FR3119039A1 - METER READING BY A COMMUNICATION SYSTEM - Google Patents

Abstract

A communication system comprises at least one meter and a display device communicating by exchanging frames conforming to a wireless communication standard to allow automated and remote reading of metering information. The display device performs pairing (S18) with each counter, comprising sending a first time-setting and synchronization frame indicating a time of first awakening of the counter in question. The display device wakes up before the first wake-up time in question and waits (S26) for an index frame comprising counting information from the counter in question. The display device sends (S28) a second time-setting and synchronization frame indicating a next wake-up time. The display device receives (S34) an acknowledgment indicating that said second frame has been received and goes to sleep (S58) until a time prior to said next wake-up time. Fig. 2

Description

METER READING BY A COMMUNICATION SYSTEM

At least one embodiment relates to a meter reading method performed by a communication system configured to enable automated and remote reading of meter count information.

STATE OF THE PRIOR ART

Fluid meters are known, of the gas, thermal energy or water type, which comprise display means of the LCD screen (Liquid Crystal Display) type allowing a user to view different information such as current consumption, for example. They are generally equipped with a push button that allows the user to select the information he wishes to view.

Such counters have several drawbacks. In particular, they are sometimes difficult to access for a user wishing to read information concerning current consumption. In addition, they are sensitive to external humidity. However, to obtain the counting index of such a counter, it must currently be provided with a push button which, when pressed, triggers a display on an LCD screen of the counting index. . Indeed, such meters are not electrically powered by the mains and must therefore include an independent source of energy, such as a battery or a cell, and limit its energy consumption to what is strictly necessary. The LCD screen display is thus put on standby as long as the push button is not pressed. However, the existence of such a push button poses problems of sealing against external humidity.

It is desirable to overcome these various drawbacks of the state of the art. It is particularly desirable to provide a display device which allows easy access to consumption information while being impermeable to external humidity.

The method described allows easy reading of counter counting information by centralizing said information on the display device. In addition, it makes it possible to reduce the problems of sealing of the meters which no longer need to be equipped with a push button to scroll the metering information.

More specifically, there is proposed a method for reading a meter executed in a communication system configured to allow automated and remote reading of meter counting information, said communication system comprising at least one meter and a device for display communicating by exchanging frames conforming to a wireless communication standard, where the method comprises for the display device: pairing with said at least one counter, said pairing comprising sending a first update frame on time and in synchronization with said at least one counter, said first frame comprising information representative of a current time enabling said counter to be timed and information representative of a time of first awakening of said at least one counter ; waking up before the first wake-up time; a) receiving an index frame comprising counting information from said at least one counter; b) sending a second time-setting and synchronization frame to said at least one counter, said second frame comprising information representative of a new current time and information representative of a next wake-up time of said at least one counter ; c) receiving an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said second frame; then go to sleep until a time before said next wake-up time.

According to a particular embodiment, said communication system comprising a plurality of counters paired with said display device, the method comprises, before going into standby, repeating a), b) and c) for each paired counter, said information of a next wake-up time being different for each paired meter.

According to a particular embodiment, pairing with said at least one counter comprises: receiving a signal indicating said display device to pair; receiving a signaling frame sent in broadcast mode by said at least one counter; sending a frame indicating successful pairing to said at least one counter; sending said first time-setting and synchronization frame to said at least one counter; receiving an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said first frame.

According to a particular embodiment, said signal indicating said display device to pair is generated by pressing a button of said display device or by an infrared connector.

According to a particular embodiment, the method comprises, before sending the frame indicating successful pairing: sending a request for an encryption key associated with said at least one meter to a management entity of said automated and remote statement d counter count information; receiving said encryption key associated with said at least one counter; using said encryption key to encrypt and decrypt the frames exchanged between said display device and said at least one counter.

According to a particular embodiment, said frames exchanged between said display device and said at least one counter comply with one of the communication standards among WM-Bus, ZigBee and Bluetooth Low Energy.

