_accepted signal RC to the
communication terminal apparatus 3, with which a connection has
been established via the communication line 4 (step S28, sequence
Q13 of FIG. 10(b)).
[0084] In the communication terminal apparatus 3, the wireless
transmission/reception section 35 passes the received
request_accepted signal RC to the application execution section 32.
After step S18, the application execution section 32 waits for the
request_rejected signal RR or the request_accepted signal RC as
described above (step S19), and if the request_accepted signal RC
is received as in the current case, the application execution
section 32 notifies the reception of the request_accepted signal RC
on the output device 36 (step S110). Thus, the user of the
communication terminal apparatus 3 knows that the current proxy
request PR has been accepted by the broadcast apparatus 1.
[0085] FIG. 16 is a flowchart illustrating the procedure of a
process that the broadcast apparatus 1 performs when transmitting
the proxy request PRp stored in the request storage device 18. As
described above, the command extraction section 111 periodically
selects and reads out a number Nmux of information sets Icom (proxy
requests PRp) from the request storage device 18 (step S31). Note
that after the completion of the readout operation described above,
the command extraction section 111 passes the information sets Icom
to the command packet assembler 112. Furthermore, it is assumed
that the command extraction section 111 has read out the proxy
request PR illustrated in FIG. 2(b) as the information set
Icom.
[0086] The command packet assembler 112 assembles a header packet
Phd, and also assembles a command packet Pct from the received
information set Icom (step S32). Therefore, Nmux command packets
Pct are assembled. Furthermore, the command packet assembler 112
first outputs the header packet Phd to the multiplexer 118, and
then sequentially outputs Nmux command packets Pct to the
multiplexer 118, as illustrated in FIG. 4(a) and FIG. 4(b).
[0087] As described above, at the broadcast start time of a
program, the video data Dv and the audio data Da of the program to
be broadcast are read out from the broadcast program storage device
113 and are outputted to the video encoder 114 and the audio
encoder 116, respectively. The video encoder 114 and the audio
encoder 116 encode the received video data Dv and the received
audio data Da to output the encoded video data Dcv and the encoded
audio data Dca to the video packet assembler 115 and the audio
packet assembler 117, respectively. The video packet assembler 115
and the audio packet assembler 117 assemble a number of video
packets Pcv and audio packets Pca from the received encoded video
data Dcv and the received encoded audio data Dca, respectively, and
output them to the multiplexer 118.
[0088] The multiplexer 118 generates the stream TS illustrated in
FIG. 5(a) and FIG. 5(b) by multiplexing together the received video
packet Pcv, the received audio packet Pca, the received header
packet Phd and Nmux received command packets Pct (step S33), and
outputs it to the TS transmitter 119. The TS transmitter 119 sends
out the received stream TS to the broadcast channel BCH described
above on a carrier wave having a predetermined broadcast frequency
band (step S34, sequence Q14 of FIG. 10(b)).
[0089] In the broadcast apparatus 1, the process of FIG. 16 is
repeated, whereby the set of a header packet Phd and Nmux command
packets Pct (only one is shown in the figure) is periodically sent
out to the broadcast channel BCH as illustrated in FIG. 10(b). It
should be noted that since the command extraction section 111
performs the process according to DSM-CC, one proxy request PRp is
read out Nsc times at the time interval Tnv. As a result, if the
reception apparatus 2 receives the first command packet Pct (see
FIG. 4(b)) at time T0, the reception apparatus 2 receives the
second command packet Pct at time T0+Tnv, and finally receives the
Nsc.sup.th command packet Pct at time T0+NscTnv, as illustrated in
FIG. 17.
[0090] Next, referring to the flow chart of FIG. 18, the process
performed by the reception apparatus 2 when receiving the command
packet Pct sent out from the broadcast apparatus 1 will be
described. The user, when going out, operates a switch (not shown)
of the reception apparatus 2 to set the power supply 21 on standby.
As a result, the power supply monitoring device 23 sends out the
control signal CSfa to the tuner 24 (step S41). In response to the
received control signal CSfa, the tuner 24 sets the receiving
frequency band thereof to the specified broadcast channel BCHr
stored in the specified channel storage section 22 (step S42).
Thus, the tuner 24 receives the stream TS from the broadcast
apparatus 1 managed by the broadcaster contracted by the user for a
proxy service, and does not receive streams TS from other broadcast
apparatuses (not shown).
