SERVER PROVIDING A QUIETER OPEN SPACE WORK ENVIRONMENT

Abstract

A server for providing a quieter environment in an open work space that has a plurality of work places used by a plurality of users comprises a processor configured to receive digital audio signals corresponding to ambient noises captured by microphones at the work places, compute average values that represent current noises at the work places, compute a threshold value that represents a current noise in a neighbourhood of a first work place as a function of p values that represent the current noises at p work places that are neighbors of the first work place, compare each digital audio signal with the threshold value, determine the digital audio signals that are greater than the threshold value to determine at least one work place that corresponds to a digital audio signal that is greater than the threshold value, and send a warning to a user of the determined at least one work place.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention generally relates to a server providing a quieter open space work environment. Office work places are more and more often open work spaces. An open work space eases verbal communication between people in the same open space. However conversations between people, conversations on phones (sometime hand free), and ringtones of phones, make a noisy environment, which generates tiredness and frustration of people working in such an open work space.

The impact of a noisy work place is huge on working people. It is a source of negative stress, lack of concentration, and tension between people. It generates a loss of productivity for a company.

2. Description of the Prior Art

Rules are generally issued in most companies, in order to generate the lowest noise level as possible in the open work spaces. In particular, these rules compel anybody to go to dedicated rooms to hold meetings and conference calls. Phone calls and conversations are allowed in the open work spaces for short periods of time only. If a conversation is longer than expected, the use of a dedicated room is then mandatory.

However rules are not thoroughly followed. While some people have low voice and do not generate a high noise level in an open work space, others have loud voices and generate frustration for people around them.

Many applications regarding noise reduction or noise metering exist on personal computers or smart phones; but they are only related to the noise generated on the work place where the device is. They are not quite satisfactory because the full environment of the work place is not taken into account. In some cases, you may be noisy but you add low additional perturbation if the whole environment is also noisy. Then noise reduction or noise metering on your own computer or smartphone is useless.

Some physical means are known for reducing the effect of ambient noise:

• • Active noise reduction by loudspeakers or headsets.
  • Passive noise reduction by sound absorbing building materials. Automatic adaptation of the audio levels of phone sets: Each phone set comprise an auxiliary microphone for capturing the ambient noise. According to the ambient noise, the phone set decides by itself to adapt the level of the reproduced audio signal.These physical means are not quite satisfactory. So there is a need to provide a better technical solution for obtaining a quieter open space work environment.

SUMMARY OF THE INVENTION

The object of the invention is a server for providing a quieter environment in an open work space comprising a plurality of work places WP₁₁, WP_ij, . . . , WP_nm respectively used by a plurality of users; said server comprising a processor configured for:

• • receiving, at the instant t, digital audio signals AN_ij(t), for i=1 to n and j=1 to m, corresponding to the ambient noises respectively captured by microphones at the work places WP₁₁, . . . , WP_nm;
  • computing average values L_ij(t), for i=1 to n and j=1 to m, respectively representing the current noises at the work places WP₁₁, . . . , WP_nm, at the instant t;
  • computing a threshold value TH_ij(t) that represents the current noise, at the instant t, in the neighbourhood of the work place WP_ij as a function of p values L_ij(t) respectively representing the current noises at p work places that are neighbors of the work place WP_ij;
  • comparing each digital audio signal AN_ij(t) with the threshold value TH_ij(t) for i=1 to n and j=1 to m;
  • then determining what are the digital audio signals AN_ij(t) that are respectively greater than the threshold value TH_ij(t) for i=1 to n and j=1 to m, for determining at least one work place that corresponds to a digital audio signal AN_ij(t) that is greater than the threshold value TH_ij(t); and then notifying a warning to the user of the so determined work place.

Thanks to the comparison between the noise generated locally on each work place with a threshold representing the average noise of all the work space (or the average noise of a limited neighbourhood around the work place), it is possible to determine whether the user of this work place is particularly noisy, in comparison with his/her neighbourhood, and then to notify a warning to this user. This warning encourages the user to be quieter.

According to a first peculiar embodiment of the server according to the present invention, periodically computing a threshold value TH_ij(t) that represents the current noise in the neighbourhood of the work place WP_ij as a function of the values L_ij(t) respectively representing the current noises at the work places WP₁₁, . . . , WP_nm , at the instant t, comprises the step of taking into account the values L_ij(t) respectively representing the current noises at all the work places WP₁₁, . . . , WP_nm of the open work space (OWS).

According to a second peculiar embodiment of the server according to the present invention, periodically computing a threshold value TH_ij(t) that represents the current noise in the neighbourhood of the work place WP_ij as a function of the values L_ij(t) respectively representing the current noises at the work places WP₁₁, . . . , WP_nm, at the instant t, takes into account the values L_ij(t) respectively representing the current noises at work places that are close neighbours of the workplace WP_ij.

Other features and advantages of the present invention will become more apparent from the following detailed description of embodiments of the present invention, when taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In order to illustrate in detail features and advantages of embodiments of the present invention, the following description will be with reference to the accompanying drawings. If possible, like or similar reference numerals designate the same or similar components throughout the figures thereof and description, in which:

FIG. 1 is a block diagram showing an exemplary open work space comprising an embodiment of the server according to the invention.

