U.S. patent application number 13/782915 was filed with the patent office on 2013-07-18 for mobile radio communication device and method of managing connectivity status for the same.
This patent application is currently assigned to NEC CORPORATION. The applicant listed for this patent is NEC CORPORATION. Invention is credited to Hubert HELAINE, Fabrice ZAPPULLA.
Application Number | 20130185441 13/782915 |
Document ID | / |
Family ID | 35335450 |
Filed Date | 2013-07-18 |
United States Patent
Application |
20130185441 |
Kind Code |
A1 |
HELAINE; Hubert ; et
al. |
July 18, 2013 |
MOBILE RADIO COMMUNICATION DEVICE AND METHOD OF MANAGING
CONNECTIVITY STATUS FOR THE SAME
Abstract
The present invention provides a method of managing connection
status for a channel connecting a server device to a mobile radio
communication device including a client/server pair (44, 46), the
method including upon receiving an indication that the
client/server pair (44, 46) is disconnected, sending from the
mobile radio communication device a status signal to the server
device (46) indicating that the client (44) has reset connection
between the client/server pair (44, 46), and upon receiving an
indication that the client (44) has connected to the server device
(46), sending from the mobile radio communication device a status
signal to the server device (46) indicating that the client (44) is
connected to the server device (46).
Inventors: |
HELAINE; Hubert; (Andresey,
FR) ; ZAPPULLA; Fabrice; (Eaubonne, FR) |
|
Applicant: |
Name |
City |
State |
Country |
Type |
NEC CORPORATION; |
Tokyo |
|
JP |
|
|
Assignee: |
NEC CORPORATION
Tokyo
JP
|
Family ID: |
35335450 |
Appl. No.: |
13/782915 |
Filed: |
March 1, 2013 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
|
|
12066802 |
Jan 14, 2010 |
|
|
|
PCT/JP2006/319003 |
Sep 25, 2006 |
|
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13782915 |
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Current U.S.
Class: |
709/227 |
Current CPC
Class: |
H04W 76/19 20180201;
H04W 80/06 20130101; H04W 76/20 20180201; H04L 65/1069 20130101;
H04W 88/02 20130101 |
Class at
Publication: |
709/227 |
International
Class: |
H04L 29/06 20060101
H04L029/06 |
Foreign Application Data
Date |
Code |
Application Number |
Sep 26, 2005 |
GB |
0519573.0 |
Claims
1. A method of managing connection status for a server device
within a mobile radio communications device, the mobile radio
communications device including a local client/server pair, the
method including the steps of: receiving an indication of a change
of connection status for a local client/server pair, wherein said
change of connection status is a change to a state in which the
server is listening for a connection from a remote client, or
receiving an indication of a change of network status; processing
the received indication to discriminate between said change of
connection status and said change of network status; generating, in
response to said processing, a client/server status signal when a
change of connection status for the local client/server pair
occurs, the generated client/server status signal indicating that
the server is listening for a connection from the remote client,
and generating a different status signal when a change of network
status occurs; and sending the generated client/server status
signal and/or said different status signal to the server
device.
2. The method as claimed in claim 1, wherein, when an indication of
a change of connection status for the local client/server pair is
received, said processing step determines the nature of said
change; and said generation step generates a corresponding
client/server status signal in dependence on a result of said
determination.
3. The method as claimed in claim 1, wherein the client/server
status signal indicating the server is listening for a connection
from the remote client is generated prior to the remote client
sending a request.
4. The method as claimed in any previous claim, wherein a
client/server status signal indicating the client/server pair is
connected is generated after a remote client sends a request.
5. The method as claimed in claim 3, wherein said client/server
status signal indicating the client/server pair is connected is
generated subsequent to the client/server status signal indicating
that the server is listening for a connection from a remote
client.