[0091] When the user realizes, while away from home, that the user
has forgotten to set a scheduled recording for a broadcast program,
the user operates the input device 31 of the communication terminal
apparatus 3 to execute the proxy request program 321. As a result,
the communication terminal apparatus 3 performs the process
illustrated in FIG. 11, thereby transmitting the proxy request PR
to the broadcast apparatus 1. In response to the received proxy
request PR, the broadcast apparatus 1 performs the process of FIG.
14. If it is determined "No" in step S224, the command packet Pct
assembled from the current proxy request PR is sent out to the
broadcast channel BCH while being multiplexed in the stream TS. It
is assumed that the command packet Pct generated from the proxy
request PR illustrated in FIG. 2(b) is sent out in the sent-out
stream TS. Since the receiving frequency band of the tuner 24 is
set to the specified broadcast channel BCHr, the tuner 24 receives
the stream TS sent out from the broadcast apparatus 1 (step S43),
and outputs it to the command packet separation section 25. Note
that although the tuner 24 outputs the received stream TS also to
the AV packet separation section 217, the AV packet separation
section 217 does not perform any operation on the stream TS because
the driving voltage Ecc is not supplied to the AV packet separation
section 217 while the power supply 21 is on standby.
[0092] The command packet separation section 25 separates each
command packet Pct multiplexed in the received stream TS while
referring to the header packet Phd (step S44), and outputs the
separated command packet Pct to the command packet disassembling
section 26. The command packet disassembling section 26
disassembles the received command packet Pct to restore the
information set Icom (step S45). Furthermore, the command packet
disassembling section 26 passes the restored information set Icom
to the command filtering section 29.
[0093] Each time the command filtering section 29 receives one
information set Icom, the command filtering section 29 extracts the
apparatus identifier IDrt and the password PW therefrom (step S46).
Furthermore, the command filtering section 29 extracts the local
apparatus identifier IDrt and the local password PW as described
above (step S47). Then, the command filtering section 29 determines
whether or not the apparatus identifier IDrt extracted in step S46
matches the local apparatus identifier IDrt extracted in step S47
(step S48). Furthermore, the command filtering section 29
determines whether or not the password PW extracted in step S46
matches the local password PW extracted in step S47 (step S49). If
it is determined "No" in step S48, the command filtering section 29
determines that the received information set Icom is not destined
for the present reception apparatus, and discards the received
information set Icom (step S410). If it is determined "No" in step
S49, it means that the password PW determined by the user is not
set in the current information set Icom, whereby the command
filtering section 29 discards the information set Icom in step
S410. In contrast, if it is determined "YES" in both steps S48 and
S49, the command filtering section 29 determines that the received
information set Icom is destined for the present reception
apparatus and that it includes the command Cct intended by the
user, whereby the command filtering section 29 extracts the command
Cct and passes it to the determination/writing section 210.
[0094] Each time the determination/writing section 210 receives one
command Cct, the determination/writing section 210 performs the
schedule overlap determination process described above (step S411)
and further performs the capacity determination process described
above (step S412). If it is determined "YES" in step S411, the
determination/writing section 210 determines that a command Cct
having a scheduled time period TPrp that overlaps that of the
received command Cct is stored in the command storage section 211.
Furthermore, if it is determined "YES" in step S412, the
determination/writing section 210 determines that the scheduled
program storage device 218 does not have a sufficient free space
FS. If either one of these two decisions is made, the
determination/writing section 210 discards the received command
Cct, and gives the error message generation section 213 the
instruction ISem as described above (step S413).
[0095] In response to the instruction ISem, the error message
generation section 213 generates the error message EM as
illustrated in FIG. 8 (step S414). Moreover, the line connection
section 214 sends out the error message EM generated by the error
message generation section 213 to the communication line 4 (step
S415). Since the error message EM is in the form of electronic mail
as described above, it is stored in a mail server (not shown)
connected to the communication line 4.
[0096] FIG. 19 is a flow chart illustrating the procedure of a
process that the communication terminal apparatus 3 performs when
receiving the error message EM. The user operates the input device
31 of the communication terminal apparatus 3 to instruct to start
the execution of the email client program 322. Furthermore, the
user instructs to obtain the error message EM from the mail server
described above. In FIG. 19, in response to the instruction from
the user, the application execution section 32 receives the error
message EM stored in the mail server via the communication line 4
and the wireless transmission/reception section 35 (step S51). The
application execution section 32 displays the body text MT of the
received error message EM on the output device 36 (step S52). Thus,
the user of the communication terminal apparatus 3 knows that the
scheduled recording cannot be set.