FIG. 2 shows a specimen of a known telephone set that can be used to collaborate with the server according to the invention.

FIG. 3 is a flow chart of the steps executed by a first embodiment of the server according to the invention.

FIG. 4 is a flow chart of the steps executed by a second embodiment of the server according to the invention.

FIG. 5 illustrates the technical effect of the invention in the exemplary open work space represented on FIG. 1.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

On FIG. 1, an exemplary open work space OWS comprises a plurality of work places WP₁₁, . . . , WP_ij, . . . , WP_nm respectively used by a plurality of users. They are placed in a matrix of m columns and n lines. For instance, n=4 and m=4. For instance, it is an open work space for sixteen employees of a call center. Each work place WP_ij comprises a personal computer PC_ij and a telephone set T_ij. These telephone sets T_ij are linked to a classical call server (not represented) and to a notification server NS according to the invention, via a classical Ethernet local area network.

FIG. 2 shows a specimen T_ij of a known telephone set that can be used to collaborate with the server according to the invention. It comprises a classical handset HS comprising a earphone EP, a microphone M1, and a base B comprising a liquid crystal display LCD and an auxiliary microphone M2. According to the invention, the auxiliary microphone M2 is used to permanently capture the ambient noise around the telephone set T_ij. An application is embedded in this telephone set in order to permanently transmit, to the notification server NS, a digital audio signal AN_ij(t) corresponding to the ambient noise captured by this auxiliary microphone M2.

In addition, the digital audio signal AN_ij(t) may be used locally in the telephone set T_ij, or centrally in a call server, for classically reducing the effect of the ambient noise by subtracting the digital audio signal AN_ij(t) from the audio signal applied to the loud speaker HP, during a phone call.

FIG. 3 is a flow chart of the steps executed by a first embodiment NS of the server according to the invention. The notification server NS comprises a processor executing a software module that is configured for doing the following steps:

Step 31: This software module receives the sixteen digital audio signals AN_ij(t) for i=1 to 4 and j=1 to 4, corresponding to the ambient noises captured by the auxiliary microphones of the telephone sets T₁₁, . . . , T₄₄ of all the work places of the open work space OWS, at the instant t.

Step 32: It periodically computes an average level L_ij(t) for each telephone set for i=1 to 4 and j=1 to 4, in a sliding time interval staring at time t, during one minute for instance.

Step 33: The software module also periodically computes a sum S(t) of the sixteen average levels T_ij(t), for i=1 to 4 and j=1 to 4. Then it divides this sum S(t) by sixteen to obtain a threshold value TH(t) that represents the average level of the ambient noise in the whole open work space OWS at the instant t.

Step 34: Then it compares each digital audio signal AN_ij(t), for i=1 to 4 and j=1 to 4, with the threshold value TH(t) and determines what are the digital audio signals AN_ij(t) that are greater than the threshold value TH(t).

Step 35: The result of this comparison determines the work places that are peculiarly noisy, presumably because the users working at these places are speaking too loud. Then the software module sends a notification to the telephone sets T_ij (or to the associated personal computers PC_ij) corresponding to the digital audio signals AN_ij(t) that are greater than the threshold value TH(t).

FIG. 4 is a flow chart of the steps executed by a second embodiment NS′ of the server according to the invention. The notification server NS′ comprises a processor executing a software module that is configured for doing the following steps:

Step 41: This software module receives the sixteen digital audio signals AN_{ij (t)}, for i=1 to 4 and j=1 to 4, corresponding to the ambient noises captured by the auxiliary microphones of the telephone sets T₁₁, . . . , T₄₄ of all the work places of the open work space OWS.

Step 42: It periodically computes an average level _ij(t) for each telephone set for i=1 to 4 and j=1 to 4, in a sliding time interval staring at time t, during one minute for instance.

Step 43: Then, for each work place WP_ij, for i=1 to 4 and j=1 to 4, it computes a sum S′_ij(t) of the p average levels Lij(t) corresponding to p close neighbor work places around the considered work place WP_ij:

WP_{i−1 j−1}, WP_{i−1 j}, WP_{i−1 j+1},WP_{i j−1} WP_{i j+1},WP_{i+i j−1}, WP_{i+1 j}, WP_{i+1 j+1} It then divides this sum S′_ij(t) by p. For instance, p=8 for WP₂₂, whereas p=3 for WP₁₁ because it is on a border. So the software module obtains a local threshold values TH′_ij(t) that represents the average level of the ambient noise at a given time t, in the closest neighborhood of the work place WP_ij. In this example of open work space OWS, there are sixteen local threshold values TH′_ij(t) for the instant t.

Step 44: The software module compares each digital audio signal AN_ij(t), for i=1 to 4 and j=1 to 4, with the respective local threshold values TH′_ij(t), and determines what are the digital audio signals AN_ij(t) that are greater than the corresponding threshold value TH′_ij(t).

