Multiplex communications – Diagnostic testing – Determination of communication parameters
Reexamination Certificate
2002-06-07
2004-12-14
Jung, Min (Department: 2663)
Multiplex communications
Diagnostic testing
Determination of communication parameters
C709S228000
Reexamination Certificate
active
06831897
ABSTRACT:
The present invention relates to a data communication apparatus which shortens the time needed for a pre-communication-protocol that is carried out prior to actual communication in data communication using a modem, such as facsimile communication.
BACKGROUND ART
Recently, this type of data communication apparatus performs data communication using a V.34 modem (28.8 kbps) which is specified by the ITU-T. The ITU-T also recommends T30 ANEXF (so-called Super G3) as facsimile communication standards using the V.34 modem for facsimile machines. A pre-communication protocol for facsimile communication is carried out according to the standards, after which communication of image data is executed.
Such a communication protocol will be explained based on the sequence chart illustrated in FIG.
13
.
FIG. 13
is a control signal chart for a pre-protocol for facsimile communication according to prior art.
Referring to
FIG. 13
, reference character
13
a
denotes a communication protocol for selecting a modulation mode from among a V34 half duplex, V34 full duplex, V17 half duplex, etc. Reference character
13
b
denotes a communication protocol for implementing line probing to check a line and determine various kinds of parameters. Reference character
13
c
denotes a communication protocol for modem training. Reference character
13
d
denotes a communication protocol for setting a modem parameter. Reference character
13
e
denotes a communication protocol for exchanging a facsimile control signal. Reference character
13
f
denotes a data communication protocol for the primary channel. The upper side in the diagram is a sequence for a caller modem, and the lower side is a sequence on an answer modem, and the sequences progress from left to right.
The above communication protocols will be discussed specifically.
First, in the communication protocol
13
a
for selecting a modulation mode and communication protocol, which permit communication between a caller modem and an answer modem, are selected through a V.21 modem (300 bps, full duplex) after a line connection is established. A facsimile machine using a V.34 modem selects a V.34 modem as the modulation mode and facsimile communication as a communication protocol.
Then, the communication protocol
13
b
for line probing checks the line by transmitting a line probing tone from the caller modem and receiving it on the answer modem, and selects a training parameter based on the result of the line inspection.
In the communication protocol
13
c
for modem training, the caller modem sends training signals based on the training parameter selected under the line probing communication protocol
13
b
, while the answer modem receives the training signals, learns a filter coefficient for an adaptive equalizer for compensating the line characteristic and checks the reception quality of the training signals.
In the communication protocol
13
d
for selecting a modem parameter, modem parameters are negotiated between the caller modem and answer modem in full duplex-communication at 1200 bps, and an optimal modem parameter is selected from the modem parameters preset in the apparatus, the result of the line inspection and the inspection of the reception quality of the training signals.
The communication protocol
13
e
for a facsimile control signal is an ordinary facsimile protocol to execute negotiation of facsimile control signals NSF, CSI, DIS, TSI, DCS, CFR, etc. in full duplex communication at 1200 bps.
In the data communication protocol
13
f
, the caller modem sends image data and the answer modem receives the image data, in half duplex communication at 2400 bps to 28.8 kbps. In the case of performing communication at the maximum communication rate of 28.8 kbps, image data can be communicated in approximately three seconds per a sheet of paper of size A4.
The aforementioned modem performs communication in accordance with the training parameter selected under the communication protocol
13
b
for communication line probing and the modem parameter selected under the communication protocol
13
d
for selection of a modem parameter. To compensate the line characteristic, the receiver modem executes communication using the filter coefficient that has learned in the modem training
13
b
. This ensure optimal data communication according to the line quality.
The above-described prior art structure involves five channels of a pre-protocol before starting sending image data after line establishment, and thus requires about 7 seconds. By contrast, since electric transmission of a single sheet of image data at the maximum communication rate of 28.8 kbps takes about 3 seconds, the pre-protocol requires over 60% of the entire time of 11 seconds required for transmission of one sheet of an original including the post-protocol of about 1 second This time needed for the pre-protocol gets greater as the number of transmission/reception lines increases, and generates wasteful time and communication cost.
DISCLOSURE OF INVENTION
Accordingly, it is an object of the present invention to provide a data communication apparatus capable of shortening the time for pre-communication protocol including setting of various parameters for a modem and the modem training time.
A data communication apparatus according to this invention comprises communication means for executing pre-communication protocol for exchanging a communication function with a communication destination and transmission and reception of data; storage means for storing a plurality of communication parameters in association with identification numbers of apparatuses to be the communication destination; and control means for, when an apparatus of the communication destination is a communication apparatus registered in the storage means, activating the communication means using the communication parameter associated with that communication destination, read from the storage means, to thereby execute data communication according to a short protocol, and, when an apparatus of the communication destination is not a communication apparatus registered in the storage means, activating the communication means using a communication parameter acquired under a communication protocol for that communication to thereby execute data communication.
More specifically, at the time of carrying out a normal communication protocol, a modulation mode, a communication protocol, a modem parameter and a modem's optimal training time, etc., which are set by four communication channels, e.g., a communication channel for selecting a modulation mode, a communication channel for implementing line probing, a communication channel for modem training, and a communication channel for setting a modem parameter, are stored for each destination communication apparatus, and subsequent communication is implemented based on the stored information.
At this time, the control means determines if an apparatus of the communication destination is a communication apparatus registered in the storage means based on either whether or not an operation key for specifying a memory address in the storage means where an identification number and a communication parameter of the communication destination are stored has been depressed, or sender identification information informed from an exchange.
At this time, the control means transmits an instruction signal of the same modulation system as a call-initiating menu signal in place of the call-initiating menu signal to thereby inform the communication destination of execution of a short protocol.
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Noguchi Yoshihiro
Takagi Genzou
Greenblum & Bernstein P.L.C.
Jung Min
Panasonic Communications Co. Ltd.
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