[0097] If it is determined "No" in both steps S411 and S412 of FIG.
18, the determination/writing section 210 gives a write permission
for the received command Cct, and writes the received command Cct
in the command storage section 211 as the command ACct (step S416).
FIG. 20 is a schematic diagram illustrating an example of the
command ACct written in step S416. In FIG. 20, if a write
permission is given for the command Cct included in the proxy
request PR illustrated in FIG. 2(b), a command ACct as illustrated
in the figure is stored in the command storage section 211.
[0098] Next, referring to the flow chart of FIG. 21, the process in
which the command execution section 216 executes the command ACct
stored in the command storage section 211 will be described. In
FIG. 21, the command execution section 216 waits for the current
time Tcr periodically sent from the timer 215 (step S61). Each time
the current time Tcr is received, the command execution section 216
searches for a command ECct whose broadcast start time Tst matches
the received current time Tcr from among all the commands ACct
stored in the command storage section 211 (see FIG. 20) (step S62).
If a command ECct is not found (step S63), the command execution
section 216 returns to step S61 to wait for the current time Tcr
sent from the timer 215. In contrast, if a command ECct is found in
step S63, the command execution section 216 generates the control
signal CSfb as described above and outputs it to the tuner 24 (step
S64), generates the control signal CSon as described above and
outputs it to the power supply 21 (step S65), and outputs the
recording instruction ISrec as described above to the AV packet
separation section 217 (step S66), in order to start the scheduled
recording. As a result of step S64, the tuner 24 sets the receiving
frequency band thereof to the broadcast channel BCH specified by
the received control signal CSfb. As a result of step S65, the
power supply 21 supplies the driving voltage Ecc to the AV packet
separation section 217. As a result of step S66, the AV packet
separation section 217 operates as instructed by the recording
instruction ISrec. If the scheduled recording is started as
described above, the scheduled program storage device 218 starts
storing the video packet Pcv and the audio packet Pca separated by
the AV packet separation section 217.
[0099] Moreover, after step S66, the command execution section 216
waits for the current time Tcr (step S67). Each time the current
time Tcr is received, it is determined whether or not the broadcast
end time Tnd set in the current command ECct matches the received
current time Tcr (step S68). If Tnd and Tcr do not match, the
command execution section 216 returns to step S67 to wait for the
current time Tcr sent from the timer 215. In contrast, if Tnd and
Tcr match, the command execution section 216 generates the control
signal CSsb as described above and outputs it to the power supply
21 (step S69) in order to terminate the scheduled recording. As a
result of step S69, the power supply 21 transitions to standby, and
stops supplying the driving voltage Ecc to the AV packet separation
section 217. If the power supply 21 transitions to standby, the
power supply monitoring device 23 generates the control signal CSfa
as described above and outputs it to the tuner 24.
[0100] As described above, with the broadcast system BS of the
present embodiment, the broadcast apparatus 1 multiplexes the
command packet Pct assembled from the accepted proxy request PRp in
a transport stream TS a plurality of times, as illustrated in FIG.
17. Therefore, it is possible to realize the broadcast system BS in
which the reception apparatus 2 can receive those commands Cct that
are destined for itself with a high probability. Moreover, as
described above, the command packet Pct assembled from the command
Cct is transmitted from the broadcast apparatus 1 primarily when
the user is away from home (i.e., if the power supply 21 is on
standby). The receiving frequency band of the reception apparatus 2
is automatically set to the specified broadcast channel BCHr stored
in the specified channel storage section 22 if the power supply 21
is set on standby. Thus, the reception apparatus 2 can receive
those commands Cct that are destined for itself with an even higher
probability. Moreover, as described above, the command filtering
section 29 performs a filtering process using the local apparatus
identifier IDrt, whereby it is possible to accurately choose those
information sets Icom that are destined for itself from among a
large number of information sets Icom received.
[0101] Moreover, the broadcast apparatus 1 discards a proxy request
PR arriving after the reference time Tref through steps S224 and
S23 of FIG. 14, while accepting a proxy request PR arriving at or
before the reference time Tref through steps S224 and S26. As a
result, the transmission of the command Cct included in the proxy
request PRp stored in the request storage device 18 is not hindered
by the command Cct included in a useless proxy request PR, whereby
the reception apparatus 2 can receive the command Cct by the
broadcast start time Tst with a higher probability.
