U.S. patent number RE28,867 [Application Number 05/329,650] was granted by the patent office on 1976-06-15 for moving object communication control system.
This patent grant is currently assigned to Sumitomo Electric Industries, Ltd.. Invention is credited to Takeshi Baba, Tetsuro Maruhama, Tsuneo Nakahara, Kenji Shibuya, Kenichi Yoshida.
United States Patent |
RE28,867 |
Baba , et al. |
June 15, 1976 |
**Please see images for:
( Certificate of Correction ) ** |
Moving object communication control system
Abstract
A communication system between mobile and wayside stations
wherein the mobile stations are traveling on a track which is
divided into sections by means of an open-type transmission line
paralleling the track. A frequency selection and conversion device
for each section of transmission line or track is connected to the
transmission line to define the length of each section. A series of
lower frequency carriers transmitted on the line are allotted
respectively to each specific section of transmission line. These
low-frequency carriers travel with a low loss along the
transmission line and they are selected and converted by their
respective frequency selection and converter device to a common
high-frequency carrier signal for leaky transmission to a mobile
station on the corresponding track section. These signals are used
for train control and other communication signals may be
transmitted on the same transmission line by a high-frequency
carrier signal which is common to all sections, such that the
common signal will leak from the transmission line for reception by
a mobile station no matter its location on the track.
Inventors: |
Baba; Takeshi (Tokyo,
JA), Shibuya; Kenji (Ohmiya, JA), Maruhama;
Tetsuro (Amagasaki, JA), Nakahara; Tsuneo
(Nishinomiya, JA), Yoshida; Kenichi (Sakai,
JA) |
Assignee: |
Sumitomo Electric Industries,
Ltd. (Osaka, JA)
|
Family
ID: |
27295172 |
Appl.
No.: |
05/329,650 |
Filed: |
February 5, 1973 |
Related U.S. Patent Documents
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Application
Number |
Filing Date |
Patent Number |
Issue Date |
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Reissue of: |
845167 |
Jul 28, 1969 |
03629707 |
Dec 21, 1971 |
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Foreign Application Priority Data
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Jul 30, 1968 [JA] |
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43-54099 |
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Current U.S.
Class: |
455/523; 246/8;
246/167R; 246/30; 343/770 |
Current CPC
Class: |
H04B
5/0018 (20130101); H04J 1/04 (20130101) |
Current International
Class: |
H04B
5/00 (20060101); H04J 1/04 (20060101); H04J
1/00 (20060101); H04b 001/00 () |
Field of
Search: |
;246/8,30,167R
;325/51,52,54,55 ;340/48 ;343/770 |
References Cited
[Referenced By]
U.S. Patent Documents
Primary Examiner: Mayer; Albert J.
Claims
We claim:
1. A communication system between mobile and a wayside stations,
said mobile stations traveling on a track divided in sections by
means of an open-type transmission line paralleling the track, a
frequency selection and conversion device for each section along
said open-type transmission line and connected thereto at the
proper position to define the length of each section, means to
transmit a series of first lower frequency carriers on said
open-type transmission line at a low loss from said wayside
station, said carriers allotted respectively to each specific
section of said open-type transmission line, said selection and
conversion devices operable to select and convert their respective
first lower frequency carrier to a first higher frequency carrier
for leaky transmission from said transmission line to a mobile
station on the corresponding track section, an antenna for each
mobile station for receiving and transmitting signals to said
open-type transmission line.
2. The communication system of claim 1 wherein the frequency of
said first higher frequency carrier is common to all sections of
said open-type transmission line. .[.3. The communication system of
claim 1 characterized by means to transmit at least one
high-frequency carrier which is common to all of said sections from
said wayside station or said mobile stations
on said open-type transmission line..]. 4. The communication system
of claim .[.3.]. .Iadd.1 .Iaddend.characterized in that selected of
said mobile stations are .Iadd.substituted by .Iaddend.stationary
ground stations coupled through their corresponding of said
frequency selection
and conversion devices directly to said transmission line. 5. The
communication system of claim 1 .[.characterized by means on
selected of said.]. .Iadd.wherein a .Iaddend.mobile .[.stations to
transmit.]. .Iadd.station traveling along a track section transmits
.Iaddend.at least one second higher frequency carrier .[.common to
all of said sections.]. from its .[.respective.]. antenna to said
transmission line.[.,.]. .Iadd.and .Iaddend.said conversion device
for the corresponding track section of said open-type transmission
line .[.being.]. .Iadd.is .Iaddend.operable to convert said carrier
of second higher frequency to .[.a.]. .Iadd.the .Iaddend.second
lower frequency .Iadd.allotted to said corresponding section on
which said mobile station travels .Iaddend.for
transmission along said line at a low loss to said wayside station.