There is also proposed a method for reading a meter executed in an automated metering management system in the context of a fluid distribution service, comprising at least one meter and a display device communicating by exchange of conforming frames to a wireless communication standard, where the method comprises for said at least one counter: pairing with said display device, said pairing comprising receiving a first time-setting and synchronization frame transmitted by said display device, said first frame comprising information representative of a current time and information representative of a time of first awakening of said at least one counter; wake up at the first wake-up time; sending to said display device an index frame comprising counting information; receiving a second time-setting and synchronization frame transmitted by said display device, said second frame comprising information representative of a new current time and information representative of a time of next awakening of said at least one counter ; set the time from the new current time; sending an acknowledgment frame to said display device, said frame indicating that said at least one counter has received said second frame; go to sleep until said next wake-up time.

According to a particular embodiment, pairing with said display device comprises: sending a signaling frame in broadcast mode and opening a listening window; receiving a frame indicating successful pairing to said at least one counter; receiving said first time-setting and synchronization frame from said at least one counter; set the time from the current time of said first frame; sending an acknowledgment frame to said display device, said frame indicating that said at least one counter has received said first frame.

A computer program product is also proposed comprising instructions for implementing, by a processor, one or other of the processes as mentioned above, according to one or other of their modes. realization, when said program is executed by said processor. There is also proposed an information storage medium storing a computer program comprising instructions for implementing, by a processor, one or the other of the methods as mentioned above, according to one or the other of their embodiments, when said program is executed by said processor.

There is also proposed a display device in a communication system configured to allow automated and remote reading of meter counting information, said communication system further comprising at least one meter communicating with said display device by exchange of frames conforming to a wireless communication standard. The display device is configured to: pair with said at least one counter, said pairing comprising sending a first time-setting and synchronization frame to said at least one counter, said first frame comprising information representative of a current time allowing said counter to be timed and information representative of a time of first awakening of said at least one counter; waking up before the first wake-up time; a) receiving an index frame comprising counting information from said at least one counter; b) sending a second time-setting and synchronization frame to said at least one counter, said second frame comprising information representative of a new current time and information representative of a next wake-up time of said at least one counter ; c) receiving an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said second frame; go to sleep until a time before said next wake-up time.

There is also proposed a meter in a communication system configured to allow automated and remote reading of meter counting information, said communication system further comprising a display device communicating with said meter by exchange of frames in accordance with a wireless communication standard. Said counter is configured to: pair with said display device, said pairing comprising the reception of a first time-setting and synchronization frame transmitted by said display device, said first frame comprising information representative of a current time and information representative of a time of first awakening of said counter; wake up at the first wake-up time; sending to said display device an index frame comprising counting information; receiving a second time-setting and synchronization frame transmitted by said display device, said second frame comprising information representative of a new current time and information representative of a time of next awakening of said counter; set the time from the new current time; sending an acknowledgment frame to said display device, said frame indicating that said counter received said second frame; go to sleep until said next wake-up time.

There is also proposed a communication system configured to allow automated and remote reading of meter counting information, said communication system comprising at least one meter and a display device, as mentioned above, communicating by exchanging frames conforming to a wireless communication standard.

The characteristics of the invention mentioned above, as well as others, will appear more clearly on reading the following description of an exemplary embodiment, said description being made in relation to the attached drawings, among which:

illustrates a communication system configured to allow automated and remote reading of meter count information according to one embodiment;

schematically illustrates a method for reading counting information according to a particular embodiment;

schematically illustrates a metering information statement method according to a particular embodiment;

schematically illustrates an example of hardware architecture of a display device according to a particular embodiment; And,

schematically illustrates an example of hardware architecture of a counter according to a particular embodiment.

DETAILED DESCRIPTION OF EMBODIMENTS

Fig. 1 illustrates a communication system configured to allow automated and remote reading of meter count information, e.g. a consumption index, in which the present invention is implemented.

The communication system includes a plurality of counters. On the , three counters C1, C2 and C3 are represented. For example, C1 is a water meter, C2 is a gas meter and C3 is a thermal energy meter. The counters C1, C2, C3 are connected to a display device A by a communication link L1.