[0102] Note that in the broadcast system BS as described above, the
broadcast apparatus 1 sends out the command packet Pct of the same
contents a number Nsc of times. This is done in order to increase
the probability that the reception apparatus 2 properly receives
the command packet Pct. However, if the probability that a command
packet Pct can be received is sufficiently high, the broadcast
apparatus 1 may alternatively transmit the command packet Pct only
once.
[0103] Moreover, in the broadcast system BS as described above, the
broadcast apparatus 1 and the reception apparatus 2 may be
connected to each other by a wire transmission path such as a
cable. Moreover, the reception apparatus 2 may receive the stream
TS generated by the broadcast apparatus 1 via a broadcast satellite
or a communications satellite. Moreover, in the broadcast system BS
as described above, the broadcast scheme of the broadcast apparatus
1 is digital, but it may alternatively be analog. Moreover, the
reception apparatus 2 transmits the error message EM to the
communication terminal apparatus 3 in the form of electronic mail,
the error message EM may alternatively be transmitted in other
forms of data communications. Furthermore, the reception apparatus
2 may alternatively transmit the error message EM to the broadcast
apparatus 1. Thus, the broadcast apparatus 1 can recognize that the
command packet Pct that it sent out to the reception apparatus 2
has not been stored in the command storage section 211 as the
command Cct.
[0104] Moreover, in the broadcast system BS as described above, as
the communication terminal apparatus 3 transmits one proxy request
PR to the broadcast apparatus 1, the broadcast apparatus 1 sends
out command packets Pct of the same contents. However, the present
invention is not limited to this, and the broadcast apparatus 1 may
alternatively send out command packets Pct of different contents in
response to one proxy request PR. When a broadcaster produces a
program, it is usually not broadcast at once from the beginning to
end of the entire story. Rather, a broadcaster usually produces a
program in which the entire story is divided into 1-hour episodes,
for example, and the entire story is completed by separately
broadcasting these episodes starting from the first episode and
ending with the last episode. Furthermore, the first to last
episodes are broadcast in the same time slot and day of week. Such
a broadcast schedule is often set in advance. Under such
circumstances, the broadcast apparatus 1 may send out command
packets Pct of the same contents except for the date or the day of
week of the broadcast start time Tst and the broadcast end time Tnd
varying from one another so that all the episodes of the specified
broadcast program can be scheduled for recording by one proxy
request PR. Furthermore, if the broadcast schedule of the broadcast
program specified by the proxy request PR is changed afterwards,
the broadcast apparatus 1 may send out command packets Pct whose
broadcast start time Tst and broadcast end time Tnd are changed
accordingly. Thus, the communication terminal apparatus 3 needs to
send out the proxy request PR only once, thereby reducing the
communication cost.
[0105] Next, a first variant of the reception apparatus 2
illustrated in FIG. 6 (hereinafter referred to as a "reception
apparatus 2a") will be described. FIG. 22 is a block diagram
illustrating a detailed configuration of the reception apparatus
2a. In FIG. 22, the reception apparatus 2a, as compared to the
reception apparatus 2 of FIG. 6, includes a dual tuner section 41
and a frequency band setting section 42, instead of the specified
channel storage section 22, the power supply monitoring device 23
and the tuner 24. Other than this, the reception apparatuses 2a and
2 do not differ from each other in structure. Therefore, in FIG.
22, those components already shown in FIG. 6 will be denoted by the
same reference numerals and will not be further described
below.
[0106] Moreover, FIG. 23 is a block diagram illustrating a detailed
configuration of the dual tuner section 41 of FIG. 22. In FIG. 23,
the dual tuner section 41 includes an AV tuner 411 and a command
tuner 412. The AV tuner 411 sets the receiving frequency band
thereof to the broadcast channel BCH specified by the user by
operating an input device (not shown) of the reception apparatus
2a. Then, the AV tuner 411 receives the stream TS transmitted over
the set broadcast channel BCH and outputs it to the AV packet
separation section 217. Moreover, the command tuner 412 sets the
receiving frequency band thereof to the specified broadcast channel
BCHr sent from the frequency band setting section 42. Then, the
command tuner 412 constantly receives the stream TS transmitted
over the specified broadcast channel BCHr and outputs it to the
command packet separation section 25.
[0107] The frequency band setting section 42 is typically a set of
keys or buttons. The user or the broadcaster operates the frequency
band setting section 42 to input the specified broadcast channel
BCHr. The frequency band setting section 42 sends the inputted
specified broadcast channel BCHr to the command tuner 412.
