JP2004274251A - Intercom forwarding device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an intercom forwarding device by which an occupant of a house who is out can deal with a visitor with an intercom slave set from outside, and the convenience and security of an intercom system can be improved. <P>SOLUTION: Upon receiving a forwarding command from an intercom master set A, the intercom forwarding device M makes a telephone interface unit 3 call external call terminal C at the telephone number previously stored in a memory . The terminal C at the forwarding destination responds and a channel is closed between the device M and the terminal C via a public telephone line network N. After that, a control unit 7 starts a call processing unit 4, and forwarding call can be performed between the slave set B and the terminal C via the master set A and the device M. <P>COPYRIGHT: (C)2004,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
TECHNICAL FIELD The present invention relates to an interphone transfer device for transferring a call voice with an intercom slave unit to a call terminal outside a home through a public telephone line network.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, there has been provided an intercom system including an intercom slave unit installed outside a house and an intercom master unit installed inside the house and connected to the interphone slave unit via a communication line. FIG. 13 shows a conventional example of this type of intercom system (see Patent Document 1).
[0003]
The intercom master unit M 'includes a microphone 1, a speaker 2, a two-wire to four-wire converter 5, a microphone amplifier G1, a line output amplifier G2 for amplifying a transmission signal to a line (a two-wire transmission line), and a line output amplifier G2. It comprises a line input amplifier G3 for amplifying a reception signal, a speaker amplifier G4, a transmission volume adjustment amplifier G5, a reception volume adjustment amplifier G6, and first and second echo cancellers 30A and 30B. The intercom slave S is composed of a microphone 1 ', a speaker 2', a two-wire to four-wire converter 5 ', a microphone amplifier G1', and a speaker amplifier G4 '.
[0004]
The first echo canceller 30A has a conventionally well-known configuration including an adaptive filter 31A and a subtractor 32A, and has a feedback path (acoustic echo path) H formed by acoustic coupling between the speaker 2 and the microphone 1. _AC 13 is adaptively identified by the adaptive filter 31A, and the echo component (acoustic echo) estimated from the reference signal (input signal to the speaker amplifier G4) is output by the subtractor 32A to the output signal of the microphone amplifier G1 (point in FIG. 13). The echo component is canceled out by subtracting from the signal A). The second echo canceller 30B also has a conventionally well-known configuration including an adaptive filter 31B and a subtractor 32B, and has a reflection and interphone element due to impedance mismatch between the 2-wire / 4-wire conversion unit 5 and the transmission path. Path (line echo path) H formed by the acoustic coupling between the speaker 2 'and the microphone 1' in the device S _LIN 13 is adaptively identified by the adaptive filter 31B, and the echo component (line echo) estimated from the reference signal (the input signal to the line output amplifier G2, that is, the transmission signal) is received by the subtractor 32B in the reception signal (FIG. 13). In this case, the echo component is canceled out by subtracting from the signal at the point C in FIG.
[0005]
Thus, the feedback path H is provided by the first and second echo cancellers 30A and 30B. _AC And H _LIN Since the echo component is canceled to break the closed loop, unpleasant echo and howling can be suppressed. Further, according to the above conventional example, components other than the echo included in the output signal of the microphone amplifier G1, that is, the voice signal uttered by the talker with respect to the intercom master unit M 'and the noise around the intercom master unit M'. Can be transmitted to the intercom slave unit S without any loss, and similarly, a component other than the echo included in the reception signal, that is, the voice signal and the interphone signal uttered by the talker for the interphone slave unit S The noise around the slave unit S can be transmitted to the intercom master unit M 'without any loss. Therefore, two-way simultaneous communication can be realized.
[0006]
[Patent Document 1]
JP-A-2002-359580 (paragraphs 0004 to 0006, FIG. 24)
[0007]
[Problems to be solved by the invention]
By the way, in the past, there was provided an intercom master unit with an answering machine function to record visitors' messages, but if it was an urgent requirement, recording a message would not make much sense There is no. Further, if the visitor is a dangerous person such as a thief, the visitor is informed that he / she is away, which is inconvenient in terms of security.
[0008]
The present invention has been made in view of the above circumstances, and has as its object the convenience and security of an intercom system by allowing a housekeeper on the go to respond to a visitor through an intercom slave unit even while away from home. It is an object of the present invention to provide an intercom transfer device which improves the intercom.
[0009]
[Means for Solving the Problems]
In order to achieve the above object, the invention according to claim 1 provides an intercom system having an intercom slave unit installed outside the house and an intercom master unit installed inside the house and connected to the interphone slave unit via a communication line. A transfer means used to transfer a call voice with the intercom slave unit to a call terminal outside the house through a public telephone line network, and a call process for two-way communication between the interphone slave unit and the call terminal outside the house. Processing means, a first two-wire to four-wire conversion means provided between the communication line and the communication processing means, and a second two-wire to four-wire conversion means provided between the transfer means and the communication processing means Means.
[0010]
According to a second aspect of the present invention, in the first aspect of the present invention, the microphone and the speaker, and the switching connection means for selectively connecting the second two-wire to four-wire conversion means to the microphone, the speaker and the transfer means are provided. It is characterized by having.
[0011]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the call processing means cancels an echo generated by acoustic coupling in a call terminal outside the home or signal wraparound in the second 2-wire to 4-wire conversion means. A first echo canceller, a second echo canceller for canceling an echo generated by acoustic coupling in the intercom slave unit or a signal wraparound in the first two-wire to four-wire conversion means, and first and second echo cancellers Amplifying means for adjusting the communication volume provided on the signal path of the communication signal interposed between the first and second echo cancellers, and reducing the loop gain of the closed loop formed by each echo path. A voice switch that suppresses howling, wherein the voice switch causes a loss in a signal path of a call signal transmitted from a call terminal outside the home to the intercom slave unit. First loss insertion means for inserting, second loss insertion means for inserting a loss in a signal path of a call signal transmitted from the intercom slave to a call terminal outside the home, and first and second loss insertion means From the output point of the second loss insertion means via a feedback path on the side of the telephone outside the home from the output point of the second loss insertion means. Estimating a first feedback gain in a first feedback path that feeds back to an input point of the loss insertion means, and inserting a second loss insertion from an output point of the first loss insertion means via a feedback path on the intercom slave unit side. Total loss estimating a second feedback gain in a second feedback path returning to the input point of the means, and calculating a sum of loss amounts to be inserted into the closed loop based on the estimated values of the first and second feedback gains Monitors call signals and talks And an insertion loss distribution processing unit that determines distribution of each insertion loss amount of the first and second loss insertion means according to the estimation result and the value calculated by the total loss amount calculation unit, The total loss amount calculation unit calculates the sum of the loss amounts to be inserted in the closed loop based on the estimated values of the first and second feedback gains, updates the total loss amount, and updates the total loss amount to a predetermined initial value. It has two operation modes, ie, a fixed mode for fixing, and operates in the fixed mode during a period from the start of the call between the intercom slave unit and the call terminal outside the home until the first and second echo cancellers sufficiently converge. In addition, it operates in the update mode during a period after the first and second echo cancellers sufficiently converge.
[0012]
According to a fourth aspect of the present invention, in the third aspect, a third loss is provided at a stage subsequent to at least one of the first and second loss insertion means included in the voice switch and inserts a loss into a signal path. Insertion means; instantaneous power estimation means for estimating the instantaneous power of the input signal to the voice switch in the signal path provided with the third loss insertion means; and the instantaneous power estimation value by the instantaneous power estimation means continues for a predetermined time or more. And a control means for inserting a predetermined amount of loss from the third loss insertion means when the threshold value becomes equal to or less than the threshold value.