6. A mobile radio communications device for communicating with a
network, the device comprising: a local client/server pair; and a
device for managing connection status of a server device for a
channel between said server device and the local client/server
pair; wherein said managing device is configured for: receiving an
indication of a change of connection status for a local
client/server pair, wherein said change of connection status is a
change to a state in which the server is listening for a connection
from a remote client, or receiving an indication of a change of
network status; processing the received indication to discriminate
between said change of connection status and said change of network
status; generating, in response to said processing, a client/server
status signal when a change of connection status for the local
client/server pair occurs, the generated client/server status
signal indicating that the server is listening for a connection
from the remote client, and generating a different status signal
when a change of network status occurs; and sending the generated
client/server status signal and/or said different status signal to
the server device.
7. The device as claimed in claim 6, further comprising a smartcard
server device.
8. The device as claimed in claim 6, wherein said client/server
pair is a transport connection protocol client/server pair.
9. The device as claimed in claim 6, wherein said managing device
is configured for: processing a received indication of a change of
connection status for the local client/server pair to determine the
nature of said change; and generating a corresponding client/server
status signal in dependence on said determination.
10. The device as claimed in claim 9, wherein the managing device
is configured such that the client/server status signal indicating
the server is listening for a connection from the remote client is
generated prior to a remote client sending a request.
11. The device as claimed in claim 9, wherein the managing device
is configured such that a client/server status signal indicating
the client/server pair is connected is generated after the remote
client sends a request.
12. The device as claimed in claim 9, wherein the managing device
is configured such that said client/server status signal indicating
the client/server pair is connected is generated subsequent to the
client/server status signal indicating that the server is listening
for a connection from the remote client.
13. A server device for use with a mobile radio communications
device, the server device comprising: a first device for
establishing a channel with a local client/server pair of the
mobile radio communications device; a second device for receiving a
client/server status signal from the mobile radio communications
device when a change of connection status for the local
client/server pair occurs, the client/server status signal
indicating that the server is listening for a connection from the
remote client, and for receiving a different status signal from the
mobile radio communications device when a change of network status
occurs; a third device for processing the received status signal to
discriminate between said client/server status signal and said
different status signal; and a fourth device for maintaining the
channel when said client/server status signal is received.
14. The device as claimed in claim 13, wherein said second device
is configured to receive a subsequent client/server signal
indicating that the client/server pair is connected; and said
server device comprises a fifth device for exchanging data over
said channel after receipt of said client/server signal indicating
the client/server pair is connected.
15. A method performed in a server device for managing
communication with a mobile radio communications device, the method
including the steps of: establishing a channel with a local
client/server pair of the mobile radio communications device;
receiving a client/server status signal from the mobile radio
communications device, the client/server status signal indicating
that the server is listening for a connection from the remote
client, wherein the status signal is a client/server status signal
generated in response to a change in client/server status or
receiving a different status signal generated in response to a
change in network status; processing the received status signal to
discriminate between said client/server status signal and said
different status signal; and maintaining the channel when said
processing indicates a client/server status signal is received.
16. The method as claimed in claim 15, wherein said receiving step
comprises receiving a subsequent client/server signal indicating
that the client/server pair is connected; and wherein said method
further comprises exchanging data over said channel after receipt
of said client/server signal indicating that the client/server pair
is connected.
Description
[0001] This application is a continuation of U.S. application No.
12/066,802 filed Jan. 14, 2010, which is a national stage entry of
Japanese Patent Application No. PCT/JP2006/319003 filed Sep. 25,
2006, which claims priority from GB Patent Application No. 0519573
filed Sep. 26, 2005, the disclosures of all of which are
incorporated herein by reference in their entirety.
FIELD OF THE INVENTION
[0002] The invention relates to a mobile radio communication
device, and a method of managing connectivity status for the
same.
BACKGROUND ART
[0003] The increased functionality offered by a mobile radio
communication device such as a cellular phone handset has arisen
from technical developments relating to the various circuit
elements of the cellular phone handset, the operating and
application software and also from improvements relating to network
operation and characteristics.
[0004] One recent development has focused on the Subscriber
Identification Module (SIM) card employed within a mobile phone
handset and, in particular, relates to the adoption of
internet-related technology within a SIM card device.
[0005] One such development relates to the provision of a web
server running in a subscriber identification module card, which
allows for the provision of SIM-based services whilst taking
advantage of the multimedia capability already present in the
mobile phone handset and relating, for example, to data display
and/or information processing.