The communication link L1 is a wireless communication link, for example based on the WM-Bus communication standard (NF EN 13757-4, "Communication systems for meters and remote reading of meters - Part 4: Wireless meter readout ( Radio meter reading for operation in SRD bands)” in Anglo-Saxon terminology). The WM-Bus standard is a wireless communication standard offering an excellent compromise between small antenna size and high range indoors and outdoors (up to 1 km without repeaters). In the embodiments described later with reference to Figs. 2 and 3, all exchanges between the display device A and the counters C1 to C3 use frames conforming to the WM-Bus standard for the physical layer (“PHY layer” in English) and the data link layer (“Data link layer” in English). However, in variant embodiments, the communication link L1 is based on another communication technology, such as another communication standard, such as for example BLE (acronym for “Bluetooth Low Energy”) or ZigBee.

The display device A is provided with a selection button B and a screen E, e.g. an LCD type screen. The selection button B allows for example a user to scroll through the consumption indexes provided by the various meters, the indexes being displayed on the screen E. In a variant embodiment, the selection button B is replaced by a connector infrared. For example, this infrared connector is configured to connect a probe that complies with the IEC 62056-21 standard, also known as a FLAG probe. Such a probe makes it possible to connect an installation and maintenance terminal communicating by infrared signals via said probe. Advantageously, the display device A is placed in a place easily accessible to a user.

Each counter is therefore configured to transmit counting information to the display device A. Once collected by the display device A, the counting information is fed back to a management entity SI to which the display device is connected via an L2 communication link. The communication link L2 is preferably a wireless communication link, for example of the LoRa (acronym for “ Long Range ”) or NB-IoT (acronym for “ NarrowBand IoT ”) type.

As soon as it is put into service, the display device A communicates with the management entity SI which regularly sends it synchronization information, e.g. in the form of hours: minutes: seconds, so that the display device A synchronizes with the IS management entity by setting the time.

The display device A appears as a virtual counter vis-à-vis the management entity SI. The latter is in particular in charge of centrally processing meter readings, e.g. for monitoring consumption. For this purpose, the IS management entity generally comprises a server, or a set of servers. Optionally, the management entity SI stores in memory for each counter of the communication system an encryption key in association with an index identifying said counter, said key being used to encrypt data exchanged with the counter with which it is associated.

There schematically illustrates a method for reading counting information according to a particular embodiment. In the example of the , the fluid meters C1 and C2 are assumed to be already paired with the display device A, a pairing having taken place during a prior phase S18. Pairing is a known operation in the world of communicating electronic devices for establishing an initial connection between these electronic devices to enable reliable communications to be established between them. Pairing is a routine operation to allow a portable device to be connected by Wi-Fi to an access point, or to a Bluetooth-compatible wireless speaker to receive an audio stream transmitted by a player that is also Bluetooth-compatible. Pairing allows fluid meters C1 and C2 to be known and recognized by display device A, and to be synchronized with display device A.

Moreover, in the example of the , the counters C1 and C2 and the display device A are in standby mode.

We take the example of the exchanges between the counters C1 and C2 and the display device A. The operation of the exchanges between the counter C3 and the display device A is identical. In the embodiment of the , counters C1 and C2 are bidirectional, ie they can send and receive frames.

In the following, we call "upstream WM-Bus frames" the WM-Bus frames going in the counter direction towards the display device, and "downstream WM-Bus frames" the WM-Bus frames going in the direction from the display device towards counter.

Since the meters C1 and C2 are paired with the display device A, a consumption index transmission phase can begin. The consumption index reading is an iterative process which is repeated at regular intervals, eg every 5 minutes. In the following, j is an index identifying an iteration.

At a time T0[j]-δT, during a step S20, the display device A wakes up. For example, δT= 1s. The waking up of display device A has been programmed so as to be earlier than a waking up of counter C1, in order to take account of possible clock slips which may occur between an internal clock of counter C1 and an internal clock of display device A. The communication round trip times between the counter C1 and the display device A are typically negligible, but this can be taken into account to define with what time margin the display device A must wake up before counter C1. The awakening of the display device A is preferentially earlier by at least 1 second than the awakening of the counter in question (here the counter C1).