[0013]
According to a fifth aspect of the present invention, in the first or second aspect of the present invention, the call processing means includes a first feedback generated by an acoustic coupling in a call terminal outside the home or a signal wraparound in the second 2-wire to 4-wire conversion means. An audio switch for reducing feedback by reducing a loop gain of a closed loop formed by a path and a second feedback path generated by acoustic coupling in the intercom slave unit or signal wraparound in the first 2-wire to 4-wire conversion means. A voice switch, a first loss insertion unit that inserts a loss into a signal path of a call signal transmitted from the call terminal outside the home to the intercom slave, and a voice switch transmitted from the interphone slave to the call terminal outside the home. A second loss insertion unit that inserts a loss into a signal path of a communication signal, and first and second feedback gains that return via the first and second feedback paths, respectively. Calculates the sum of the loss amounts to be inserted into the closed loop based on the estimated values of the first and second feedback gains, and monitors the speech signal to determine the first and the second according to the estimated speech state and the sum of the loss amounts. An insertion loss amount control unit that determines the distribution of each insertion loss amount of the second insertion loss unit; and a first background noise level estimation unit that estimates a background noise level of the outside call terminal included in the call signal. A second background noise level estimating unit for estimating a background noise level on the intercom slave unit side included in the call signal, and a call signal from the external call terminal monitored by the insertion loss control unit to the interphone slave unit. A first demultiplexing mode setting amplifying section for amplifying, a second demultiplexing mode setting amplifying section for amplifying a call signal from the intercom slave unit monitored by the insertion loss control section to the outside call terminal, Estimate the feedback gain of the feedback path A first feedback gain estimating unit that estimates a feedback gain of a second feedback path, a first and a second background noise level, and a first and a second feedback gain that are estimated A weighted mode control unit that adjusts each gain of the first and second weighted mode setting amplifying units according to the value of the second background noise level. If the state in which the estimated value of the first feedback gain is a value sufficiently larger than the estimated value of the background noise level and smaller than the predetermined value continues for a certain period of time or more, the first demultiplexing mode setting amplifying unit The voice switch is set to the first weighted mode by increasing the gain from the gain of the second weighted mode setting amplification unit, and the estimated value of the first background noise level is calculated from the estimated value of the second background noise level. Is sufficiently large and the estimated value of the second feedback gain is a predetermined value. If the value smaller than the value continues for a certain period of time or more, the gain of the second demultiplexing mode setting amplifying unit is increased more than the gain of the first demultiplexing mode setting amplifying unit, and the voice switch is switched to the second demultiplexing mode. The first and second weighted modes are set unless the state in which the difference between the estimated value of the first background noise level and the estimated value of the second background noise level becomes a sufficiently large value does not continue for a predetermined time or more. It is characterized in that the call processing means is set to the neutral mode by not amplifying the call signal by the setting amplifier.
[0014]
According to a sixth aspect of the present invention, in the first or second aspect of the present invention, when an abnormality such as a fire or a gas leak is detected by a sensor installed in the house, an alarm message or an alarm sound corresponding to the content of the abnormality detected. And a speech processing means provided with a speech communication processing circuit composed of a single processor.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
(Embodiment 1)
FIG. 1 shows a system configuration of an intercom system using the interphone transfer device M of the present embodiment and a configuration of the interphone transfer device M.
[0016]
An intercom slave unit B installed at an entrance outside the home and the like and an intercom master unit A installed inside the home are connected by two communication lines Ls. Then, the intercom master unit A and the intercom transfer device M installed in the house are connected by two communication lines Ls' and a control line Lc. A general telephone D installed in the house is connected to the interphone transfer device M, and the interphone transfer device M is connected to the public telephone network N through a telephone line Lt wired in the house. Note that the telephone D can make and receive calls from the interphone transfer device M to the external telephone terminal C such as a mobile telephone via the public telephone network N.
[0017]
The interphone transfer device M includes a telephone interface unit 3 serving as a transfer unit for transferring a call voice with the intercom slave unit B to the outside call terminal C via the public telephone line network N, and the interphone slave unit B and the outside call terminal C. , A first two-wire to four-wire conversion unit 5 provided between the communication line Ls ′ and the communication processing unit 4, and a telephone interface unit 3. A two-wire to four-wire conversion unit 6 provided between the communication unit 4 and the call processing unit 4, and the interphone transfer device M in response to a control command having the CPU as a main component and received from the intercom master unit A via the control line Lc. And a control unit 7 for performing overall control of.
[0018]
Next, the configuration of the call processing unit 4 will be described with reference to FIG. However, the same components as those of the call processing unit in the conventional intercom master unit M 'are denoted by the same reference numerals, and description thereof will be omitted.
[0019]
An audio switch 10 is provided between volume control amplifiers G5 and G6 provided on a signal path of a call signal sandwiched between the first and second echo cancellers 30A and 30B. The voice switch 10 includes a first loss insertion unit 11 that inserts a loss into a signal path of a call signal transmitted from the out-of-home call terminal C to the intercom slave unit B, and a transmission from the intercom slave unit B to the out-of-home call terminal C. A second loss insertion unit for inserting a loss into a signal path of a communication signal to be transmitted; and an insertion loss control unit for controlling a loss amount inserted from the first and second loss insertion units. I do.
[0020]
The insertion loss control unit 13 performs the first feedback from the output point Rout of the second loss insertion unit 12 to the input point Tin of the first loss insertion unit 11 via the feedback path on the outside call terminal C side. The first feedback gain α in the path H1 is estimated, and the feedback point Tout of the first loss insertion unit 11 is fed back to the input point Rin of the second loss insertion unit 12 via the feedback path on the intercom slave B side. The second feedback gain β in the second feedback path H2 is estimated, and based on the estimated values α ′ and β ′ of the first and second feedback gains α and β, the sum of the loss amounts to be inserted into the closed loop is calculated. The calculated total loss amount calculator 14 monitors the communication signal to estimate the communication state, and the first and second loss insertion units 11 and 12 according to the estimation result and the value calculated by the total loss amount calculator 14. The insertion loss amount distribution processing unit 15 that determines the distribution of each insertion loss amount It has.
[0021]
The total loss calculator 14 estimates a short-time average power of the input signal of the first loss insertion unit 11 using a rectifier smoother, a low-pass filter, or the like, and similarly calculates the rectifier smoother or the low-pass filter. And the like, the time average power of the output signal of the second loss insertion unit 12 in a short time is estimated, and the output signal of the first loss insertion unit 11 is output at the maximum delay time assumed in the first feedback path H1. Of the estimated value of the time-averaged power of the second loss insertion unit 12 and the value obtained by dividing the estimated value of the time-averaged power of the input signal of the second loss insertion unit 12 with the estimated value α ′ of the first feedback gain. In addition, the time-average power of the input signal of the first loss insertion unit 11 in a short time is estimated using a rectifier smoother, a low-pass filter, and the like. Output of the loss insertion unit 11 Estimating the time average power of the signal in a short period of time, obtaining the minimum value of the estimated value of the time average power of the output signal of the second loss insertion unit 12 in the maximum delay time assumed in the second feedback path H2, A value obtained by dividing the estimated value of the time average power of the input signal of the first loss insertion unit 11 by this minimum value is defined as an estimated value β ′ of the second feedback gain. The total loss calculator 14 calculates the total loss required to obtain a desired gain margin from the estimated values α ′ and β ′ of the first and second feedback gains α and β, and calculates the value. Output to the insertion loss distribution processor 15.
[0022]
The insertion loss distribution processor 15 monitors the input and output signals of the first and second loss insertion units 11 and 12 and determines the communication state (for example, from the external telephone terminal C) And the total loss amount is distributed at a rate corresponding to the determined call state and inserted into each signal path from the first and second loss insertion units 11 and 12. .
[0023]
Next, the operation of the intercom system in the present embodiment will be described. First, when a family member is at home, intercom master unit A is set to the normal mode. In this state, when the visitor operates the call button (not shown) of the intercom slave B, the intercom master A detects a call signal transmitted from the interphone slave B through the communication line Ls, and sounds a ring tone from the speaker. Let it ring. Then, if the family member operates the answer button of intercom master unit A in response to the ringing tone, a call can be made between intercom master unit A and intercom slave unit B. When intercom master A is set to the normal mode, a call is made only between intercom master A and intercom slave B as described above, and interphone transfer device M does not function at all.
