Method of radio telecommunication and device for implementation thereof

Method and device for radio telecommunication between a central station and a certain number of peripheral stations. In each station, a device 1 is connected to a radio transmitter-receiver 2 and comprises a keyboard 5 for introducing messages which are stored in a memory 15. A microprocessor 13 continuously tests the availability of the radio channel and automatically transmits the message as soon as the channel is free. Application to the operation of delivery or commercial-traveling network.

The present invention relates to a method of radio telecommunication in the 
simplex mode or alternate duplex mode in which messages are exchanged at 
irregular instants between central stations and a certain number of 
secondary stations. 
The invention also relates to a device for implementation of this method. 
The methods and devices of the type contemplated are more precisely 
concerned with telecommunications by radiotelephone in the alternate mode 
and are employed mainly for establishing links between fixed central 
stations and a certain number of secondary stations located a board 
vehicles. This is the case, for example, of a network of commercial 
travelers who have to transmit urgent orders for products, especially 
fresh products, or a fleet of delivery vehicles which circuit is desired 
to be checked continuously. But the invention does not in any way exclude 
fixed secondary stations. 
One of the difficulties of links of this type lies in the fact that the 
transmission channel is not always free, thus obliging the user to repeat 
his attempts, which results in a regrettable loss of time. The same 
difficulty arises if a central station which can be a management computer, 
for example, is temporarily employed for another task. 
In order to facilitate the operator's work, devices have been proposed in 
which the message to be transmitted is stored in a memory, but that does 
not alter the fundamental problem of availability of the transmission 
channel. 
Furthermore, local conditions of transmission may be poor, thus making the 
message unusable and obliging the user to repeat his transmission. 
The same difficulties evidently affect two-way transmissions. 
The object of the present invention is to provide a method and a device for 
telecommunication which free the user from any tedious need for waiting 
and repetition. 
In the method contemplated by the invention, messages are exchanged at 
irregular instants between central stations and a certain number of 
secondary stations by storing in memory the message to be transmitted. 
In accordance with the invention, this method is characterized in that 
availability of the radio channel is tested automatically and continuously 
and that the message is transmitted automatically when the channel is 
free. 
Once the message has been introduced in memory, the user no longer needs to 
attend to his transmission. This latter takes place automatically as soon 
as the channel is subsequently free. As a function of the capacity of the 
memory, the user can even introduce a certain number of messages which 
will in some cases be checked on. 
In a preferred embodiment of the method, the validity of the message 
received is checked and transmission of the message is repeated 
automatically if the reception is not correct. 
Neither does the user need to worry about local or atmospheric conditions 
of transmission or to check the transmission while waiting for an 
acknowledgement of reception. 
Preferably, the message received is stored in memory until the final 
receiver stage is made available. 
For example, if this receiver is a large management computer occupied on a 
time-sharing basis, no waiting period is imposed. 
In an avantageous embodiment of the method, there is added to the message 
at the instant of transmission a data item representing the time which has 
elapsed since the instant of introduction of the message. 
As a complementary feature, up to the instant of reception by the final 
receiver stage, the data item representing the time which has elapsed 
since the instant of introduction of the message is updated. 
Although the transmission in fact takes place in deferred time, a 
reconstitution of the real time is readily obtained. 
In an improved embodiment of the method, after having recognized 
availability of the channel, transmission is retarded by a predetermined 
time interval corresponding to a transmission-priority hierarchy. 
In accordance with a second aspect of the invention, the device for radio 
telecommunication in simplex mode or alternate duplex mode between central 
stations and a certain number of secondary stations for applying the 
method aforesaid is provided on each of said stations and comprises a 
connector for establishing a connection with a radio transmitter-receiver, 
a connector for establishing a connection with a microphone-loudspeaker 
assembly provided with controls for calling and alternate transmission, 
means for introducing a message to be transmitted, a transmission memory 
for storing this message, and means for signaling a message received. It 
is characterized in that it comprises a computation unit connected to the 
transmitter-receiver and to said memory for continuously testing the 
availability of the radio channel and for initiating transmission of the 
message only if the channel is free. 
The device advantageously comprises a reception memory connected to the 
receiver and to the signaling means for storing the messages received as 
well as a clock pulse counter for measuring the time of residence of each 
message in memory. 
In a preferred embodiment of the device, the means for introducing a 
message comprise a manual keyboard and/or an analog-to-digital converter 
coupled to a lead for connecting to a measuring probe, thus making it 
possible to transmit data without human intervention. 
The means for signalling a message received comprise a visual display unit 
which can advantageously be duplicated by a voice synthesizer connected to 
the loudspeaker. 
Other particular features and advantages of the invention will also be 
brought out by the following detailed description.

With reference to FIGS. 1 to 3, the device 1 in accordance with the 
invention is inserted between a transmitter-receiver stage 2 and a 
microphone-loudspeaker assembly 3. 