At a time T0[j], during a step S22, the counter C1 wakes up.

During a step S24, the counter C1 recovers its consumption index and sends an uplink WM-Bus consumption index transmission frame including it. In the context of uplink WM-Bus frames, an application layer (e.g. proprietary application layer) defines the following command bytes and associated payloads (note that each command byte takes the form of a hexadecimal value):

- “0x00” meaning “reserved” associated with an empty payload;

- “0x01” meaning “reserved” associated with an empty payload;

- "0x02" meaning "transmission of an index value" associated with a payload comprising four bytes of consumption index value (the value of the consumption index indicated by the counter C1 is called Idx_C1);

- “0x03” to “0xFF” being reserved for future use.

During a step S26, the display device A receives the uplink WM-Bus consumption index transmission frame and stores the value of the consumption index Idx_C1 relating to the meter C1. Thus, he can thus display the stored value on the screen E at the request of a user. It can also retransmit the consumption index to the SI manager entity.

During a step S28, the display device A sends a downlink WM-Bus time-setting and synchronization frame. The display device A is itself regularly timed by the management entity SI.

As part of downlink WM-Bus frames, the application layer (e.g. proprietary application layer) defines the following command bytes and associated payloads (note that each command byte takes the form of a hexadecimal value):

- “0x00” meaning “reserved” associated with an empty payload;

- “0x01” meaning “time setting and synchronization” associated with a payload of six bytes. The first byte (respectively the second, the third) representing a value of hours (respectively minutes, seconds) for a time setting and the fourth byte (respectively the fifth, the sixth) representing an instant of next wake-up , for example also in the form of a value of hours (respectively minutes, seconds). In one embodiment, the value T0[j+1] sent in the frame is equal to the value of T0[j], i.e. the wake-up time of step S22, to which is added a time increment, e.g. 5 minutes ;

- “0x02” to “0xFF” being reserved for future use.

During a step S30, the counter C1 receives the downlink WM-Bus time-setting and synchronization frame. It sets the time using the data (hours, minutes, seconds) contained in the first three bytes of the downlink WM-Bus frame received.

It memorizes the time T0[j+1] of its next awakening from the data (hours, minutes, seconds) contained in the last three bytes of the downlink WM-Bus frame received.

In general, fluid meters implemented in the field have accurate internal clocks. Typically, any clock slips over a 5 minute period are much less than 1 second.

During a step S32, the counter C1 sends an uplink WM-Bus acknowledgment frame to the display device to acknowledge the reception of the time setting and synchronization frame. The uplink WM-Bus acknowledgment frame corresponds to a frame conforming to the WM-Bus standard comprising an ACK symbol as defined in table 25 of the standard.

During a step S34, the display device receives the uplink WM-Bus acknowledgment frame.

During a step S36, the counter C1 goes into standby. Note that step S36 can take place before, after or at the same time as step S34. Counter C1 will then wake up at the recorded time T0[j+1]. Since display device A is supposed to be woken up before counter C1, a new iteration of steps S24 to S34 then takes place.

In the particular case where display device A is connected to counter C1 alone, display device A in turn goes into standby. In the case where display device A is connected to a plurality of other counters Ck, steps S22 to S36 are repeated for each of the other counters from an hour T0[j]+∆t', eg ∆ t'=(k-1)*∆t. For example, ∆t is equal to 4 seconds. Thus, the next wake-up time indicated in a downlink WM-Bus frame for setting the time and synchronization for the same reading iteration j is different, ie shifted in time, from one counter to another counter. In other words, the value of ∆t' is different for each counter.

On the , the display device A is connected to the counter C2. Steps S22 to S36 therefore apply with counter C2, but in a time-shifted manner.

Thus, at a time T0[j]+∆t, during a step S42, the counter C2 wakes up.