[0024]
On the other hand, in intercom master unit A, when a transfer setting button (not shown) is operated, the transfer mode is set. Then, when a call signal from intercom slave B is detected in the transfer mode, intercom master A transmits a transfer command to interphone transfer device M via control line Lc. Upon receiving this transfer command, the control unit 7 of the intercom transfer device M transmits the transfer destination telephone number stored in the memory in advance (for example, a mobile phone carried by a family member who has gone out or a telephone set installed at a family member's outside location). The telephone interface unit 3 makes a call to the telephone number of the telephone that is located. Then, the transfer destination outside-the-home telephone terminal (such as the above-mentioned mobile phone or telephone) C responds and the line is closed between the intercom transfer device M and the outside-the-home telephone terminal C via the public telephone network N. Thereafter, the control unit 7 activates the call processing unit 4 and makes a call (hereinafter, referred to as a “transfer call”) between the intercom slave unit B and the outside call terminal C via the intercom master unit A and the interphone transfer device M. ) Becomes possible.
[0025]
In this way, by simply adding the intercom transfer device M according to the present invention to the existing intercom system, the call voice with the intercom slave unit B is transferred to any out-of-home call terminal C. The housekeeper can respond directly to the visitor through the intercom slave unit B, and can respond to urgent requirements, and can make a dangerous person such as a thief think that he is at home. And security can be improved.
[0026]
By the way, in the conventional example, the adaptive filter 31A, 31B of the first and second echo cancellers 30A, 30B usually requires a learning time of several seconds to identify the impulse response of the feedback paths H1, H2. In other words, the feedback paths H1 and H2 cannot be cut off by the first and second echo cancellers 30A and 30B for several seconds immediately after the start of the call, and a closed loop is formed in the communication system. In such a state, the voice uttered by the caller can be heard as an echo by the caller himself, which causes discomfort. Also, howling occurs if the gain of the amplifier is large. Therefore, even in a state in which the echo cancellers 30A and 30B have not converged immediately after the start of a call (a learning state for identifying an impulse response), in order to prevent howling from occurring, the loop gain of the closed loop should not exceed 1 time. It is necessary to design the gain of each amplifier. This obviously imposes restrictions on the call volume.
[0027]
The above is based on the premise that the coefficients of the adaptive filters 31A and 31B of the first and second echo cancellers 30A and 30B are all reset to 0 at the start of a call. On the other hand, a method in which the initial values of the coefficients are given to the adaptive filters 31A and 31B in advance can be considered. However, since the characteristics of the feedback paths H1 and H2 to be identified by the adaptive filters 31A and 31B differ depending on the installation environment, With the set initial value, there is a possibility that the effect of canceling the feedback paths H1 and H2 cannot be obtained at all. Therefore, even in such a system, it is unavoidable that the call volume is restricted.
[0028]
Therefore, in the interphone transfer device M of the present embodiment, the total loss amount calculation unit 14 of the insertion loss amount control unit 13 forms a closed loop based on the estimated values α ′ and β ′ of the feedback gains α and β as described above. It has two operation modes: an update mode in which the sum of the loss amounts to be inserted is calculated and adaptively updated, and a fixed mode in which the total loss amount is fixed to a predetermined initial value. The first and second echo cancellers 30A and 30B operate in the fixed mode during a period until the echo cancelers 30A and 30B sufficiently converge, and operate in the update mode during a period after the first and second echo cancelers 30A and 30B sufficiently converge. ing. That is, in the total loss amount calculating unit 14, the estimated values α ′ and β ′ of the first feedback gain α and the second feedback gain β are both kept for a predetermined time (several hundred milliseconds) or more from the start of the transfer call. (For example, 10 dB to 15 dB smaller than the estimated values α ′ and β ′ at the start of the transfer call), the first and second echo cancellers 30A and 30B have sufficiently converged. It operates in the fixed mode in which the total loss is fixed to the initial value before the time point, and enters the update mode in which the total loss amount is adaptively updated based on the estimated values α ′ and β ′ after the time point. Switch the operation mode. Note that the initial value of the total loss amount in the fixed mode is set to a value sufficiently larger than the total loss amount updated as needed in the update mode.
[0029]
Thus, when the first and second echo cancellers 30A and 30B are not sufficiently converged immediately after the start of the transfer call, the total loss calculator 14 operating in the fixed mode sets the value to a sufficiently large value. Since the total loss of the initial value is inserted into the closed loop, unpleasant echo and howling can be suppressed, and a stable half-duplex call can be realized. In a state where the first and second echo cancellers 30A and 30B have sufficiently converged after a lapse of time from the start of the transfer call, the operation mode of the total loss calculator 14 switches from the fixed mode to the update mode. Since the total loss inserted into the closed loop is reduced to a value sufficiently lower than the initial value, two-way simultaneous communication can be realized. In addition, by setting the initial value of the total loss amount to an appropriate value, the loop gain of the closed loop is reduced to prevent howling in a state where the first and second echo cancellers 30A and 30B do not converge immediately after the start of a call. The constraint of designing the gain of each amplifier so that it does not exceed 1 times is eliminated.
[0030]
Next, a specific operation of the total loss amount calculation unit 14 in the update mode will be described with reference to a flowchart of FIG.
[0031]
The total loss amount calculation unit 14 executes estimation processing of the first and second feedback gains α and β at a predetermined sampling period from the point of time when the mode is shifted from the fixed mode to the update mode (t = t1), and α ′ (n) and β ′ (n) are calculated (step 1), and the gain margin MG of the closed loop is calculated from the product of these two estimated values α ′ (n) and β ′ (n) and the gain margin MG. The desired total loss amount value Lr (n) required to maintain [dB] is calculated by the following equation (step 2).
[0032]
Lr (n) = 20 log | α ′ (n) · β ′ (n) | + MG [dB]
Note that α ′ (n), β ′ (n), and Lr (n) indicate the estimated value of the feedback gain and the desired value of the total loss amount, respectively, calculated by the n-th sampling from the transition to the update mode. Further, the total loss amount calculation unit 14 calculates the n-th total loss amount desired value Lr (n) calculated from the above equation and the previous (n−1-th) total loss amount Lt (n−1), that is, the previous processing. When the total loss amount desired value Lr (n) calculated this time is larger than the total loss amount actually determined and inserted in the above, the previous total loss amount Lt (n−1) is slightly increased by Δi [dB]. ] Is added to the current total loss amount Lt (n) = Lt (n−1) + Δi (steps 3 and 4), and the total amount calculated this time with respect to the previous total loss amount Lt (n−1) is calculated. When the desired loss amount Lr (n) is small, the value obtained by subtracting the slight decrease amount Δd [dB] from the previous total loss amount Lt (n−1) is the current total loss amount Lt (n) = Lt (n). -1) -Δd (steps 5 and 6).
[0033]
As described above, by suppressing the increase / decrease of the total loss amount by the total loss amount calculation unit 14 to a small value of Δi or Δd, the first and second echo cancellers 30A and 30B are directed toward convergence just after the start of the transfer call. Even when the first and second feedback gains α and β change drastically because the coefficient is actively updated, it is possible to eliminate a sense of incongruity in hearing.
[0034]
(Embodiment 2)
FIG. 4 shows a system configuration of an intercom system using the interphone transfer device of the present embodiment. In the present embodiment, the intercom master unit A is configured as an intercom transfer device, and the basic configuration is common to the first embodiment. Therefore, the same reference numerals are given to the same components as those in the first embodiment, and the description will be appropriately omitted.
[0035]
The intercom master unit A includes a microphone 1 and a speaker 2, a telephone interface unit 3 serving as a transfer means for transferring a call with the intercom slave unit B to the outside call terminal C via the public telephone network N, and the interphone slave unit B and the home unit. A call processing unit 4 for performing a call process for making a two-way call with the external call terminal C; a first two-wire to four-wire conversion unit 5 provided between the call line Ls and the call processing unit 4; A two-wire to four-wire conversion unit 6 provided between the telephone interface unit 3 and the call processing unit 4; and the microphone 2 and the speaker 2 and the second two-wire to four-wire conversion unit 6 And a control unit 7 for performing overall control of the intercom master unit A.