Step 45: The comparison determines the work places that are peculiarly noisy, presumably because the users working at these places are speaking too loud. Then the software sends a notification to the telephone sets T_ij (or to the associated personal computers PC_ij) corresponding to the digital audio signals AN_ij(t) that are greater than the current threshold value TH′_ij(t).

FIG. 5 illustrates the technical effect of the invention in the exemplary open work space OWS represented on FIG. 1. In the example represented on FIG. 5, at the instant t, the digital audio signals AN₂₂(t) and AN₃₃(t) are greater than the current threshold value TH(t). A warning is notified to the users of the work places WP₂₂ and WP₃₃. In this example, the notification server NS sends notifications respectively to the telephone terminals T₂₂ and T₃₃. In an embodiment, the warning is a blinking message on the displays LCD of these telephone sets, for instance, or on the screens of the associated personal computers. When people know they are generating perturbations for other people in the same open work space they usually adapt their behavior to the situation.

In other embodiments, the ambient noise can be monitored by other means such as:

• • A microphone classically embedded in each personal computer.
  • An independent microphone located at each work place.

The warning can be notified by different means such as:

• • A warning message on the computer display of a user.
  • Lights with dedicated colors corresponding to the levels of perturbation: from yellow to red for instance.
  • A bip superimposed onto the audio signal reproduced by the earphone of the handset.

Further more, statistics can be computed and stored in the notification server and, when needed, a report can be provided for a given period of time.

In the example illustrated by FIG. 4, the considered close neighbor work places are located in the rows and columns that are immediately next to the considered work place. In other examples, the considered close neighbor work places may be a little further, though not embracing the whole open work space. For instance:

WP_{i−2 j−2}, WP_{i−2 j−1}, WP_{i−2 j}, WP_{i−2 j+1}, WP_{i−2 j+2} WP_{i−1 j−2}, WP_{i−1 j−1}, WP_{i−1 j}, WP_{i−1 j+1}, WP_{i−1 j+2} WP_{i j−2}, WP_{i j−1} WP_{i j+i}, WP_{i j+2} WP_{i+1 j−2}, WP_{i+1 j−1}, WP_{i+1 j}, WP_{i+1 j+1}, WP_{i+1 j+2} WP_{i+2 j−2}, WP_{i+2 j−1}, WP_{i+2 j}, WP_{i+2 j+1}, WP_{i+2 j+2}

Claims

1. A method for providing a quieter environment in an open work space comprising a plurality of work places respectively used by a plurality of users, comprising the steps of: receiving, at an instant t, digital audio signals corresponding to ambient noises respectively captured by microphones at the work places;computing average values respectively representing current noises at the work places at the instant t;computing a threshold value that represents a current noise, at the instant t, in a neighbourhood of a first work place as a function of p values respectively representing the current noises at p work places that are neighbors of the first work place;comparing each digital audio signal with the threshold value;determining the digital audio signals that are respectively greater than the threshold value to determine at least one work place that corresponds to a digital audio signal that is greater than the threshold value; andnotifying a warning to a user of the determined at least one work place.

2. The method according to claim 1, wherein the step of computing the threshold value that represents the current noise in the neighbourhood of the first work place as a function of the p values respectively representing the current noises at the p work places at the instant t, comprises the step of taking into account the values respectively representing the current noises at all the work places of the open work space.

3. The method according to claim 1, wherein the step of computing the threshold value that represents the current noise in the neighbourhood of the first work place as a function of the p values respectively representing the current noises at the p work places at the instant t, comprises the step of taking into account the values respectively representing the current noises at work places that are close neighbours of the first workplace.

4. The method according to claim 1, wherein the threshold value is computed periodically.

5. The method according to claim 1, wherein the warning is a blinking message on a display of a telephone or on a screen of a personal computer.

6. A server for providing a quieter environment in an open work space comprising a plurality of work places respectively used by a plurality of users; said server comprising a processor configured to: receive, at an instant t, digital audio signals that correspond to ambient noises respectively captured by microphones at the work places;compute average values that represent current noises at the work places at the instant t;compute a threshold value that represents a current noise, at the instant t, in a neighbourhood of a first work place as a function of p values that represents the current noises at p work places that are neighbors of the first work place;compare each digital audio signal with the threshold value;determine the digital audio signals that are greater than the threshold value to determine at least one work place that corresponds to a digital audio signal that is greater than the threshold value; andsend a warning to a user of the determined at least one work place.

7. The server according to claim 6, wherein the compute the threshold value that represents the current noise in the neighbourhood of the first work place as a function of the p values that represents the current noises at the p work places at the instant t takes into account the values that represent the current noises at all the work places of the open work space.

8. The server according to claim 6, wherein the compute the threshold value that represents the current noise in the neighbourhood of the first work place as a function of the p values that represents the current noises at the p work places at the instant t takes into account the values that represent the current noises at work places that are close neighbours of the first workplace.

9. The server according to claim 6, wherein the threshold value is computed periodically.

10. The method according to claim 6, wherein the warning is a blinking message on a display of a telephone or on a screen of a personal computer.