During a step S44, the counter C2 recovers its consumption index and sends an uplink WM-Bus consumption index transmission frame including it (the value of the consumption index indicated by the counter C2 is called Idx_C2 ).

During a step S46, the display device A receives the uplink WM-Bus consumption index transmission frame and stores the value Idx_C2 of the consumption index relating to the meter C2. Thus, it can display the stored value on the screen E at the request of a user. It can also retransmit the consumption index to the SI management entity.

During a step S48, the display device A sends a downlink WM-Bus frame for setting the time and synchronization which comprises the current time and a value T0[j+1]+∆t of instant of next awakening.

During a step S50, the counter C2 receives the downlink WM-Bus time-setting and synchronization frame. It sets the time using the data (hours, minutes, seconds) contained in the first three bytes of the downlink WM-Bus frame received. In addition, it memorizes the time T0[j+1]+∆t to determine its next awakening from the data (hours, minutes, seconds) contained in the last three bytes of the downlink WM-Bus frame received.

During a step S52, the counter C2 sends an uplink WM-Bus acknowledgment frame to the display device A to acknowledge receipt of the downlink WM-Bus time-setting and synchronization frame.

During a step S54, the display device receives the uplink WM-Bus acknowledgment frame.

During a step S56, the counter C2 goes into standby. Note that step S56 may take place before, after or at the same time as step S54. Counter C2 will then wake up at the recorded time T0[j+1]+∆t. Since display device A is supposed to be woken up before counter C2 wakes up, a new iteration of steps S44 to S54 then takes place.

In the particular case where the display device A is connected only to the counters C1 and C2, the display device A in turn goes into standby during a step S58 until a time prior to the time of next awakening of counter C1 or counter C2 (whichever expires first), for example 1 second before. In the particular case where display device A is also connected to counter C3, steps S42 to S56 therefore apply with counter C3, but in a time-shifted manner. Thus counter C3 wakes up at T0[j]+∆t’. For example, ∆t'=2*∆t.

Display device A goes into standby when it has retrieved or attempted to retrieve the consumption indexes of all the meters to which it is paired. In the event that display device A failed to collect a consumption index for a meter, eg because the index frame was lost, it will attempt to collect the consumption index again when a next iteration. After n consecutive failures, eg n =3, the display device A considers that the meter is no longer paired and tries to pair it again. As a variant, the display device A considers that the counter is faulty and that the counter in question must be changed. To this end, he can display a message on his screen E to indicate this.

There schematically illustrates a method for reading counting or index information according to a particular embodiment. In the example of the , the fluid meter C3 and the display device A are not paired. Prior to the first consumption index reading step, a pairing phase (as already disclosed in step S18) is implemented. This pairing phase is implemented in particular during the installation of a new meter or in the event of replacement of the display device A following, for example, a breakdown.

In the example of the , meter C3 is a water meter newly installed by an installer.

As soon as it detects a consumption (for example a circulation of water in the circuit), the counter C3 wakes up and sends during a step S304 at least one rising WM-Bus signaling frame, called “Hello” frame, in broadcast mode, and opens a listening window of duration ∆t, e.g. 5 seconds, in order to wait for confirmation of successful pairing. The uplink WM-Bus “Hello” frame identifies the counter C3 which transmits it and includes an SND-IR symbol as defined in table 24 of the standard. In practice, the counter C3 transmits in broadcast mode at regular intervals, e.g. every 5 minutes, a rising WM-Bus frame "Hello", opens a listening window of duration ∆t and goes into standby. The counter C3 proceeds in this way until it receives a response.

At least one of these frames is received by the display device A during a step S306.

In step S306, display device A receives a signal telling it to pair. For example, a user such as an installer presses button B on display device A for a predefined time, e.g. 2 seconds, in order to generate a signal telling display device A to initiate the pairing procedure. Pressing button B causes display device A to take into account the uplink WM-Bus “Hello” frames sent by meter C3 for pairing. In other words, the reception of a "Hello" frame after pressing button B causes pairing of the counter C3 with the display device A. Alternatively, pressing button B is replaced by reception of a infrared signal on the infrared connector already mentioned.