[0036]
The control unit 7 has a CPU as a main component, detects a call signal transmitted through the communication line Ls when the call button is operated on the intercom slave B, makes the speaker 2 sound a ringing sound, and (Not shown), the call processing unit 4 is activated to start a call with the intercom slave unit B, and the switching connection unit 8 is controlled to switch the call processing unit 4 to the microphone 1, the speaker 2, and the second. Function to selectively switch connection to the 2-wire to 4-wire conversion unit 6. When a call signal from the intercom slave B is detected when the transfer mode is set as described later, the transfer stored in the memory is performed. The telephone interface unit 3 has a function of making a call to the previous telephone number. The switching between the normal mode in which the call processing unit 4 is connected to the microphone 1 and the speaker 2 by the switching connection unit 8 and the transfer mode in which the call processing unit 4 is connected to the second 2-wire to 4-wire conversion unit 6 are as follows. This is performed by the control unit 7 when a transfer setting button (not shown) is operated.
[0037]
As shown in FIG. 5, the call processing unit 4 is common to the first embodiment, and the microphones 1 and 2 are connected between the amplifiers G1 and G4 and the second 2-wire to 4-wire conversion unit 6 via the switching connection unit 8. The only difference is that the speaker 2 is connected.
[0038]
Next, the basic operation of the intercom master unit A in the present embodiment will be described. First, when a family member is at home, the normal mode is set, and the control unit 7 controls the switching connection unit 8 to connect the call processing unit 4 to the microphone 1 and the speaker 2. When the visitor operates the call button of the intercom slave B in this state, the control unit 7 detects a call signal transmitted from the intercom slave B through the communication line Ls, and causes the speaker 2 to sound a ring tone. Then, when the family member operates the answer button of intercom master unit A in response to the ringing tone, control unit 7 activates call processing unit 4 to start a call with intercom slave unit B.
[0039]
On the other hand, when the transfer setting button (not shown) of the intercom master unit A is operated, the control unit 7 controls the switching connection unit 8 to switch the call processing unit 4 to the second 2-wire to 4-wire conversion unit 6. Connected and set to transfer mode. Then, when detecting the call signal from the intercom slave unit B when the transfer mode is set, the control unit 7 determines the telephone number of the transfer destination stored in the memory in advance (for example, a person who has gone out and carries it). The telephone interface unit 3 makes a call to a mobile phone or a telephone number of a telephone set outside the home. Then, the transfer destination out-of-home telephone terminal (such as the above-mentioned mobile phone or telephone) C responds and the line is closed between the intercom master unit A and the out-of-home telephone terminal C via the public telephone network N. Thereafter, the control unit 7 activates the call processing unit 4 to enable a transfer call between the intercom slave unit B and the outside call terminal C via the intercom master unit A.
[0040]
As described above, in the present embodiment, since the intercom transfer device is incorporated into the intercom master device A and integrated, the system configuration is more complicated than the intercom transfer device M is configured separately from the intercom master device A as in the first embodiment. There is an advantage that it is simplified, space can be saved, and the degree of freedom of the installation location increases.
[0041]
(Embodiment 3)
FIG. 6 is a block diagram showing a configuration of the call processing unit 4 in the intercom transfer device of the present embodiment. However, since the configuration of the call processing unit 4 in the present embodiment is basically the same as that of the first embodiment, the same reference numerals are given to the same components, and the description will be omitted.
[0042]
In the first embodiment, in the silent state when the operation mode of the total loss amount calculating unit 14 shifts to the update mode and the total loss amount in the voice switch 10 is low, the first or second return path H1, When the characteristic of H2 fluctuates, learning of the adaptive filters 31A and 31B does not proceed because the level of the reference signal to the first and second echo cancellers 30A and 30B is low, and as a result, the echo suppression characteristics by the echo cancelers 30A and 30B. Is deteriorated, so that the loop gain of the closed loop of the communication system may exceed 1 times and howling may occur.
[0043]
Therefore, in the present embodiment, as shown in FIG. 6, a third loss insertion unit 20 provided after the first loss insertion unit 11 included in the voice switch 10 to insert a loss into a signal path, The instantaneous power estimating unit 21 for estimating the instantaneous power of the input signal to the voice switch 10 in the signal path provided with the loss insertion unit 20 and the instantaneous power estimation value by the instantaneous power estimating unit 21 continue for a predetermined time or more. The speech processing unit 4 is provided with a loss control unit 22 for inserting a predetermined amount of loss from the third loss insertion unit 20 when the loss becomes equal to or less than the threshold value.
[0044]
The third loss insertion unit 20 is an attenuator having a variable loss amount. The loss control unit 22 selects an insertion loss amount of 0 [dB] or L [dB] (L> 0). Is switched.
[0045]
The loss control unit 22 compares the instantaneous power estimation value Pti of the transmission signal sequentially input from the instantaneous power estimation unit 21 with the threshold value Pc, and as shown in FIG. It is constantly monitored whether or not the situation of (Pti ≦ Pc) continues for a predetermined time Te (several hundreds of ms). When the above situation continues for a predetermined time Te or more, the insertion of the third loss insertion unit 20 is performed. The loss amount is switched from 0 [dB] to L [dB]. When the instantaneous power estimated value Pti exceeds the threshold value Pc after the switching, the insertion loss amount of the third loss insertion unit 20 is changed from L [dB]. Switch to 0 [dB]. In FIG. 7, the vertical axis represents the gain of the third loss insertion unit 20.
[0046]
That is, the loss control unit 22 determines that the instantaneous power estimated value Pti of the call signal from the outside call terminal C to the intercom slave B is equal to or less than the threshold value Pc as a silent state, and the operation of the total loss amount calculation unit 14 After the mode is switched to the update mode, the first feedback gain α is obtained by inserting a loss (L [dB]) into the signal path on the transmitting side when the silent state continues for a while (the predetermined time Te or more). Alternatively, even if the second feedback gain β fluctuates, the loop gain of the closed loop of the communication system does not exceed 1 and the occurrence of howling can be prevented. Here, only when the sum of the loss amounts calculated by the total loss amount calculation unit 14 of the voice switch 10 is smaller than a predetermined value, the loss control unit 22 controls the third loss insertion unit 20 to cause a loss in the signal path. Is inserted, it is possible to suppress the feeling of disconnection at the beginning, during speech, and at the end of words due to excessive loss being inserted into the signal path. Further, a rewritable nonvolatile memory (for example, an EEPROM or the like) for storing a threshold value Pc for the instantaneous power estimated value Pti, a predetermined time Te, and a predetermined amount L [dB] of the insertion loss amount is provided. It is desirable that the controller reads parameters such as the threshold value Pc from the memory (not shown) and performs the above-described control operation. In this way, parameters such as the threshold value Pc for the instantaneous power estimated value Pti can be easily changed from the outside, and it is possible to flexibly cope with various situations in the communication system.
[0047]
It should be noted that a third loss insertion unit that is provided at a subsequent stage (output side) of the second loss insertion unit 12 included in the voice switch 10 and that inserts a loss into a signal path, and an input point of the second loss insertion unit 12. An instantaneous power estimator for estimating the instantaneous power of the signal of Rin (a call signal from the intercom slave unit B to the out-of-home communication terminal C); A loss control unit for inserting a predetermined amount of loss into the third loss insertion unit when the value becomes equal to or less than the third loss insertion unit 20, the instantaneous power estimation unit 21, and the loss control unit 22; It may be configured to be provided together. That is, even when these are provided, it is possible to prevent the occurrence of howling when the silent state continues for a while as described above, and when both are provided, it is possible to more reliably prevent the occurrence of howling. There is.