[0108] As described above, with the provision of the command tuner
412 dedicated for the specified broadcast channel BCHr, the
reception apparatus 2a can constantly receive the command packet
Pct destined for itself whether or not the power supply 21 is on
standby, thereby further reducing the possibility of failing to
receive the command Cct destined for itself.
[0109] Next, a second variant of the reception apparatus 2
illustrated in FIG. 6 (hereinafter referred to as a "reception
apparatus 2b") will be described. FIG. 24 is a block diagram
illustrating a detailed configuration of the reception apparatus
2b. In FIG. 24, the reception apparatus 2b, as compared to the
reception apparatus 2 of FIG. 6, includes a command execution
section 51 and a bus control section 52, instead of the command
execution section 216 and the scheduled program storage device 218,
and is connected to an external recording device 6 via a bus 7.
Other than this, the reception apparatuses 2b and 2 do not differ
from each other in structure. Therefore, in FIG. 24, those
components already shown in FIG. 6 will be denoted by the same
reference numerals and will not be further described below. Note
that some of the components shown in FIG. 6 are not shown in FIG.
24 for the sake of simplicity.
[0110] The command execution section 51 has two differences as
follows from the command execution section 216 described above.
First, the command execution section 51 sends out a transfer
instruction IStf to the AV packet separation section 217, instead
of the recording instruction ISrec described above. The transfer
instruction IStf is information for instructing to transfer the
video packet Pcv and the audio packet Pca, which have been
separated by the AV packet separation section 217, to the bus
control section 52. In addition to the operation above, the other
difference is that the command execution section 51 sends a target
identifier TID pre-assigned to the external recording device 6 for
uniquely identifying the external recording device 6 and the
recording instruction ISrec to the bus control section 52. Thus,
the command execution section 51 instructs to transmit the video
packet Pcv and the audio packet Pca outputted from the AV packet
separation section 217 to the external recording device 6 via the
bus 7.
[0111] As with the AV packet separation section 217, the driving
voltage Ecc is not supplied to the bus control section 52 if the
power supply 21 is on standby, and the driving voltage Ecc is
supplied thereto if the power supply 21 is ON. In response to the
recording instruction ISrec from the command execution section 51
while the driving voltage Ecc is supplied to the bus control
section 52, the bus control section 52 first assembles a bus packet
BPrec from the recording instruction ISrec so as to include the
target identifier TID, which is received together with the
recording instruction ISrec, according to a predetermined bus
protocol (e.g., IEEE1394), and sends it out to the bus 7 connected
to itself. Then, from the video packet Pcv and the audio packet Pca
received subsequently, the bus control section 52 assembles bus
packets BPcv and BPca so as to include the target identifier TID,
and sends them out to the bus 7 connected to itself.
[0112] Moreover, the external recording device 6 is typically a
hard disk recorder, a DVD (Digital Versatile Drive) recorder, or a
VTR (Video Tape Recorder). The external recording device 6 has the
target identifier TID as described above, and includes a bus
control section 61 and a scheduled program storage device 62. The
bus control section 61 executes the recording command ISrec after
disassembling the bus packet BPrec received via the bus 7. More
specifically, the bus control section 61 restores the video packet
Pcv and the audio packet Pca by disassembling the bus packets BPcv
and BPca, respectively, which are received after the start of the
execution of the recording command ISrec. The bus control section
61 transmits the restored video packet Pcv and the audio packet Pca
to the scheduled program storage device 62. The scheduled program
storage device 62, corresponding to the scheduled program storage
device 218 of FIG. 6, stores the received video packet Pcv and the
received audio packet Pca.
[0113] Next, settings to be made before performing data
communications in the broadcast system BS including the reception
apparatus 2b according to the present variant will be described.
Before performing data communications according to the present
variants, the user operates the input device 31 to input the target
identifier TID after the activation of the application execution
section 32 of the communication terminal apparatus 3, in addition
the settings described above. The application execution section 32
stores the inputted target identifier TID in the target identifier
storage section 37 (see FIG. 9).
[0114] Next, data communications to be performed in the present
broadcast system BS will be described in detail. As described
above, the user, who realizes, while away from home, that the user
has forgotten to set a scheduled recording for a
recording-scheduled broadcast program, operates the input device 31
of the communication terminal apparatus 3 to specify the proxy
request program 321. In response to the specification, the
application execution section 32 starts executing the proxy request
program 321, after which the application execution section 32
generates the proxy request PR according to the information
inputted by the user, and transmits it to the broadcast apparatus 1
via the communication line 4 (sequence Q11 of FIG. 10(a) and FIG.