During an optional step S308, the display device A sends to the management entity SI a request for an encryption key for the counter C3 as identified in the “Hello” frame received from the counter C3. The request includes an index identifying the counter C3.

During an optional step S310, the management entity SI receives the encryption key request for the counter C3.

During an optional step S312, the management entity SI sends the display device A the encryption key for the counter C3 in response to the request received at step S310.

During an optional step S314, the display device receives the encryption key for the counter C3. This encryption key is then used to encrypt all the WM-Bus frames exchanged between display device A and meter C3.

During a step S316, the display device A sends a downlink WM-Bus frame of successful pairing to the counter C3. The successful pairing downlink WM-Bus frame includes a CNF-IR symbol as defined in table 25 of the standard.

During a step S318, the successful pairing downlink WM-Bus frame is received by the counter C3.

During a step S320, the display device sends a downlink WM-Bus frame for setting the time and synchronization which includes the current time and a value of a next wake-up instant, e.g. T0[j]+ ∆t', with ∆t'=2*∆t.

During a step S322, the counter C3 receives the downlink WM-Bus time-setting and synchronization frame. It sets the time using the data (hours, minutes, seconds) contained in the first three bytes of the downlink WM-Bus frame received.

It memorizes the time T0[j]+∆t' to determine its next awakening from the data (hours, minutes, seconds) contained in the last three bytes of the downlink WM-Bus frame received.

During a step S324, the counter C3 sends an uplink WM-Bus acknowledgment frame to the display device A to acknowledge receipt of the time setting and synchronization frame.

During a step S326, the display device A receives the uplink WM-Bus acknowledgment frame.

During a step S328, the counter C3 goes into standby. Counter C3 will wake up at T0[j]+∆t’. Note that step S328 can take place before, after or at the same time as step S326.

During a step S330, the display device in turn goes into standby.

In a particular embodiment, a counter which has not been reset for a certain time T1, e.g. T1 equal to 1 hour, sends at regular intervals (for example, every 5 minutes), a frame WM -Bus up "Hello", opens a listening window of duration ∆t and goes back to sleep. This scenario can occur in the event of a breakdown of the display device, or when the display device is changed.

During a first commissioning of a display device following a breakdown, a pairing is carried out as illustrated by the with meters that are already in service. In order to be able to pair all the counters previously paired with the display device that has broken down and not just the counters that have not been reset for a certain time T1 (only counters that then emit WM- uplink buses "Hello"), a longer press than in step S306 (eg at least 10 seconds instead of 2 seconds) is performed on button B and the display device remains awake for 10 minutes so to be able to pair all the meters. As a variant, pressing button B is replaced by reception of an infrared signal on the infrared connector already mentioned. This infrared signal is then different from the alternatively disclosed infrared signal of step S306.

There schematically illustrates an example of hardware architecture of a display device 140 according to a particular embodiment. According to the hardware architecture example shown in , the display device 140 then comprises, connected by a communication bus 1400: a processor or CPU (Central Processing Unit) 1401; a random access memory RAM (Random Access Memory) 1402; a read-only memory ROM 1403; a storage unit 1404 such as a hard disk or such as a storage medium reader, eg an SD (“Secure Digital” in English) card reader; at least a first communication interface 1405 allowing the display device 140 to send or receive information from the management entity SI and a second communication interface 1406 allowing the display device 140 to send or receive counter information.

For example, the first 1405 communication interface complies with the LoRa or NB-IoT standard. The second interface is for example compliant with the WM-Bus, ZigBee or BLE standard. The display device 140 is provided with the selection button B and the screen E (e.g. an LCD type screen) already mentioned. Alternatively, as already mentioned, an infrared connector replaces the button B. The display device 140 is powered by battery or battery.

Processor 1401 is capable of executing instructions loaded into RAM 1402 from ROM 1403, external memory (not shown), storage media (such as an SD card), or a communications network. When display device 140 is powered up, processor 1401 is able to read instructions from RAM 1402 and execute them. These instructions form a computer program causing the implementation, by the processor 1401, of all or part of the methods described in relation to Figs. 2 to 3.