[0048]
Similarly to the second embodiment, as shown in FIG. 8, the microphone 1 and the speaker 2 are connected between the amplifiers G1 and G4 and the second 2-wire to 4-wire conversion unit 6 via the switching connection unit 8, The intercom transfer device may be configured as the intercom master A.
[0049]
(Embodiment 4)
FIG. 9 is a block diagram showing a configuration of the call processing unit 4 in the interphone transfer device of the present embodiment. However, since the configuration of the call processing unit 4 in the present embodiment is basically the same as that of the first embodiment, the same reference numerals are given to the same components, and the description will be omitted.
[0050]
In the present embodiment, the first background noise level estimating unit 23 for estimating the background noise level of the outside call terminal C included in the call signal and the background noise level of the intercom slave B included in the call signal are estimated. A second background noise level estimating unit 24 and a first demultiplexing mode setting amplifying unit 25 for amplifying a call signal from the outside call terminal C to the intercom slave unit B monitored by the insertion loss control unit 13. A second demultiplexing mode setting amplifying unit 26 for amplifying a call signal from the intercom slave B to the outside call terminal C monitored by the insertion loss control unit 13, and a feedback of the first return path H1 A first feedback gain estimating unit 27 for estimating the gain α, a second feedback gain estimating unit 28 for estimating the feedback gain β of the second feedback path H2, the first and second background noise levels and the first And the estimated value | α of the second feedback gains α and β The call processing unit 4 includes a demultiplexing mode control unit 29 that adjusts each gain of the first and second demultiplexing mode setting amplifying units 25 and 26 in accordance with '|, | β' |.
[0051]
Each of the first and second background noise level estimating units 23 and 24 is realized by an integrating circuit or a digital filter or the like having a characteristic that the rising is gradual and the falling is steep. 23 estimates the background noise level that is constantly present in the speech signal output from the volume adjusting amplifier G5 (the transmission signal as viewed from the outside-home communication terminal C), and the second background noise level estimation unit 24 estimates the volume of the background noise. The background noise (background noise) level that is constantly present in the speech signal output from the adjustment amplifier G6 (the reception signal as viewed from the outside communication terminal C) is estimated. The estimation processing of the feedback gains α and β in the first and second feedback gain estimation units 27 and 28 is common to the estimation processing by the total loss amount calculation unit 14.
[0052]
The weighted mode control unit 29 estimates that the second background noise level estimated value PFn is sufficiently larger than the first background noise level estimated value PNn (PFn≫PNn) and estimates the first feedback gain α. If the state in which the value | α ′ | becomes smaller than the predetermined value α0 (| α ′ | <α0) continues for a certain period of time T1 [sec] or more, the gain of the first demultiplexing mode setting amplification unit 25 is set to G1. [DB] (G1> 0), the gain of the second demultiplexing mode setting amplifying unit 26 is set to 0 [dB], so that the voice switch 10 is set to the first demultiplexed mode, and the first background noise level is reduced. The estimated value PNn is a value (PNn≫PFn) sufficiently larger than the estimated value PFn of the second background noise level, and the estimated value | β ′ | of the second feedback gain H2 is smaller than the predetermined value β0 ( | Β ′ | <β0) if the state continues for a certain time T2 [sec] or more. By setting the gain of the second amplifying mode setting amplifier 26 to G2 [dB] (G2> 0) and setting the gain of the first amplifying mode setting amplifier 25 to 0 [dB], the voice switch 10 is switched to the second. If the mode is set to the weighted mode and the state in which the difference between the estimated value PNn of the first background noise level and the estimated value PFn of the second background noise level becomes a sufficiently large value does not continue for a certain period of time T1 or T2, The voice switch 10 is set to the neutral mode by not amplifying the call signal in the first and second demultiplexing mode setting amplifying units 25 and 26, that is, by setting each gain to substantially zero.
[0053]
In the first embodiment, when the difference between the ambient noise level on the intercom slave unit B side and the ambient noise level on the in-home telephone terminal C side is large, the insertion loss control unit 13 that monitors the telephone signal and estimates the telephone state is used. For example, in the situation where the ambient noise level on the intercom slave unit B side is high, the reception state is always determined from the outside call terminal C side, and in the situation where the ambient noise level on the in-home call terminal C side is high, the call is not sent from the outside call terminal C. A phenomenon that the call state is always determined and the call state is fixed to either the reception state or the transmission state regardless of the actual call state (a so-called one-sided fall of the voice switch 10). There is.
[0054]
On the other hand, in the present embodiment, the decentralized mode control unit 29 compares the estimated value PNn of the first background noise level on the in-home communication terminal C side with the estimated value PFn of the second background noise level on the intercom slave unit B side. In comparison, if the second estimated value PFn of the background noise level is sufficiently large, the speech signal monitored by the insertion loss control unit 13 (the transmission signal as viewed from the outside-home communication terminal C) is transmitted to the first demultiplexed mode. By amplifying the gain G1 [dB] by the setting amplifier 25, the insertion loss control unit 13 sets the state to be easily determined as the transmission state viewed from the outside-of-home communication terminal C (first biased mode), and conversely. If the first estimated value PNn of the background noise level is sufficiently large, the call signal monitored by the insertion loss control unit 13 (the received signal as viewed from the outside call terminal C) is amplified by the second demultiplexing mode setting amplification unit. 26 and the gain is G2 [dB] Insert by amplifying loss controller 13 is prevented from falling pieces of voice switch 10 so as to set the state easy to determine the listen state as seen from the out-of-house speaking terminal C (second overemphasis mode).
[0055]
Here, when the weighted mode control unit 29 switches between the first weighted mode, the second weighted mode, and the neutral mode based only on the comparison result of the first and second estimated values PNn and PFn of the background noise level. For example, when the first feedback gain α is a relatively large value, a phenomenon in which the mobile telephone terminal C should be in a receiving state when it should be viewed from outside the home telephone terminal C but not in a receiving state (reception blocking), and a second phenomenon. When the feedback gain β is a large value to some extent, there is a possibility that a phenomenon (sending blocking) may not occur even though the situation should be the sending state when viewed from the outside telephone terminal C. .
[0056]
Therefore, in the present embodiment, the weighted mode control unit 29 determines not only the level difference between the first and second estimated values PNn and PFn of the background noise level but also the estimated values of the first and second feedback gains α and β. The weighted mode controller 29 sets the first weighted mode, the second weighted mode, and the neutral mode in consideration of | α ′ | and | β ′ |. That is, even when the second background noise level estimated value PFn is sufficiently larger than the first background noise level estimated value PNn for a certain period of time T1 or more, the estimated value | α of the first feedback gain α. When '| exceeds the predetermined value α0, the mode does not shift to the first biased mode, so that it is possible to prevent the voice switch 10 from falling down without causing reception blocking. Further, even when the situation in which the first background noise level estimated value PNn is sufficiently larger than the second background noise level estimated value PFn continues for a certain period of time T2 or more, the estimated value | β 'of the line side feedback gain β. When | exceeds the predetermined value β0, the mode does not shift to the receive multiplexing mode, so that the voice switch 10 can be prevented from falling down without causing transmission blocking.
[0057]
Here, in order to prevent reception blocking and transmission blocking, | α ′ | + G1 <M1, | β ′ | + G2 <M2 (this is rewritten as | α ′ | <M1-G1 = α0, | β '| <M2-G2 = β0) must be established. That is, the predetermined values α0 and β0 are determined according to the margins M1 and M2 for the reception blocking and the transmission blocking, the gain G1 of the first demultiplexing mode setting amplifier 25, and the gain G2 of the second demultiplexing mode setting amplifier 26. It is determined. Note that the gain G1 of the first demultiplexing mode setting amplifier 25 and the gain G2 of the second demultiplexing mode setting amplifier 26 are based on the background on the side of the in-home communication terminal C and the side of the intercom slave unit B assumed in the usage environment, respectively. A request as the interphone transfer device M for what level of sound pressure the voice switch 10 switches to the transmission state or the reception state when the sound level is uttered from the in-home telephone terminal C side and the intercom slave unit B side with respect to the noise level. Determined based on specifications.