[0006] That is, the provision of such a smartcard web server allows
for internet-related design characteristics to be incorporated into
SIM card applications, and this can lead to advantages such as
enhanced and unified graphical user interface (GUI) for SIM-based
services, the storage of static pages such as a browser's homepage,
and also the use of dynamic web pages.
[0007] Such pages can prove attractive to network operators as a
means for increasing on-line revenue.
[0008] Further, control of a SIM-based services menu can readily be
profiled so as to match the end-user's preferences and common
requirements.
[0009] Connectivity with the mobile phone handset to the smartcard
web server is achieved by way of a Bearer Independent Protocol
(BIP) channel, and so use of such a BIP server allows support
within the mobile phone handset of the local smartcard web server
which is then readily accessible by the handset browser.
DISCLOSURE OF THE INVENTION
Problems to be Solved by the Invention
[0010] However, limitations are nevertheless experienced concerning
the manner in which channel status signals are developed and
employed within the mobile phone handset particularly with regard
to connectivity to the smartcard web server and to a related
transport connection protocol (TCP) client/server pair.
[0011] As discussed further below with regard to limitations found
in the related art, it is found that the mobile phone handset can
disadvantageously lose local connection within the TCP
client/server pair within the mobile phone handset, and then, the
browser associated with the smartcard web server will then make an
attempt at reconnection. The data exchanges that arise in relation
to such reconnection will lead to a decrease in the speed of
operational processing within the mobile phone handset.
[0012] Further, it can disadvantageously be found that limitations
arise with regard to the manner in which indications can be
provided to the smartcard we server device that the server of the
TCP client/server pair is ready for re-connection and, in order to
ensure successful further connection, the smartcard web server will
server to close, and then, re-open the channel. Such attempted
re-connection, and associated closing and re-opening of the channel
will likewise lead to an increase in message being generated ,and
this is found to have a disadvantageous effect of slowing down the
data exchange in the mobile phone handset.
[0013] In general, current systems are disadvantageously limited
since, for client mode operation, there is generally only provided
an arrangement for indicating the status of the bearer connection
by means of "line dropped with packet connection activated" status
signals or "line dropped with packet connection deactivated" status
signals.
[0014] FIGS. 1, 2 and 3 are timing charts showing channel status
found in the related mobile radio communication device.
[0015] Hereinbelow is explained the problem found in the related
mobile radio communication device, with reference to FIGS. 1 to
3.
[0016] FIG. 1 is a timing chart illustrating channel status events
with regard to status transmissions within a mobile radio
communication device handset and between a network connection 10, a
browser 12, a TCP/IP client 14, a TCP/IP server 16, USAT 18, USIMM
20, and a web server circuit card 22 in the form of a Universal
Mobile Telecommunications System Integrated Circuit Card
(UICC).
[0017] As noted above, in accordance with current IP specifications
for operation in client mode, there is only one manner in which
status of the bearer connection is provided by way of "line dropped
with packet connection activated" and "line dropped with packet
connection deactivated" status signals.
[0018] As illustrated in FIG. 1, with a normal service signal 24
originating from the network 10, channel status signals 26 are
provided from SAT 18 and USIMM 20, confirming packet connection
activated and link established.
[0019] Then, the mobile radio communication device is in a mode
waiting for receipt of a new network status, as indicated by an
arrow 28.
[0020] When a new network status, for example "no service" is
received from the network, as indicated by an arrow 30, the channel
status 32 to the circuit card 22 is changed as indicated to packet
connection activated and line dropped.
[0021] It should however be appreciated that, the "no service"
signal can arise through the mobile phone handset being out-zone
temporarily, but with its packet connection context, not
deactivated by the network 10. This leads to the "line dropped with
packet connection activated" or "line dropped" status signal
32.
[0022] The mobile radio communication device is then again waiting
for a new network status such as indicated by an arrow 34.
[0023] On receipt of a new network status, such as "service
detached" as indicated by an arrow 36 from the network 10, the
packet connection context is then deactivated by the network 10,
and the data link is downed. This leads to the channel status
signal 38 indicating "packet connection deactivated" or "line not
established".