10(b)). The proxy request PR of the present variant differs from
that of FIG. 2(a) and FIG. 2(b) in that the command Cct further
includes the target identifier TID stored in the target identifier
storage section 37.
[0115] The broadcast apparatus 1 performs a process according to
the procedure illustrated in FIG. 14 if it receives the proxy
request PR of the present variant. If it is determined "No" in step
S224, the received proxy request PR is stored in the request
storage device 18, and the request_accepted signal RC is
transmitted to the communication terminal apparatus 3 (see sequence
Q13 of FIG. 10(b)).
[0116] Then, the broadcast apparatus 1 performs a process according
to the procedure illustrated in FIG. 16, if the proxy request PR of
the present variant is stored. In step S31, the information set
Icom, which further includes the target identifier TID, is read out
and sent to the command packet assembler 112. As a result, the TS
transmitter 119 sends out the stream TS, in which the command
packet Pct assembled from the information set Icom as described
above is multiplexed, to the broadcast channel BCH described above
(see sequence Q14 of FIG. 10(b)).
[0117] The reception apparatus 2 performs a process according to
the procedure illustrated in FIG. 18, if it receives the stream TS
of the present variant. Therefore, if it is determined "Yes" in
both steps S48 and S49 and "No" in both steps S411 and S412, the
command Cct multiplexed in the received stream TS is stored in the
command storage section 211 as the command ACct.
[0118] Next, referring to the flow chart of FIG. 25, the process in
which the command execution section 51 executes the command ACct
stored in the command storage section 211 will be described. FIG.
25, as compared to FIG. 21, further includes steps S71 and S72,
instead of step S66. Other than this, the flow charts do not differ
from each other. Therefore, in FIG. 25, those steps already shown
in FIG. 21 will be denoted by the same step numbers and will not be
further described below. As with the command execution section 216,
the command execution section 51 sends out the target identifier
TID and the recording instruction ISrec included in the command
ECct to the bus control section 52 after step S65 (step S71). Then,
the command execution section 51 sends out the transfer instruction
IStf as described above to the AV packet separation section 217
(step S72). As a result of step S65, the power supply 21 supplies
the driving voltage Ecc not only to the AV packet separation
section 217 but also to the bus control section 52. As a result of
steps S71 and S72, the bus control section 52 first assembles the
bus packet BPrec from the target identifier TID and the recording
instruction ISrec received from the command execution section 51,
and sends it out to the bus 7. Then, the bus control section 52
assembles the bus packets BPcv and BPca from the video packet Pcv
and the audio packet Pca, respectively, which are received from the
AV packet separation section 217, and sends them out to the bus 7.
In the external recording device 6, the bus control section 61
receives and disassembles the first bus packet BPrec sent via the
bus 7, and starts executing the recording instruction ISrec. The
bus control section 61 receives and then disassembles the
subsequent bus packets BPcv and BPca. The video packet Pcv and the
audio packet Pca restored as described above are transferred to,
and stored in, the scheduled program storage device 62 by the bus
control section 61. This data storing process is constantly
performed during the scheduled time period TPrp specified by the
command ECct.
[0119] As described above, with the reception apparatus 2b of the
present variant, the video packet Pcv and the audio packet Pca can
be transferred also to the external recording device 6, which is
connected to the reception apparatus 2b via the bus 7, thus further
improving the usability.
[0120] Note that in the present variant, the reception apparatus 2b
and the external recording device 6 are independent of each other.
Therefore, the command Cct received by the reception apparatus 2b
may not be executed as it is by the external recording device 6, as
they may be from different manufacturers. Therefore, the command
execution section 51 may alternatively output the received command
Cct to the bus control section 52 after converting it to the
recording instruction ISrec having a command format employed by the
external recording device 6.
[0121] Moreover, the reception apparatus 2b and the external
recording device 6 of the present variant may be connected to each
other by a wireless connection. Moreover, in the present variant,
in order for the determination/writing section 210 to know the free
space FS of the scheduled program storage device 62 in the capacity
determination process, the determination/writing section 210 can
transmit an instruction therefor to the external recording device
6.
[0122] Moreover, while what is executed by the reception
apparatuses 2, 2a and 2b is the scheduled recording command in the
description above, the command is not limited to any particular
type of command as long as the command includes at least a
predetermined execution start time.
INDUSTRIAL APPLICABILITY
[0123] The broadcast system of the present invention can be used in
a broadcast system capable of broadcasting data signals multiplexed
with video and audio signals.
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