The device proper is contained in a casing 4 (FIG. 2) on the front face of 
which is shown a keyboard 5 of the telephone type, warning indicator lamps 
6 and a sound signal element 7. Socket outlets 8, 9 are provided on the 
rear side (FIG. 3) for the purpose of connecting respectively to the 
transmitter-receiver and to the microphone-loudspeaker assembly. 
The apparatus is also provided on the front face with an alphanumeric 
luminous display device 11 and on the side with a connector 12, the 
function of which will be described hereinafter. 
Referring more precisely to FIG. 1, the device 1 comprises a microprocessor 
13 containing a PROM program memory and connected on one hand to a data 
introduction stage 14 and on the other hand to a transmission memory 15. 
The data-introduction stage 14 includes the keyboard 5 and an 
analog-to-digital converter 10 which is connected to the connector 12 for 
establishing a connection with an external measuring probe. 
The memory 15 is connected to the transmitter 2a through a 
modulator-demodulator (MODEM) 16 and through the socket outlet 8 via a 
line 17 for information transmitted at low frequency (INFEBF). 
Similarly, a reception memory 18 is connected to the receiver 2b through 
the MODEM 16 via a line 18 for information received at low frequency 
(INFEBF). This memory is also connected to a stage 19 for indicating 
messages received via the microprocessor 13. 
In addition to the display device 11, the stage 19 comprises a voice 
synthesizer 21, the output of which is connected via a line BFHP to the 
loudspeaker HP which forms part of the assembly 3. 
This assembly 3 comprises a microphone M from which extends a low-frequency 
transmission line BFE. This line returns to the line 17 which terminates 
at the transmitter 2a via the socket outlet 9, via a control unit CTR and 
a multiwire cable 22 so as to return to the low-frequency information line 
17. 
The assembly 3 further comprises a control unit 23 from which extend call 
connections AP and alternate transmission connections AL which terminate 
via the same channel at the transmitter 2a. 
The control unit CTR which is in a mutually dependent relationship with the 
microprocessor 13 receives via a multiwire cable 24 service data derived 
from the receiver 2b, namely a received-code data item 25, a free-channel 
data item 26 and a data item 27 indicating the presence of a low-frequency 
message which is intended for the loudspeaker. 
The microprocessor 13 further comprises a counter K which counts the pulses 
of a clock H and is connected to the transmission memory 15 by means of a 
dating connection D. 
Assuming that the device which has been described is installed on a 
secondary station, the user enters a message by means of the keyboard 5 
and, via the microprocessor 13, this message is stored in the transmission 
memory 15 and dated. As soon as the free-channel information 26 is 
transmitted to the microprocessor by means of the control unit CTR, the 
contents of the memory are transmitted via the line 17 and the transmitter 
2a with the addition of an item of information representing the time of 
residence in the memory 15; this item of information corresponds to the 
contents of the counter K. 
In another mode of operation, analog data derived from a measuring probe 
connected to the connector 12 are digitized in the converter 10 and 
transmitted on receipt of an order from the microprocessor after a 
possible waiting period in memory. 
At each instant, the user may communicate by radio by means of the calling 
and alternate transmission control unit 23. 
The items of information transmitted by a central station are visualized on 
the display device 11 or communicated by voice by means of the loudspeaker 
HP via the synthesizer 21. 
In the event that the device is installed in a central station, it is 
practically not modified except for certain details of programming of the 
microprocessor. The signal stage 19 is in that case connected to a final 
receiver stage which may be occupied at the moment of a transmission, with 
the result that the reception memory 18 plays an important part. When the 
message is finally transmitted to this stage, the time of residence in the 
memory 18 is added to the time of residence in the transmission memory of 
the secondary station which has sent the message. 
The operating sequences will now be described in greater detail with 
reference to FIGS. 4 to 14 in order to give a more complete description of 
the method and to explain the programming of the microprocessor. 
Consideration is given to the two modes of operation which are possible 
according to the station which takes the initiative of transmission: 
A. From a secondary station 
The operations relating to the secondary station are summarized in FIG. 4. 
The initial operation is the entry of a message which normally takes place 
by way of programmed questions to which the user replies. Once the message 
has been entered, it is stored in memory and dated in accordance with the 
sub-sequences which will be described below in detail. 
If there are other messages to be introduced in accordance with the same 
cycle of questions-answers, one returns to the beginning or, if not, one 
endeavors to transmit whenever the radio channel is free. As long as the 
channel is not free, one returns in order to carry out updating. 
Transmission takes place in accordance with a procedure which will be 
described below in detail. In the event of faulty transmission, one 
returns to the dating operation. 
After transmission, the message is erased from the memory and one may 
change if necessary to another type of message to which a different 
question-answer procedure is applicable. 