[0024] It should be however be appreciated that the above-mentioned
channel status signals are used primarily in order to indicate the
network status, i.e., the incoming signals arising from the network
source 10, and are not employed for describing the TCP
client/server pair status connection.
[0025] The TCP client/server pair status connection can comprise
various status such as "listening", "listening and connected",
"listening and disconnected", and, again "listening".
[0026] When listening, the TCP/IP server 16 is waiting for
connection from a remote client, and the status "listening and
connected" arises when connection from a remote client to the
TCP/IP server 16 is achieved for subsequent data exchange.
[0027] Once the remote client disconnects this connection to the
TCP/IP server 16, the shutdown status is sent to the TCP/IP server
16, leading to the "listening and disconnected" status.
[0028] As noted above, various limitations and related problems can
arise from the above-mentioned channel status management.
[0029] For example, with regard to the bearer connection channel
status signals currently arising, i.e. "link established or packet
connection activated" or "link not established or packet connection
not activated", the subscriber identification module card
(smartcard) web server is enable to determine if a client is
connected or not, as indicated by the "link established" and "link
not established" status signals.
[0030] Furthermore, in this scenario, it will not be possible for
the subscriber identification module card (smartcard) web server to
determine the difference between a client connection status signal
and a network change status signal.
[0031] Thus, if the network 10 sends a change status signal to the
mobile radio communication device, a revised channel status signal
will be sent to the web server circuit card 22.
[0032] For example, if a "SERVICE DETACHED" status signal is
received from the network 10, the mobile radio communication device
then will send a "link not established" signal as indicated in FIG.
1 such that the web server circuit card 22 will then proceed to
send a close channel status signal. This close channel status
signal will serve to reset the local connection with the
client.
[0033] Such operation proves particularly disadvantageous in that
the user will then lose its local connection temporarily, and the
browser 12 will attempt a re-connection and the data exchanges
arising in relation to such attempted re-connection. This will lead
to a decrease in possible speed for the data exchanges within the
mobile radio communication device.
[0034] Such problematic operation within the current state of the
art is illustrated with reference to FIG. 2.
[0035] FIG. 2 is a timing diagram showing status signals arising
within a network connected mobile radio communication device, and
illustrating the network connection 40, the browser 42, the TCP/IP
client 44, the TCP/IP server 46, the BIP/SATS 48, and the web
server circuit card 50.
[0036] The channel status indicated by the web server circuit card
50 is initially an OPEN_CHANNEL status indicated by an arrow 52,
which arises with an automatic re-connection flag off.
[0037] To initiate activity, the browser 42 sends a first request
as indicated by an arrow 54, but, prior to this, the BIP channel
status is indicated by an arrow 56 as "link not established".
[0038] This TCP connection status as sent to the web server circuit
card 50 then changes to "link established" as indicated by an arrow
58 upon connection 60 being achieved between the TCP/IP client 44
and the TCP/IP server 46.
[0039] The browser 42 and the web server client card 50 are then
able to exchange data, as indicated at block 62, prior to receipt
of a "service detached" status signal 64 received from the network
40. In this scenario, the network 40 releases the packet connection
during data exchanges between the web server circuit card 50 and
the browser 42.
[0040] A CLOSE_CHANNEL status signal 66 is then generated and
issued by the web server circuit card 50 in response to the web
server circuit card 50 receiving a "link not established" status
signal on its BIP channel.
[0041] Disconnection 68 between the TCP/IP client 44 and the TCP/IP
sever 46 then arises such that the close channel status signal 66
transmitted from the web server circuit card 50 leads to the
browser 42 losing connection to the web server circuit card 50.
[0042] Subsequent to the disconnection 68 between the TCP/IP client
44 and the TCP/IP server 46, the channel status signal delivered to
the web server circuit card 50 remains as "link not
established".
[0043] As noted above, such loss of connection and attempted
re-connection in the browser 42 leads to a disadvantageous decrease
in the rate of data exchanges within the mobile radio communication
device.
[0044] FIG. 3 is a timing diagram illustrating channel status
signals arising within a mobile radio communication device
according to the current art, and illustrating standard TCP
connection with channel status events arising without network
interaction.