[0058]
As in the second embodiment, as shown in FIG. 10, the microphone 1 and the speaker 2 are connected between the amplifiers G1 and G4 and the second 2-wire to 4-wire conversion unit 6 via the switching connection unit 8, The intercom transfer device may be configured as the intercom master A.
[0059]
(Embodiment 5)
Conventionally, fire detectors that detect fire by smoke or heat, gas leak detectors that detect gas leaks, and emergency call switches installed in bathrooms and toilets, etc. An intercom master unit (so-called house information panel) is provided in which a warning message or an alarm sound corresponding to the content of the abnormality is sounded from a speaker when a call is detected or an emergency call switch is operated. Also, in an intercom system using such a housing information panel as a master unit (a housing information panel system), security can be improved by adding the intercom transfer device M according to the present invention.
[0060]
FIG. 11 is a block diagram showing an intercom transfer device M of the present embodiment corresponding to the above-described intercom system (house information panel system). However, the same components as those in the first to fourth embodiments are denoted by the same reference numerals, and description thereof will be omitted.
[0061]
The interphone transfer device M of the present embodiment is a voice call processing circuit including the call processing unit 4 described in any one of Embodiments 1 to 4 and the voice generation unit 41 that generates the above-described alarm message and alarm sound. 40. Here, the call signal (the transmission signal as viewed from the outside call terminal C) input from the second 2-wire / 4-wire conversion unit 6 to the voice call processing circuit 40 is amplified by the amplifier 42 and then subjected to A / D conversion. The conversion from analog to digital is performed by the unit 43 and input to the call processing unit 4, where the call processing unit 4 performs various call processing (processing by the voice switch 10 and the echo cancellers 30 </ b> A and 30 </ b> B described in the first to fourth embodiments). After being converted from digital to analog by the D / A converter 44, the signal is amplified by the amplifier 45. A call signal (received signal as viewed from the outside call terminal C) input from the first two-wire to four-wire conversion unit 5 to the voice call processing circuit 40 is amplified by the amplifier 46 and then the A / D conversion unit 47. Is converted from analog to digital and input to the call processing unit 4. The call processing is performed by the call processing unit 4, and is converted from digital to analog by the D / A conversion unit 48 and then amplified by the amplifier 49.
[0062]
The sound generation unit 41 is appropriately selected from a plurality of prepared alarm sounds to generate a digital alarm sound (not shown), and is compressed and stored in an internal or external memory. And a voice message decompression unit (not shown) for generating a digital voice message by appropriately selecting, reading and decompressing the plurality of voice message data. Note that the alarm sound is for notifying a resident of the occurrence of an abnormality such as a fire or gas leak, and the voice message is a message (alarm message) for notifying the above-mentioned abnormality. Then, the sound signal of the special sound such as the alarm sound and the voice message generated by the sound generation unit 41 is converted from digital to analog by the D / A conversion units 50 and 53, and then amplified by the amplifiers 51 and 54. First or second analog signal multiplexing units 52 and 55 are time-division multiplexed with a communication signal (transmission signal and reception signal) output from communication processing unit 4 and are converted into first or second 2-wire to 4-wire conversion unit Output to 5 and 6.
[0063]
Thus, when the control unit 7 of the intercom transfer device M receives the fire detection signal transmitted from the fire detector or the emergency call signal transmitted from the emergency call switch, the alarm sound generated by the voice generation unit 41 is generated. And an alarm message are transmitted to the intercom slave unit B, and are transmitted from the telephone interface unit 3 to the external telephone terminal C. For this reason, even when the user is out of the office, it is possible to hear the alarm sound and the alarm message from the out-of-home communication terminal C, and the security can be further improved.
[0064]
Here, in the present embodiment, the voice call processing unit 30 is constituted by a single processor such as a digital signal processor (DSP), and the above-described call processing unit is controlled by controlling the hardware of the DSP with dedicated software. 4 and the voice generation unit 41 are realized. As described above, since the simultaneous call processing and the voice generation processing are performed by the voice call processing circuit 30 constituted by a single processor (DSP), compared with the conventional example in which each processing is performed by combining a plurality of integrated circuits. Therefore, there is an advantage that the number of parts can be reduced to reduce the manufacturing cost.
[0065]
(Embodiment 6)
In the present embodiment, as shown in FIG. 12, the intercom master unit A is configured as the interphone transfer device of the fifth embodiment, and the basic configuration is common to the second and fifth embodiments. Therefore, the same reference numerals are given to the same components as those in the second and fifth embodiments, and the description will be appropriately omitted.
[0066]
As shown in FIG. 12, in the intercom master unit A, the microphone 1 and the speaker 2 are connected via the switching connection unit 8 between the amplifier 42 and the first analog signal multiplexing unit 52 and the second 2-wire to 4-wire conversion unit 6. Connected. Also, a monitor unit 56 composed of a CRT, a liquid crystal display, or the like, and displaying an image captured by the imaging camera of the intercom slave B, and a signal processing of a video signal transmitted from the intercom slave B via the communication line Ls. The intercom master unit A includes a video display circuit 57 for displaying a video on the monitor unit 56 and a signal separating unit 58 for separating an audio signal and a video signal multiplexed and transmitted from the intercom slave unit B.
[0067]
On the other hand, the intercom slave unit B in the present embodiment is provided with an imaging camera, and multiplexes an FM signal with a baseband-transmitted audio signal to transmit an audio signal via a communication line Ls composed of a pair of paired lines. And the video signal are transmitted to the intercom master unit A. However, such an intercom slave unit B with a camera is well known in the related art, and a detailed description thereof will be omitted.
[0068]
In the intercom master A, the multiplexed audio signal and video signal received by the first two-wire to four-wire conversion unit 5 are separated by the signal separation unit 58, and the video signal demodulated by the video display circuit 57 is monitored. By outputting the video to the unit 56, the image captured by the imaging camera of the intercom slave B is displayed on the screen of the monitor unit 56.
[0069]
On the other hand, in addition to the alarm sound generation unit and the voice message decompression unit, the sound generation unit 41 appropriately selects from a plurality of ring tones prepared in advance to generate a digital ring sound (shown in FIG. And a melody sound expansion unit (not shown) for generating a digital melody sound by appropriately selecting, reading and expanding a plurality of melody sound data compressed and stored in the memory. The melody tone is used as a ring tone.
[0070]
Further, the voice generation unit 41 includes a specific sound generation unit that generates a specific sound that is used as an excuse to stop the telephone conversation with the other party or a specific sound expansion unit that expands the specific sound data stored in a compressed memory. It has at least one. For example, when responding to the call from the intercom slave B, the other party (the other party) is an uninvited visitor, such as a salesman, and wants to stop the call immediately and pick up the visitor. The housekeeper may want. In such a case, it is possible to create an excuse to stop the call by letting the other party hear a sound such as a telephone ringing sound or a child's cry (this is called a "specific sound"). For example, "The telephone is ringing now" You can immediately stop the call with the other party you do not want to talk to by saying, "Please pick it up because your child is crying and you can't release your hand."
[0071]
Thus, the voice signal of the special sound such as the ringing tone, the alarm tone, or the voice message generated by the voice generating unit 41 is output from the call processing unit 4 by the first or second analog signal multiplexing unit 52, 55. The signal is time-division multiplexed with the communication signal (the transmission signal and the reception signal), and is output to the speaker 2 or the first or second 2-wire to 4-wire conversion units 5 and 6. Note that the operation of the intercom master unit A in the normal mode and the transfer mode is the same as that of the second embodiment, and thus the description is omitted.