6. The communication system of claim .[.1.]. .Iadd.5
.Iaddend.characterized in that selected of said mobile stations are
.Iadd.substituted by .Iaddend.stationary ground stations coupled
through their corresponding of said frequency selection and
conversion devices directly to said
transmission line. 7. The communication system of claim 1 wherein
said
open-type transmission line is an open-type coaxial transmission
line. 8. The communication system of claim 7 wherein said coaxial
line has an outer conductor sheath with a longitudinal series of
alternately slanted slots having a spacing pitch P, said lower
frequency .[.carries.]. .Iadd.carriers .Iaddend.all having a
frequency regulated by the condition ##EQU8## and said higher
frequency carriers all having a frequency regulated by the
condition ##EQU9##
Description
The present invention relates to a moving object communication and
control system and particularly to such a system wherein the
transmission of carriers for various different types of information
between central stations and moving objects or between fixed
stations are done by one common open-type transmission line.
In recent times many studies are being made of automatic operation
systems for moving bodies, especially railroad trains with a view
to their safe operation at high speeds and dense traffic. Such
automatic operation systems contemplate a partial or total
substitution of train operation now done by humans with an
electronic technique which utilizes an electronic computer as its
central data processor. In the system referred to above, it is
necessary to transmit and process a great variety of information
for train operation and passenger service.
The various types of information of such a system may be classified
under two major categories: (1), those in which the transmission of
information between the central station and each train can be done
simultaneously by a common channel, and (2), those in which the
transmission of information between the central station and each
train must be done by an independent channel. Information for local
control, especially the information concerning the location, speed
and the like of each individual train comes under category (2),
while the information for common train operation control and
passenger service such as telephone, television, radio, etc. may be
classified under category (1).
What is referred to as the local control above refers to the
ability of the control to allow only one train to be present in one
section in order to ensure a safe distance between traveling
trains, the railroad track being divided into sections of a
suitable length.
The present invention provides a moving object communication
control system in which the various types of information belonging
to the aforementioned categories are transmitted by means of one
common open-type transmission line.
In the system of the present invention, the information belonging
to category (1) is transmitted on one open-type transmission line
by a channel of a common higher carrier frequency, this carrier
propagating and partly leaking along the line and being received by
all trains. The information belonging to the category (2) is
transmitted also on the same line by an independent carrier of a
lower carrier frequency which is allotted to a selected section of
the track and this carrier is converted at an end of a selected
section to a carrier of a higher frequency which is common to all
sections over the track, the converted carrier thus propagates and
partly leaks along the selected section of the transmission line
and is received by a train present in that section conversely
individual information from trains present in various sections is
radiated by a carrier wave of a higher frequency which is common to
all sections over the open-type transmission line, and is coupled
by the transmission line, converted to the carriers by lower
frequency allotted to the individual section and transmitted to the
central station.
The particular feature of the present invention is that the various
carriers of lower frequency are transmitted with a low-transmission
loss over a long distance of the open-type transmission line and
converted to a carrier of a higher frequency which is common to all
sections of the transmission line, and a carrier of another higher
frequency from the trains which is common to all sections is
coupled with the transmission line, and converted to an independent
carrier of a lower frequency which is allotted to each section and
transmitted in the open-type transmission line to the central
station with a low-transmission loss.
In consequence, it is not at all necessary to change the carrier
frequency to the particular frequency allotted to each section
every time the train travels one section. Therefore a switch over
device for the information channel is not necessary in the system.
The communication device aboard the train may be a common frequency
transmitter and receiver. This makes the system more economical and
makes the maintenance of the apparatus easier.
Other features and advantages of the present invention will be
clear from consideration of the following detailed description and
accompanying drawings.
FIG. 1 shows a conceptual diagram of a system according to the
present invention.
FIG. 2 shows a leaky coaxial cable as an example of the open-type
transmission line used for the system of the present invention.
FIG. 3, FIG. 5 and FIG. 6 are schematic diagrams explaining the
operation of the system of FIG. 1.
FIG. 4 is a diagram of the frequency spectrum of the carrier
frequencies for the various types of information of the system of
FIG. 1.