[0045] FIG. 3 illustrates in particular a further problem arising
in the current art in that there is no manner for indicating to the
web server circuit card 50 that the TCP/IP server is ready to
receive a further connection consistent with the previous
connection.
[0046] Accordingly, in order to ensure operational connectivity,
the web server circuit card 50 has to operate to close, and then,
re-open the BIP channel in spite of presence of the automatic
re-connection flag.
[0047] In view of such operation, the number of messages arising
within the mobile radio communication device channel will increase
and serve to slow down the general data change within the mobile
radio communication device such that normal service from the mobile
radio communication device will be unavailable temporarily, i.e.
during the close/open phase of operation initiated by the web
server smart card.
[0048] FIG. 3 illustrates the network 40, the browser 42, the
TCP/IP client 44, the TCP/IP server 46, a BIP/SA 48, and the web
server circuit card 50.
[0049] An OPEN_CHANELL status signal 52 is provided from the web
server circuit card 50, arising with the automatic re-connection
flag set.
[0050] In this scenario illustrated in FIG. 3, no status signals
are transmitted from the network connector 40, and the process
proceeds to the browser 42 sending a first request, as indicated by
an arrow 54.
[0051] Prior to sending such a first request, a channel status
signal "link not established" is sent from the TCP/IP server 46 to
the web server circuit card 50, as illustrated by an arrow 56.
[0052] An event is changed to the channel status to "link
established", as indicated by an arrow 58, and subsequent to
connection 60 is established between the TCP/IP client 44 and the
TCP/IP server 46.
[0053] The subsequent to the connection 60 and at the time of
establishing the channel status 58, the TCP connection status
signal is sent to the web server circuit card 50, but there is no
information concerning the server status, in particular, whether
the TCP/IP server 46 might be considered to be listening on the
channel.
[0054] Subsequent to the link being established, the browser 42 and
the web server circuit card 50 exchange data as required, as
indicated by block 62.
[0055] As will be appreciated, the channel status and connection
modes discussed above in relation to FIG. 3 are consistent with
those arising initially in relation to FIG. 2.
[0056] However, in FIG. 3, subsequent to the exchange of data
between the browser 42 and the web server circuit card 50, a
connection cut is experienced between the TCP/IP client 44 and the
TCP/IP server 46, as indicated by an arrow 72, and this leads to a
change in channel status to "link not established", as indicated by
an arrow 74.
[0057] A signal indicative of the connection cut 72 may be sent
while a receiver buffer is empty and not during or before a
transmission so as to simplify the web server circuit card 50.
[0058] Assuming the second request 76 leads to a successful
connection, as indicated by an arrow 78, the TCP/IP server 46
initiates the change in connection status to the web server circuit
card 50 such that the channel status to the web server circuit card
50 is changed to "link established", as indicated by an arrow
80.
[0059] With the link now established, the browser 42 and the web
server circuit card 50 initiate a new data exchange, as indicated
by block 82.
[0060] The closing of the channel status 74, the subsequent second
request 76 sent by the browser 42, the attempted further connection
78, and status change 80 will result in a large number of messages
which grow to disadvantageously slow down data exchange between the
browser 42 and the web server circuit card 50.
[0061] In view of the above-mentioned problems in the current art,
it is an object of the present invention to provide a method of
managing connectivity status in a mobile radio communication
device, and a mobile radio communication device capable of managing
connectivity status thereof, both of which are able to solve the
problems in the current art.
Solution to the Problems
[0062] In order to achieve the above-mentioned object, the present
invention provides a method of managing connection status for a
channel connecting a server device to a mobile radio communication
device including a client/server pair, the method including upon
receiving an indication that the client/server pair is
disconnected, sending from the mobile radio communication device a
status signal to the server device indicating that the client has
reset connection between the client/server pair, and upon receiving
an indication that the client has connected to the server device,
sending from the mobile radio communication device a status signal
to the server device indicating that the client is connected to the
server device.
[0063] It is preferable that the method further includes sending a
status signal indicating that the sever device is waiting form the
connection from a remote client.