[0072]
【The invention's effect】
The invention according to claim 1 is used in an intercom system having an intercom slave unit installed outside the house and an intercom master unit installed inside the house and connected to the interphone slave unit by a communication line, and is connected to a public telephone network. Transfer means for transferring a call voice with the intercom slave to a call terminal outside the house, call processing means for performing call processing for two-way talking between the interphone slave and the call terminal outside the house, and call A first two-wire to four-wire conversion means provided between the line and the call processing means; and a second two-wire to four-wire conversion means provided between the transfer means and the call processing means. By simply adding it to the existing intercom system, the voice of the call to the intercom slave unit can be transferred to any out-of-home calling terminal, allowing the household to respond directly to the visitor from wherever they go. Can be thought to together be supported at home against security risk such as thieves, it can be improved convenience and security as intercom system.
[0073]
According to a second aspect of the present invention, in the first aspect of the present invention, the microphone and the speaker, and the switching connection means for selectively connecting the second two-wire to four-wire conversion means to the microphone, the speaker and the transfer means are provided. The intercom transfer device can be configured as an intercom master unit, which simplifies the system configuration compared to configuring the intercom master unit separately and saves space and increases the degree of freedom in installation locations. become.
[0074]
According to a third aspect of the present invention, in the first or second aspect of the present invention, the call processing means cancels an echo generated by acoustic coupling in a call terminal outside the home or signal wraparound in the second 2-wire to 4-wire conversion means. A first echo canceller, a second echo canceller for canceling an echo generated by acoustic coupling in the intercom slave unit or a signal wraparound in the first two-wire to four-wire conversion means, and first and second echo cancellers Amplifying means for adjusting the communication volume provided on the signal path of the communication signal interposed between the first and second echo cancellers, and reducing the loop gain of the closed loop formed by each echo path. A voice switch that suppresses howling, wherein the voice switch causes a loss in a signal path of a call signal transmitted from a call terminal outside the home to the intercom slave unit. First loss insertion means for inserting, second loss insertion means for inserting a loss in a signal path of a call signal transmitted from the intercom slave to a call terminal outside the home, and first and second loss insertion means From the output point of the second loss insertion means via a feedback path on the side of the telephone outside the home from the output point of the second loss insertion means. Estimating a first feedback gain in a first feedback path that feeds back to an input point of the loss insertion means, and inserting a second loss insertion from an output point of the first loss insertion means via a feedback path on the intercom slave unit side. Total loss estimating a second feedback gain in a second feedback path returning to the input point of the means, and calculating a sum of loss amounts to be inserted into the closed loop based on the estimated values of the first and second feedback gains Monitors call signals and talks And an insertion loss distribution processing unit that determines distribution of each insertion loss amount of the first and second loss insertion means according to the estimation result and the value calculated by the total loss amount calculation unit, The total loss amount calculation unit calculates the sum of the loss amounts to be inserted in the closed loop based on the estimated values of the first and second feedback gains, updates the total loss amount, and updates the total loss amount to a predetermined initial value. It has two operation modes, ie, a fixed mode for fixing, and operates in the fixed mode during a period from the start of the call between the intercom slave unit and the call terminal outside the home until the first and second echo cancellers sufficiently converge. In addition, it operates in the update mode during a period after the first and second echo cancellers have sufficiently converged, and in a state where the first and second echo cancellers have not converged immediately after the start of a call, Operate in fixed mode Since the total loss amount is fixed to a sufficiently large initial value by the total loss amount calculation unit, generation of unpleasant echoes and howling can be suppressed to realize a stable half-duplex call, and the first and second echo cancellers Is sufficiently converged, the total loss amount is updated at any time by the total loss amount calculation unit operating in the update mode, so that two-way simultaneous communication can be realized. In addition, by setting the initial value of the total loss amount to an appropriate value, there is no restriction on the amplification gain including the amplifying means for adjusting the communication volume, so that a sufficient communication volume that does not hinder practical use can be obtained. The amplification gain can be designed as follows.
[0075]
According to a fourth aspect of the present invention, in the third aspect, a third loss is provided at a stage subsequent to at least one of the first and second loss insertion means included in the voice switch and inserts a loss into a signal path. Insertion means; instantaneous power estimation means for estimating the instantaneous power of the input signal to the voice switch in the signal path provided with the third loss insertion means; and the instantaneous power estimation value by the instantaneous power estimation means continues for a predetermined time or more. And a control means for inserting a predetermined amount of loss from the third loss insertion means when the threshold value becomes equal to or less than the threshold value in the call processing means, wherein the operation mode of the total loss amount calculation unit is updated. After switching to the mode, when the silent state continues for a while, the loss is inserted into at least one of the signal path on the transmitting side and the signal receiving side as viewed from the outside-of-home communication terminal. Can be round gain of the closed loop call system even when the echo suppression characteristic is deteriorated in the echo canceller is to prevent the occurrence of howling gone to exceed 1 fold by the characteristics of the second feedback path is varied.
[0076]
According to a fifth aspect of the present invention, in the first or second aspect of the present invention, the call processing means includes a first feedback generated by an acoustic coupling in a call terminal outside the home or a signal wraparound in the second 2-wire to 4-wire conversion means. An audio switch for reducing feedback by reducing a loop gain of a closed loop formed by a path and a second feedback path generated by acoustic coupling in the intercom slave unit or signal wraparound in the first 2-wire to 4-wire conversion means. A voice switch, a first loss insertion unit that inserts a loss into a signal path of a call signal transmitted from the call terminal outside the home to the intercom slave, and a voice switch transmitted from the interphone slave to the call terminal outside the home. A second loss insertion unit that inserts a loss into a signal path of a communication signal, and first and second feedback gains that return via the first and second feedback paths, respectively. Calculates the sum of the loss amounts to be inserted into the closed loop based on the estimated values of the first and second feedback gains, and monitors the speech signal to determine the first and the second according to the estimated speech state and the sum of the loss amounts. An insertion loss amount control unit that determines the distribution of each insertion loss amount of the second insertion loss unit; and a first background noise level estimation unit that estimates a background noise level of the outside call terminal included in the call signal. A second background noise level estimating unit for estimating a background noise level on the intercom slave unit side included in the call signal, and a call signal from the external call terminal monitored by the insertion loss control unit to the interphone slave unit. A first demultiplexing mode setting amplifying section for amplifying, a second demultiplexing mode setting amplifying section for amplifying a call signal from the intercom slave unit monitored by the insertion loss control section to the outside call terminal, Estimate the feedback gain of the feedback path A first feedback gain estimating unit that estimates a feedback gain of a second feedback path, a first and a second background noise level, and a first and a second feedback gain that are estimated A weighted mode control unit that adjusts each gain of the first and second weighted mode setting amplifying units according to the value of the second background noise level. If the state in which the estimated value of the first feedback gain is a value sufficiently larger than the estimated value of the background noise level and smaller than the predetermined value continues for a certain period of time or more, the first demultiplexing mode setting amplifying unit The voice switch is set to the first weighted mode by increasing the gain from the gain of the second weighted mode setting amplification unit, and the estimated value of the first background noise level is calculated from the estimated value of the second background noise level. Is sufficiently large and the estimated value of the second feedback gain is a predetermined value. If the value smaller than the value continues for a certain period of time or more, the gain of the second demultiplexing mode setting amplifying unit is increased more than the gain of the first demultiplexing mode setting amplifying unit, and the voice switch is switched to the second demultiplexing mode. The first and second weighted modes are set unless the state in which the difference between the estimated value of the first background noise level and the estimated value of the second background noise level becomes a sufficiently large value does not continue for a predetermined time or more. The call processing means is set to the neutral mode by not amplifying the call signal by the setting amplification unit, and not only the difference in the ambient noise level between the intercom slave unit side and the outside call terminal side, but also the first and second modes. In consideration of the respective estimated values of the feedback gain of 2, the first decentralized mode, the second decentralized mode, and the neutral mode are set, so that transmission blocking and reception blocking as viewed from the outside-home telephone terminal do not occur, Voice switch It is possible to prevent the falling pieces of switch.