Referring now to FIG. 1, there is shown a system in accordance with
the teachings of the present invention in which 1 denotes a central
station including an electronic data processor and communication
apparatus, 2 an open-type transmission line installed along the
track, 3 a train which is able to couple with the leaked wave from
the open-type transmission line 2, 5 an apparatus for communication
aboard the train 3, 6 a track for moving objects and i and i+1
frequency selection and conversion devices which are placed at the
ends of local sections "i" and "i+1," of the line 2
respectively.
In the moving object communication control system of FIG. 1, the
information of the aforementioned category 1 is transmitted from
the central station 1 to the line 2 by using a carrier frequency
which is common for all sections.
This carrier is transmitted by the line 2 which leaks a portion of
it to outer space to be received by the apparatus for communication
aboard the train via the antenna 4.
On the other hand, the various types in information of the
aforementioned category (2) are transmitted by independent carrier
frequencies which are of first lower frequency range which does not
leak from the line 2 and are allotted respectively to the sections
of the line, each independent carrier being converted at the
initial end of a selected section by a frequency selection and
conversion device to a common carrier of the first higher frequency
which is able to leak partially from the line 2 and be received, if
a train is present, by the apparatus for communication aboard the
train via the antenna 4.
For example, the independent carrier allotted to section "i" is
converted by the frequency selection and conversion device "i" to a
common carrier of the first higher frequency to partially leak
during the section "i" and couple with the antenna aboard a
train.
Conversely, the various types of information from a train present
in some section is radiated from antenna 4 of the train by another
carrier of the second higher frequency, and coupled with the
open-type line 2, transmitted along said section and converted to
an independent carrier of a second lower frequency range by a
frequency selection and conversion device. This carrier wave does
not leak and is transmitted with a low-transmission loss to the
central station.
The communication between local stations (not shown) distributed
along the line 2 or between local station and central station are
performed in the same manner using the same line 2.
FIG. 2 shows a highly preferable open-type coaxial line as one of
the open-type transmission lines of the present invention. In FIG.
2, 11 denotes the inner conductor of a coaxial line, 12 the outer
conductor, 13 slits provided recurrently on the outer conductor 12
with a pitch P. When the wavelength .lambda.g transmitted in the
line as shown in FIG. 2 has the specific relation with the pitch P
and with the free space wave length .lambda.g that is given by:
##EQU1## the wave having the wavelength .lambda.g propagates along
the line; leaking out of the slit portions of its energy.
However, when the wavelength .lambda.g is under the condition
##EQU2## it propagates with a low transmission loss, because no
leaky wave occurs along the line under said condition ##EQU3##
The frequency of the wavelength .lambda.g satisfying the condition
##EQU4## is essentially higher than that of the wavelength
.lambda.g satisfying the condition ##EQU5##
In the present invention a higher frequency which satisfies the
condition ##EQU6## is used for a carrier frequency common for all
sections of the line 2 to be transmitted, partially leaking along
the open-type transmission line, and a lower frequency which is
under the condition ##EQU7## is used for an independent carrier
frequency to be transmitted with a low loss along the line.
Referring to FIG. 3, the operation of the system of FIG. 1 will be
explained in further detail. The independent signals S.sub.1,
S.sub.2, S.sub.3 . . . belong to the category (2) for the first,
second, third . . . sections respectively and are carried by
independent carrier frequencies f.sub.1, f.sub.2, f.sub.3 . . . of
the first low-carrier frequency respectively.
When these signals are sent on the transmission line 2, the
frequency selection and conversion device 30, provided at the
initial end of the first section (not necessarily at the initial
terminal) extracts the signal S.sub.1 of the frequency f.sub.1 and
converts it to the carrier of the first higher frequency F.sub.1
for coupling with the train antenna.
It is thus transmitted along the transmission line of the first
section and information S.sub.1 is sent to the train located in the
first section. In the first section, S.sub.2, S.sub.3 . . . are
transmitted with a frequencies f.sub.2, f.sub.3 . . . unchanged,
while the frequency F.sub.1 which carries S.sub.1 is present only
in the first section.
The frequency selection and conversion device (30.sub.2) provided
at the initial end of the second section, (not necessarily at the
initial end) extracts the signal S.sub.2 of the carrier of the
first lower frequency f.sub.2 and this is converted to the carrier
of the first higher frequency F.sub.1, the same as that for the
preceding section, for coupling with the train antenna. The signal
S.sub.2 is thus transmitted to the train antenna, of a train
traveling in the second section. The frequency F.sub.1 which
carries S.sub.2 is present only in the second section. Likewise,
S.sub.n is transmitted in the nth section. F.sub.3 is another
higher carrier frequency for the common information for all
sections.