The methods described in relation to Figs. 2 to 3 can be implemented in software form by execution of a set of instructions by a programmable machine, for example a DSP ("Digital Signal Processor" in English) or a microcontroller, or be implemented in hardware form by a machine or a dedicated component, for example an FPGA (Field-Programmable Gate Array) or an ASIC (Application-Specific Integrated Circuit). In general, display device 140 includes electronic circuitry configured to implement the methods described in connection with Figs. 2 to 3.

There schematically illustrates an example of hardware architecture of a counter 150 according to a particular embodiment. According to the hardware architecture example shown in , the counter 150 then comprises, connected by a communication bus 1500: a processor or CPU (Central Processing Unit) 1501; a random access memory RAM (Random Access Memory) 1502; a read-only memory ROM 1503; a storage unit 1504 such as a hard disk or such as a storage medium reader, eg an SD (“Secure Digital” in English) card reader; at least one communication interface 1505 allowing counter 150 to send or receive information from display device 140.

For example, the 1505 communication interface complies with the WM-Bus, ZigBee or BLE standard. The meter 150 is powered by cell or battery.

Processor 1501 is capable of executing instructions loaded into RAM 1502 from ROM 1503, external memory (not shown), storage media (such as an SD card), or a communications network. When counter 150 is powered up, processor 1501 is able to read instructions from RAM 1502 and execute them. These instructions form a computer program causing the implementation, by the processor 1501, of all or part of the methods described in relation to Figs. 2 to 3.

The methods described in relation to Figs. 2 to 3 can be implemented in software form by execution of a set of instructions by a programmable machine, for example a DSP ("Digital Signal Processor" in English) or a microcontroller, or be implemented in hardware form by a machine or a dedicated component, for example an FPGA (Field-Programmable Gate Array) or an ASIC (Application-Specific Integrated Circuit). Generally, meter 150 includes electronic circuitry configured to implement the methods described in connection with Figs. 2 to 3.

Thus, thanks to the methods and arrangements disclosed above, the display device A is capable of concentrating the display of metering index readings relating to different meters, for example carrying out different metering operations (water, gas, etc.). ). This makes it possible in particular to concentrate the display of these counts for a dwelling in the same place, typically inside the dwelling, in an accessible place and protected from humidity. The meters themselves do not have to have a push button, which avoids problems of sealing against external humidity.

Claims (13)

A method for reading a meter executed in a communication system configured to allow automated and remote reading of meter counting information, said communication system comprising at least one meter and a display device communicating by exchange of frames conforming to a wireless communication standard, characterized in that the method comprises for the display device:
- pairing (S18) with said at least one counter, said pairing comprising sending a first time-setting and synchronization frame to said at least one counter, said first frame comprising information representative of a time current allowing the time of said counter to be set and information representative of a time of first awakening of said at least one counter;
- waking up (S20) before the first wake-up time;
a) receiving (S26) an index frame comprising counting information from said at least one counter;
b) sending (S28) a second time-setting and synchronization frame to said at least one counter, said second frame comprising information representative of a new current time and information representative of a next wake-up time of said at least minus one counter;
c) receiving (S34) an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said second frame;
- go to sleep (S58) until a time prior to said next wake-up time. The method according to claim 1, wherein said communication system comprising a plurality of meters paired with said display device, the method comprises, before going to sleep, repeating a), b) and c) for each paired meter , said information of a next wake-up time being different for each paired meter. The method according to claim 1 or 2, wherein pairing to said at least one counter comprises:

• receiving a signal indicating said display device to pair;
• receiving a signaling frame sent in broadcast mode by said at least one counter;
• sending a frame indicating successful pairing to said at least one counter;
• sending said first time-setting and synchronization frame to said at least one counter;
• receiving an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said first frame.