[0077]
According to a sixth aspect of the present invention, in the first or second aspect of the present invention, when an abnormality such as a fire or a gas leak is detected by a sensor installed in the house, an alarm message or an alarm sound corresponding to the content of the abnormality detected. The voice generation means for generating the, the call processing means, characterized by comprising a voice call processing circuit configured by a single processor, the voice processing by the voice call processing circuit configured by a single processor, Since the voice generation processing is performed, the number of components is reduced as compared with the conventional example in which each processing is performed by combining a plurality of integrated circuits, thereby reducing the manufacturing cost.
[Brief description of the drawings]
FIG. 1 is a system configuration diagram of an intercom system including an interphone transfer device according to a first embodiment.
FIG. 2 is a block diagram of a call processing unit in the embodiment.
FIG. 3 is a flowchart for explaining the operation of the above-described call processing unit.
FIG. 4 is a system configuration diagram of a second embodiment.
FIG. 5 is a block diagram of a call processing unit in the embodiment.
FIG. 6 is a block diagram of a call processing unit according to a third embodiment.
FIG. 7 is an operation explanatory view of the above.
FIG. 8 is a block diagram of a call processing unit when the above is configured as an intercom master unit.
FIG. 9 is a block diagram of a call processing unit according to a fourth embodiment.
FIG. 10 is a block diagram of a call processing unit when the above is configured as an intercom master unit.
FIG. 11 is a block diagram showing a main part of a fifth embodiment.
FIG. 12 is a block diagram showing a main part of a sixth embodiment.
FIG. 13 is a block diagram of a conventional intercom master unit and intercom slave unit.
[Explanation of symbols]
M intercom transfer device
3 Telephone interface
4 Call processing section
5 First two-wire to four-wire converter
6. Second 2-wire to 4-wire conversion unit
7 control section
A Intercom master unit
B Intercom cordless handset
C Outside call terminal
N Public telephone network

Claims (6)

It is used in an intercom system having an intercom slave unit installed outside the home and an intercom master unit installed inside the home and connected to the intercom slave unit via a communication line. A transfer unit for transferring a call voice with the slave unit, a call processing unit for performing a call process for performing a two-way call between the intercom slave unit and a call terminal outside the home, and a call line and the call processing unit. An interphone transfer device comprising: a first two-wire to four-wire conversion means provided in the communication device; and a second two-wire to four-wire conversion means provided between the transfer means and the call processing means. 2. The interphone transfer according to claim 1, further comprising a microphone and a speaker, and switching connection means for selectively connecting and connecting the second two-wire to four-wire conversion means to the microphone and the speaker and the transfer means. apparatus. The call processing means comprises: a first echo canceller for canceling acoustic coupling at a telephone terminal outside the home or echo caused by signal wraparound at the second 2-wire to 4-wire converting means; and acoustic coupling or first coupling at an intercom slave unit. A second echo canceller for canceling an echo caused by signal wraparound in the 2-wire to 4-wire conversion means, and a call volume adjustment provided on a signal path of a call signal sandwiched between the first and second echo cancellers. Amplifying means, and a voice switch provided between the first and second echo cancellers, for reducing feedback in a closed loop formed by each echo path to suppress howling. First loss insertion means for inserting a loss into a signal path of a call signal transmitted from an outside call terminal to an intercom slave, and an interphone slave Loss insertion means for inserting a loss into a signal path of a speech signal transmitted from the home to a call terminal outside the home, and insertion loss amount control means for controlling the amount of loss inserted from the first and second loss insertion means Wherein the insertion loss amount control means includes a first feedback loop that feeds back from the output point of the second loss insertion means to the input point of the first loss insertion means via a feedback path on the side of the telephone outside the home. A second feedback path for estimating the first feedback gain in the path and returning from the output point of the first loss insertion means to the input point of the second loss insertion means via the feedback path on the intercom slave unit side. A total loss amount calculator for estimating a second feedback gain, calculating a total loss amount to be inserted into the closed loop based on the estimated values of the first and second feedback gains, and monitoring a communication signal to set a communication state Is estimated, and this estimation result is calculated by the total loss amount calculation unit. And an insertion loss amount distribution processing unit that determines the distribution of each insertion loss amount of the first and second loss insertion means in accordance with the first and second loss insertion means, wherein the total loss amount calculation unit estimates the first and second feedback gains. It has two operation modes: an update mode in which the sum of the loss amounts to be inserted into the closed loop is calculated based on the values and an adaptive update, and a fixed mode in which the total loss amount is fixed at a predetermined initial value. During the period from the start of the call with the call terminal outside the home to the time when the first and second echo cancellers are sufficiently converged, the apparatus operates in the fixed mode and the time after the first and second echo cancellers are sufficiently converged. 3. The interphone transfer device according to claim 1, wherein the interphone transfer device operates in an update mode. A third loss insertion unit is provided at a stage subsequent to at least one of the first and second loss insertion units included in the voice switch, and a third loss insertion unit is provided. An instantaneous power estimating means for estimating the instantaneous power of the input signal to the voice switch in the signal path; and a third method when the instantaneous power estimation value by the instantaneous power estimating means continuously falls below the threshold for a predetermined time or more. 4. The interphone transfer device according to claim 3, wherein said call processing means includes control means for inserting a predetermined amount of loss from said loss insertion means. The call processing means includes: a first return path generated by acoustic coupling at a telephone terminal outside the home or a signal wraparound at the second two-wire to four-wire conversion means; A voice switch for reducing a loop gain of a closed loop formed by a second feedback path generated by signal wraparound in the four-wire conversion means to suppress howling; Loss insertion unit that inserts a loss into a signal path of a call signal transmitted to a telephone, and a second loss insertion that inserts a loss into a signal path of a call signal transmitted from an intercom slave unit to a telephone terminal outside the home And a unit for estimating first and second feedback gains that return via the first and second feedback paths, respectively, based on the estimated values of the first and second feedback gains. To calculate the sum of the loss amounts to be inserted into the closed loop, and monitor the speech signal to determine the distribution of the respective insertion loss amounts of the first and second insertion loss units according to the estimated speech state and the sum of the loss amounts. A first background noise level estimating unit for estimating a background noise level on the side of the communication terminal outside the house included in the call signal, and a background noise level on the side of the intercom slave unit included in the call signal. A second background noise level estimating unit for estimating, a first demultiplexing mode setting amplifying unit for amplifying a call signal from the external call terminal to the intercom slave unit monitored by the insertion loss amount control unit, and an insertion loss A second demultiplexing mode setting amplifying unit for amplifying a call signal from the intercom slave unit monitored by the amount control unit to the outside call terminal, and a first feedback gain for estimating a feedback gain of the first feedback path An estimator and a second return path return A second feedback gain estimator for estimating a gain, and first and second demultiplexing mode setting amplifiers according to the first and second background noise levels and the first and second feedback gain estimation values. And a weighted mode control unit that adjusts each of the gains. The weighted mode control unit determines that the estimated value of the second background noise level is sufficiently larger than the estimated value of the first background noise level, and If the estimated value of the feedback gain becomes smaller than the predetermined value for a certain period of time or more, the gain of the first amplifying unit for setting the mode is increased from the gain of the second amplifying unit for setting the mode. The voice switch is set to the first weighted mode, the estimated value of the first background noise level is sufficiently larger than the estimated value of the second background noise level, and the estimated value of the second feedback gain is If the value that is smaller than the specified value continues for a certain period of time For example, the gain of the second amplifying unit for setting a mode is set to be larger than the gain of the first amplifying unit for setting a mode, the voice switch is set to the second mode, and the estimated value of the first background noise level is set. Unless the state in which the difference between the estimated value of the second background noise level and the estimated value of the second background noise level become sufficiently large does not continue for a certain period of time, the first and second demultiplexing mode setting amplifying units do not amplify the communication signal, thereby performing the communication processing. 3. The interphone transfer device according to claim 1, wherein the means is set to a neutral mode. When an abnormality such as a fire or a gas leak is detected by a sensor installed in the house, a voice generation unit that generates an alarm message or an alarm sound according to the content of the detected abnormality and a call processing unit are a single unit. 3. The interphone transfer device according to claim 1, further comprising a voice call processing circuit including a processor.

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