[0064] It is preferable that the method further includes sending a
combination of status signals indicating that the client is
connected to the server device and that the server device is ready
for a follow-on connection.
[0065] It is preferable that the method further includes sending a
status signal indicating that when the client has reset the
connection with the server device, the server device is ready for a
follow-on connection.
[0066] It is preferable in the method that the status signal is
arranged to arise in an open channel configuration with an
automatic reconnection flag set, and wherein the status signal is
defined by reference to an open channel with the automatic
connection flag set.
[0067] It is preferable that the method further includes sending a
status signal indicating that the client is connected to the server
device as a connected status event. For example, such a status
signal is a signal responsive to a command signal, such as an
open-channel signal and a send-data signal.
[0068] It is preferable in the method that a channel status
indicating that the client has reset the connection is provided as
a connected or disconnected status event.
[0069] The present invention further provides a mobile radio
communication device including a server device, and a channel for
connection of the server device therein, the mobile radio
communication device further including a client/server pair, the
mobile radio communication device being arranged for, upon
receiving an indication that the client/server pair is
disconnected, sending a status signal indicating to the server
device that the client has reset connection between client/server
pair, and, upon receiving an indication that the client is
connected to the server device, sending a status signal to the
server device indicating that the client is connected to the server
device.
[0070] It is preferable in the mobile radio communication device
that a status signal is transmitted indicating that the server
device is waiting for the connection from a remote client.
[0071] It is preferable in the mobile radio communication device
that a combination of status signals is transmitted indicating that
the client is connected to the server device and that the server
device is ready for a follow-on connection
[0072] It is preferable in the mobile radio communication device
that a status signal is transmitted indicating that when the client
has reset the connection with the server device, the server device
is ready for a follow-on connection.
[0073] It is preferable in the mobile radio communication device
that the status signal is arranged to arise in an open channel
configuration with an automatic reconnection flag set, and wherein
the status signal is defined by reference to an open channel with
the automatic connection flag set.
[0074] It is preferable in the mobile radio communication device
that the channel status indicating that the client has reset the
connection is provided as a connected or disconnected status
event.
[0075] For instance, the server device comprises a smartcard server
device.
[0076] Advantageously, the mobile radio communication device is
arranged for providing further channel status signals and signals
indicative of details as outlined above.
[0077] Thus, it will be appreciated that the present invention
allows for dividing the semantic reporting between the bearer
connection status and the transport connection status of the TCP
connection. This is particularly useful when a client of the server
device comprises a remote client.
Advantages Provided by the Invention
[0078] The present invention advantageously provides for a
subscriber identification module (smartcard) device operating in
server mode. This is advantageously achieved within the concept of
the present invention through dividing the reporting between the
bearer connection status and the transport connection status, i.e.
the TCP connection. This provides particularly useful when a client
of a subscriber identification module (smartcard) device comprises
a remote client.
BRIEF DESCRIPTION OF THE DRAWINGS
[0079] FIG. 1 is a timing diagram showing channel status events
arising in a mobile radio communication device in accordance with
the current state of the art.
[0080] FIG. 2 is a timing diagram showing channel status signals
arising in a mobile radio communication device in accordance with
the current state of the art.
[0081] FIG. 3 is a timing diagram showing channel status signals
arising in a mobile radio communication device in accordance with
the current state of the art.
[0082] FIG. 4 is a timing diagram illustrating channel status
signals arising in a mobile radio communication device in
accordance with the present invention.
[0083] FIG. 5 is a timing diagram illustrating channel status
signals arising in a mobile radio communication device in
accordance with the present invention.
INDICATION BY REFERENCE NUMERALS
[0084] 40 Network
[0085] 42 Browser
[0086] 44 TCP/IP client
[0087] 46 TCP/IP server
[0088] 48 BIP/SATS
[0089] 50 Web server circuit card
BEST EMBODIMENT FOR REDUCING THE INVENTION TO PRACTICE
[0090] In accordance with the present invention, in order to avoid
any confusion between the mobile radio communication device and the
web server circuit card 50, specific channel status signals are
generated in order to indicate the accurate TCP server status to
the web server circuit card 50.