The method of claim 3, wherein said signal indicating said display device to pair is generated by pressing a button on said display device or by an infrared connector. The method according to claim 3 or 4, comprising, before sending the frame indicating successful pairing:
- sending a request for an encryption key associated with said at least one meter to a management entity of said automated and remote reading of meter counting information;

• receiving said encryption key associated with said at least one counter;
• using said encryption key to encrypt and decrypt the frames exchanged between said display device and said at least one counter.

The method according to one of claims 1 to 5, in which said frames exchanged between said display device and said at least one counter comply with one of the communication standards among WM-Bus, ZigBee and Bluetooth Low Energy. A method for reading a meter executed in an automated metering management system in the context of a fluid distribution service, comprising at least one meter and a display device communicating by exchange of frames conforming to a wireless communication, characterized in that the method comprises for said at least one counter:

• pairing (S18) with said display device, said pairing comprising receiving a first time-setting and synchronization frame transmitted by said display device, said first frame comprising information representative of a time current and information representative of a time of first awakening of said at least one counter;
• waking up (S22) at the first wake-up time;
• sending (S24) to said display device an index frame including count information;
• receiving (S30) a second time-setting and synchronization frame transmitted by said display device, said second frame comprising information representative of a new current time and information representative of a next wake-up time of said at minus one counter;
• set the time (S30) from the new current time;
• sending (S32) an acknowledgment frame to said display device, said frame indicating that said at least one counter has received said second frame;
• going to sleep (S36) until said next wake-up time.

The method of claim 7, wherein pairing to said display device comprises:

• send a signaling frame in broadcast mode and open a listening window;
• receiving a frame indicating successful pairing to said at least one counter;
• receiving said first time-setting and synchronization frame from said at least one counter;
• set the time from the current time of said first frame;
• sending an acknowledgment frame to said display device, said frame indicating that said at least one counter has received said first frame.

A display device in a communication system configured to allow automated and remote reading of meter counting information, said communication system further comprising at least one meter communicating with said display device by exchange of compliant frames to a wireless communication standard, characterized in that the display device is configured for:
- pairing (S18) with said at least one counter, said pairing comprising sending a first time-setting and synchronization frame to said at least one counter, said first frame comprising information representative of a time current allowing the time of said counter to be set and information representative of a time of first awakening of said at least one counter;
- waking up (S20) before the first wake-up time;
a) receiving (S26) an index frame comprising counting information from said at least one counter;
b) sending (S28) a second time-setting and synchronization frame to said at least one counter, said second frame comprising information representative of a new current time and information representative of a next wake-up time of said at least minus one counter;
c) receiving (S34) an acknowledgment frame from said at least one counter, said frame indicating that said at least one counter has received said second frame;
- go to sleep (S58) until a time prior to said next wake-up time. A meter in a communication system configured to allow automated and remote reading of meter counting information, said communication system further comprising a display device communicating with said meter by exchange of frames conforming to a communication standard wireless, characterized in that the counter is configured for:

• pairing (S18) with said display device, said pairing comprising receiving a first time-setting and synchronization frame transmitted by said display device, said first frame comprising information representative of a time current and information representative of a time of first awakening of said counter;
• waking up (S22) at the first wake-up time;
• sending (S24) to said display device an index frame including count information;
• receive (S30) a second time-setting and synchronization frame transmitted by said display device, said second frame comprising information representative of a new current time and information representative of a time of next awakening of said counter ;
• set the time (S30) from the new current time;
• sending (S32) an acknowledgment frame to said display device, said frame indicating that said counter has received said second frame;
• going to sleep (S36) until said next wake-up time.

A communication system configured to allow automated and remote reading of meter counting information, said communication system comprising at least one meter according to claim 10 and a display device according to claim 9 communicating by exchange of frames conforming to a wireless communication standard. A computer program product characterized in that it comprises instructions for implementing, by a processor, the method according to any one of claims 1 to 8, when said program is executed by said processor. A storage medium characterized in that it stores a computer program comprising instructions for implementing, by a processor, the method according to any one of claims 1 to 8, when said program is executed by said processor.