The corresponding operation of a central station (FIG. 5) consists in 
identifying its call code, in demodulating the message and in storing it 
in memory as soon as the transmission is found to be correct. Updating is 
carried out by adding the time of residence in the reception memory and, 
as soon as the final receiver computer is available, the message is 
transferred thereto and the memory is erased. 
If the computer is not available, one returns to the dating operation 
unless another message appears for the purpose of being demodulated and 
stored in memory. 
B. From a central station 
A message entered manually or automatically at a central station (FIG. 6) 
is first stored in memory, then transmitted as soon as the channel is 
free. After checking for correct transmission, the memory is reset to 
zero. 
In correspondence (FIG. 7), the secondary station identifies its call code 
and demodulates the message which is stored in memory only after checking 
for correct transmission. 
The message is then indicated on the display device 11. 
Normally, no provision is made in this case for dating since the real time 
of the instructions transmitted by a central station is a priori of no 
interest. 
C. Sub-sequences. 
The initial operation (FIG. 8) described here with reference to the 
secondary station consists in putting the apparatus into service, which 
initiates scanning of the keyboard. The user must then introduce his 
personal key. If this is not done, the apparatus will be limited to 
transmission of the message (or the messages) which may have remained 
stored in the transmission memory. 
The user then enters a code which defines a cycle of questions-answers. 
The introduction of the code is shown in detail in FIG. 9. If the code is 
erroneous, after three attempts, a break-in message is transmitted. 
Once the code has been identified, the questions are displayed successively 
and the user answers them by introduction of the data. An interruption of 
20 seconds in the key entry of data puts the apparatus in the transmission 
state and the data are cancelled. 
The introduction of data is represented in detail in FIG. 10. The 
key-entered data are displayed and checked in their format. They have to 
be validated by depressing a push-button. They are then stored in memory 
and one passes to the next question. Pressure exerted on a "cancellation" 
button makes it possible to change to a different cycle of 
questions-answers materialized by another code to be introduced. 
The storage operation is shown in detail in FIG. 11. This operation 
includes a dating operation which starts up a time-counting operation 
relating to the message which has just been introduced and which updates 
the messages stored previously and not yet transmitted (FIG. 12). This 
general updating takes place not only at the time of storage of a new 
message but also at each transmission. 
Each stored message contains: 
its code; 
the question (or the questions); 
the data; 
the dating operation; 
identification of the station; 
the length of the message. 
The user is informed of the state of filling of the memory. When this 
latter is full, the device necessarily changes over to transmission. 
There will now be described in detail, with reference to FIGS. 13 and 14, 
the sequence of operations of transmission from a secondary station and 
the sequence of operations of reception by the same secondary station. 
Before each transmission, one waits for a certain time .theta. which is 
different for each secondary station in order to define a scale of 
priority between these stations. Final updating is then performed in 
regard to the message awaiting time at the secondary station. 
After modulation and transmission, the central station repeats the message. 
If this return is correct, one sends an agreement to validate the message 
at the level of the final receiver. If this agreement itself is correct, 
the message is erased from the transmission memory and one proceeds to the 
next message. The set of data in memory is in fact divisible and it is 
preferable to transmit by fraction by reason of the random character of 
radio transmission incidents. 
At the end of transmission, one reverts to the code introduction position. 
The reception of a message by the secondary station (FIG. 14) first 
consists of identification of the personal code of this station, then 
identification of the nature of the message (digital or phonic). The 
digital message is demodulated and stored in the reception memory. Its 
arrival is announced by a sound signal. 
The user then requests display by actuating the keyboard. If an answer is 
compulsory, one changes to the data introduction position. If not, the 
message remains displayed until the cancellation button is actuated. 
By way of example of utilization of the invention, mention can be made of 
the operation of a concrete mixing plant. Movements of trucks are frequent 
and incidents may be numerous. The various changes of state are 
communicated manually by the driver or automatically by analog probes (for 
example the gasoline consumption of the truck). The plant is thus in a 
position to determine at each instant the state of each vehicle and the 
progress of each construction site. The plant can accordingly optimize its 
production and accelerate billing. And these advantages are obtained with 
a minimum loss of time for the deliveryman. In this example of 
application, the presence of the voice synthesizer at the secondary 
station is very useful. 
Another example is that of the distribution of fresh products in which 
speed of transmission from a network of commercial travelers is of primary 
importance. Aside from the orders transmitted by the secondary station, 
the central station can rapidly deliver messages such as beginnings or 
ends of sales promotion campaigns or a stock failure. Furthermore, by 
virtue of the digitization process, discretion is ensured. 
One can also mention the example of management of a network of taxicabs. 
As can readily be understood, the invention is not limited to the examples 
described but covers any alternative form within the scope of anyone 
versed in the art. 
Thus the converter 10 could provide for two-way information transfer, for 
example in order to exert an analog control on an external element. It 
could also be designed to perform the function of a transparent interface 
for receiving via the socket outlet 12 "series" items of information which 
are already in digital form.