[0091] A "link not established" status signal was transmitted to
the web server circuit card 50 when the local client disconnects in
the current state of the art. In accordance with the present
invention, the mobile radio communication device can be arranged to
send a "disconnection" status signal to the web server circuit card
50 in place of sending a "link not established" status signal.
[0092] Furthermore, instead of sending a "link established" status
to the web server circuit card 50 when the local client connects to
the server, the mobile radio communication device may be arranged
to send a "in connection" status signal to the web server circuit
card 50.
[0093] Furthermore, the mobile radio communication device, when
arranged to listen on a specified port of the web server circuit
card 50, can be arranged to send a "listening" status signal to the
web server circuit card 50.
[0094] The present invention is advantageous in providing improved
operation and management of the channels in the mobile radio
communication device as compared with the current state of the
art.
[0095] For example, the web server circuit card 50 when arranged
for operation in accordance with the present invention will be able
to discriminate between a network event and a TCP client/server
connection event.
[0096] Furthermore, the smartcard web server circuit card 50 can be
accessed from a location remote from the mobile radio communication
device, and can provide a specific local address.
[0097] The data exchanges between the mobile radio communication
device and the web server circuit card 50 can be improved. A
"listening" status signal is generated and received for each of the
web server circuit card 50 between subsequent TCP client
connections. The web server circuit card 50 will not then need to
initiate a close/open channel procedure in order to ensure the
current state of TCP server connectivity.
[0098] Through adoption of the three new channel status events
noted above, i.e. "connected", "disconnected" and "listening", the
following five channel status events can be implemented in
accordance with the present invention.
[0099] A "listening" status event indicates that the server is
waiting from a connection from a remote client, whereas a
"connected" status event indicates that a client is connected to
the server. For instance, this is indicated by an open channel
without an automatic re-connection flag.
[0100] The "disconnected" status indicates that the client has
reset the connection. This is indicated by, for instance, an open
channel without the automatic re-connection flag.
[0101] Through a combination of the above-mentioned three new
channel status events, there can be provided a "connected and
listening" channel status which indicates that the client is
connected to the server and that the server is ready for the
follow-up connection with a status of open channel with an
automatic re-connection flag.
[0102] Likewise, as combination of the above-mentioned three new
channel status events, there can be provided a "disconnected and
listening" channel status which indicates that the client has reset
the connection with the server and that the server is immediately
ready for the next attempted connection. This is as associated with
an open channel with an automatic re-connection flag, for
instance.
[0103] The adoption of the "connected and listening" and
"disconnected and listening" status will reduce the number of
events sent to the web server circuit card 50 since, without such
combining, the mobile radio communication device would send
consecutive "connected" and "listening" channel signals to the web
server circuit card 50.
[0104] An embodiment in accordance with the present invention is
explained hereinbelow with reference to FIGS. 4 and 5.
[0105] FIG. 4 is a timing diagram with channel status events
arising in a mobile radio communication device in accordance with
the embodiment of the present invention.
[0106] In particular, FIG. 4 serves to illustrate how the problems
illustrated in the timing diagram of FIG. 2 can be overcome by the
present invention.
[0107] Where appropriate similar reference numbers to those
employed in FIG. 2 are found in FIG. 4, and serve to indicate again
in FIG. 4 the signaling relationship between the network connector
40, the browser 42, the TCP/IP server 46, the TCP/IP client 44, the
BIP/SATS 48, and the web server circuit card 50.
[0108] Likewise, similar channel status events, requests 52 and 54,
connectivity, and data exchanges 60, 62 and 64 as found in FIG. 2
are likewise illustrated in FIG. 4.
[0109] However, the present invention illustrated in FIG. 4 is
different in operation from the current state of the art in that
the two altered channel status signals "listening" 84 and
"connected" 86 arise prior to the browser 42 sending a first
request 54, the initial connection 60 between the TCP/IP client 44
and the TCP/IP server 46, and the data exchange 62 between the
browser 42 and the web server circuit card 50.
[0110] The TCP connection status signal as indicated by arrows 84
and 86 is sent to the web server circuit card 50.