FIG. 4 is a frequency spectrum which is sent from the central
station 1 to the transmission line 2 of the system of FIG. 3.
In FIG. 4, 41 denotes a group of carriers of the first lower
frequency f.sub.1, f.sub.2, f.sub.3 . . . f.sub.n conveying the
independent signals S.sub.1, S.sub.2, S.sub.3 . . . S.sub.n
respectively, 42 a group of carriers of high frequency F.sub.1 ,
F.sub.3 which are common to all sections of the line 2, F.sub.1 of
some section being of the frequency conversion of the carrier of
the first lower frequency allotted to that section.
On the other hand, the transmission of signals from trains to the
central station are also carried out in a similar way. This will be
explained with reference to FIG. 5.
A signal is transmitted by the antenna of a train in the nth
section by the carrier of the second high frequency F.sub.2 which
is common to all sections, this signal of the frequency F.sub.2
coupling with the transmission line 2 and is converted to a low
carrier of the second low frequency f'.sub.n, by the frequency
selection and converter 30n at the terminal end (not necessarily at
the terminal end) of the nth section and is transmitted to the
central station 1 with a low loss.
Likewise, the signal from the train in other sections are radiated
by the second high frequency F.sub.2 and by the train antenna,
coupled by the transmission line, converted to the respective
frequency f'.sub.2, f'.sub.3, . . . f'.sub.n 1 for that section and
sent to the central station.
The frequency selection and conversion devices 30 may be readily
constructed by those of ordinary skill in the art by conventional
components assembled in such a manner to accomplish the frequency
conversion and selection functions required. For example, it may be
composed of the following well-known devices in combination: (a) a
branching filter for selecting a designated frequency component
f.sub.n from a number intermediate frequency signals f.sub.1,
f.sub.2 . . . f.sub.n which propagate in the single open-type
transmission line, (b) a demodulator for demodulating said selected
intermediate frequency signal to a base band carried signal, (c) a
modulator for modulating a high-frequency current F.sub.1 supplied
by a generator by said base band signal, and (d) a diplexer for
sending out from an output terminal of said diplexer the addition
of signals coming from two different input terminals of said
diplexer.
Device 30 thus has the function of selecting a designated signal
from a number of intermediate frequency signals and converting said
intermediate carrier frequency signal to a very high-carrier
frequency signal, carrying the same modulation information as
carried by the intermediate carrier frequency.
As has been explained, the system of the present invention makes it
possible to transmit information independently between each
individual section and the central station without changing the
frequency for each traveling train as it travels on.
For the transmission of information common to all the sections
which belongs to the category (1), the transmission is made from
the central station at a frequency F'.sub.3 of the frequency range,
for leaky wave coupling with train antennas and, where necessary,
there are installed at suitable intervals repeater devices for the
amplification of the signal of frequency F'.sub.3.
What has been stated refers to communication between a ground
station and traveling trains. However, communication can likewise
be carried out between a ground station and another ground station.
This will be explained with reference to FIG. 6 wherein, 1 denotes
the central station, 2 open-type transmission line, 30.sub.1,
30.sub.2, 30.sub.3 . . . frequency selection and conversion
devices, 31 ground station, f".sub.2, f".sub.3 . . . carrier
frequencies for the transmission of separate information from
ground station to the central station respectively. F'.sub.1 is a
carrier frequency common to all ground stations which is converted
from any one of the separate informations allotted to each ground
station by means of a frequency selection and conversion device and
received by a ground station. F'.sub.2 is another carrier frequency
common to all ground stations which is sent out of a ground
station, coupled by the transmission line and converted to each
independent carrier frequency allotted to a ground station by means
of a frequency selection and conversion device.
F'.sub.2 converted by the frequency selection and conversion
devices to individual lower frequencies called the second lower
frequencies (f'" .sub.1, f'".sub.2, f'".sub.3 . . .) for
communication between each ground station and the central station.
Independent transmission of information between the central station
and each ground station is carried out in this way. Thus the
frequency employed by all the ground stations is made one and the
same, so that the standardization of stations is made possible. It
may be said that this is accompanied also by the advantage that a
portable telephone carried by construction and maintenance workers
for job communication and protection against danger can easily be
accommodated by a plug-in-type assembly.
A leaky coaxial line is one of the suitable transmission lines for
signal transmission employed in the system of the present
invention. However, any transmission line having a requisite
transmission capacity such as a stripline having a periodic
structure will be found to be equivalently good.
* * * * *