[0111] Subsequent to the data exchange 62 between the browser 42
and the web server circuit card 50, the "service detached" status
signal 64 again arises as initiated from the network connection 40
since, in this scenario, the network 40 releases the packet
connection context during the data exchange 62 between the browser
42 and the web server circuit card 50.
[0112] With the change in the channel status signals 84 and 86, the
web server circuit card 50 is then not influenced by the SERVICE
DETACHED network-originating signal 64, and the web server circuit
card 50, as indicated at 88, does not serve to close the BIP
channel.
[0113] The browser 42 and the web server circuit card 50 can then
continue to exchange data as indicated by block 90, and thus, the
disadvantages arising in the current state of the art and as
illustrated in FIG. 2 do not arise in the present invention.
[0114] FIG. 5 is a timing diagram of a mobile radio communication
device in accordance with the embodiment of the present invention,
and illustrates the manner in which the present invention can
overcome the problems of the current art as illustrated in FIG.
3.
[0115] The reference numerals shown in FIG. 3 are used also in FIG.
5. The network 40, the browser 42, the TCP/IP server 46, the TCP/IP
client 44, the BIP/SATS 48, and the web server circuit card 50, and
similar channel status and connectivity 52, 54, 60, 62, 72, 76, 78
and 82 as illustrated in FIG. 3 arise in FIG. 5.
[0116] However, in accordance with the present invention, the
different channel status signals arising in relation to the BIP
channel status lead to solution to the problems in the current
state of the art.
[0117] That is, prior to the browser 42 sending a first request 54,
a channel status "listening" signal 92 is delivered to the web
server circuit card 50 from the BIP/SATS 48.
[0118] Subsequent to the connectivity 60 achieved after the browser
42 has sent its first request 54, and prior to the data exchange 62
arising between the browser 42 and the web server circuit card 50,
the channel status is switched to "connected and listening" in
accordance with the present invention.
[0119] Subsequent to the connection cut 72 between the TCP/IP
client 44 and the TCP/IP server 46, the BIP channel status becomes
"disconnected and listening" as illustrated by an arrow 96. It
should be appreciated that a signal indicative of the connection
cut 72 may be sent when the receiver buffer is emptied and not
during or before data transport in order to simplify the web server
circuit card 50.
[0120] Subsequent to the successful connection 78, the channel
status changes to "connected and listening" as indicated by an
arrow 98, and subsequently the browser 42 and the smartcard web
server can then exchange new data as indicated by block 82.
[0121] As with FIG. 3, there is no interaction from the network 40
in FIG. 5.
[0122] The TCP server status can then be readily determined such
that it becomes readily possible to indicate to the web server
circuit card 50 that the
[0123] TCP server is ready to achieve further connectivity.
[0124] Additional messages such as those arising in the current
state of the art, as illustrated in FIG. 3, do not then arise in
the scenario as illustrated in FIG. 5 so as to lead to advantageous
improvements within the present invention.
[0125] The present invention provides for improved management of a
BIP channel connection status when in server mode, and serves to
divide the semantic report in between the bearer connection status
and the transport connection status of the TCP connection. This
proves particular useful in that the client of the web server card
comprises a remote client.
[0126] However, even with a local client, the management of the
connection status for the BIP channel between, for example, a
mobile radio communication device and a UICC smartcard when in
server mode is advantageously improved.
[0127] It should be appreciated in general that the present
invention is not restricted to the details of the above-mentioned
embodiments. For example, the present invention not only relates to
local TCP connection, but is also equally relevant to remote
connection. For example, if an IP address of a mobile radio
communication device is known to a user, the user can then connect
to the web server through his/her own browser.
INDUSTRIAL APPLICABILITY
[0128] The present invention can be extended for use in relation to
a variety of peripheral devices for use, for example, in relation
to a handset such as a demotic device, memory cards in the form of
a SD card or MMC cards, camera devices or indeed any peripheral
device offering a server feature employing a mobile TCP/IP
stack.
[0129] Likewise, the present invention can find employment in
relation to any appropriate protocols used between such peripherals
and handling delegation of TCP connections.
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