JPH07245770A - Feeder system - Google Patents

Abstract

PURPOSE:To promote miniaturization and economy of a subscriber circuit to the utmost with respect to the power feeder system for the exchange subscriber circuit. CONSTITUTION:In the subscriber circuit supplying a DC current to a subscriber line (300) in a direction from a line B to a line A, the line B is connected to a positive power supply (V+) whose voltage is higher than a voltage of an earth (E) via a feeder circuit (100) having a prescribed resistance with respect to the DC signal and having a prescribed impedance or over with respect to a voice signal and the line A is connected to the earth (E), or the line B is connected to the positive power supply (V+) and the line A is connected to the earth (E) via the feeder circuit 100, or the line B is connected to the earth (E) via the feeder circuit 100 and the line A connects to a negative power supply (V-), or the line B is connected to the earth (E) and the line A is connected to the negative power supply (V-) via the feeder circuit 100, or the line B is connected to the positive power supply (V+) via the feeder circuit 100 and the line A is connected to the negative power supply (V-), or the line B is connected to the positive power supply (V+) and the line A is connected to the negative power supply (V-) via the feeder circuit 100.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply system in a subscriber circuit of an exchange, and more particularly to a power supply system in a subscriber circuit for supplying a direct current to a subscriber line in a direction from line B to line A.

[0002]

2. Description of the Related Art FIG. 4 is a diagram showing an example of a subscriber line accommodation type, and FIG. 4 (a) shows a direct exchange accommodation type.
FIG. 5B shows a remote device accommodation type, and FIG. 5 is a diagram showing an example of a conventional power feeding system.

In a general exchange (1), a home (2
The analog telephone (2) installed in (0) is connected directly to the exchange (1) by the subscriber line (3) as shown in FIG. 4 (a).
It is housed in.

In the exchange (1), a subscriber circuit (SLC) (11) accommodating a subscriber line (3) comprises a power supply circuit for supplying a direct current in a predetermined range to an analog telephone (2). ing.

The direct current supplied from the subscriber circuit (SLC) (11) to the analog telephone (2) decreases as the line length of the subscriber line (3) increases and the line resistance increases. The remote analog telephone (2) is also accommodated in the exchange (1) as long as the direct current maintains the allowable value.

As the subscriber line (3) becomes long-distance, the chances of being affected by the inductive signal from the power line or the like increase. Since this kind of induction signal is an in-phase signal with respect to the A line and the B line of the subscriber line (3), the subscriber circuit (S
If the impedance between the A and B lines of LC (11) and the ground is unbalanced, a differential signal is generated between the A and B lines, which adversely affects voice as noise.

As shown in FIG. 5, the feeder circuit provided in the subscriber circuit (SLC) (11) connects the B line of the subscriber circuit (SLC) (11) to the B line side feeder circuit (6 _B ). From the ground (E) to the side of the B line by connecting the A line to the negative power source (V-) via the A line side power supply circuit (6 _A ) while connecting to the ground (E) via the Power supply circuit (6 _B ), B
DC current flowing to the negative power source (V-) via the line, the A line, and the A line side power supply circuit (6 _A ) is supplied to the analog telephone (2) via the subscriber line (3). It will be.

Here, the B line side power supply circuit (6 _B ) and A
The line side power supply circuit (6 _A ) has a resistance value within a predetermined range for a DC signal and an impedance over a predetermined value for a voice signal, and maintains an unbalance between both impedances within an allowable range. Is required in order to reduce the noise caused by the aforementioned induction signal.

[0009]

As is apparent from the above description, in the conventional subscriber circuit, in consideration of accommodating the subscriber line (3) which is often affected by the inductive signal, B It is necessary to provide a B-line side power supply circuit (6 _B ) and an A-line side power supply circuit (6 _A ) with balanced impedance on the A line and the A line, which poses a problem of impairing economy and downsizing of the subscriber circuit. It was

It is an object of the present invention to promote miniaturization and economy of subscriber circuits as much as possible.

[0011]

In recent years, with the rapid progress in downsizing and economicization of communication equipment, there is a remote device accommodating type as shown in FIG. 4 (b) as an accommodating type of the analog telephone (2). It is being put to practical use.

In FIG. 4 (b), a remote device (4) is provided in a remote place from the exchange (1), and an analog telephone (2) installed in a house (20) near the remote device (4) is remote. It is housed in the device (4), and the remote device (4) and the exchange (1) are connected by a multiple line (5).

The remote unit (4) has a subscriber circuit (SL).
C) (41) and demultiplexing circuit (MDPX) (42)
Is provided, and the exchange (1) is provided with a demultiplexing circuit (MD
PX) (13) is provided.

The subscriber circuit (SLC) (41) accommodates the analog telephone (2) via the subscriber line (3) and is provided in the exchange (1) in FIG. 4 (a). It has the same function as the subscriber circuit (SLC) (11).

The demultiplexing circuit (MDPX) (42) multiplexes the signals from a plurality of subscriber circuits (SLC) (41) and transmits them to the multiplex line (5), and also the signals from the multiplex line (5). Are separated and distributed to each subscriber circuit (SLC) (41).

The demultiplexing circuit (MDPX) (13) provided in the exchange (1) also connects the multiplexing line (5) and the accommodation terminal of the subscriber line (3) of the network (NW) (12) to each other. Connect to.

In the remote device accommodation type, the distance between the remote device (4) and each home (20) is much closer to that of the direct exchange accommodation system [Fig. 4 (b)], and the subscriber line ( 3)
The line length will be much shorter and the chances of being affected by the inductive signal will be much less.

Therefore, even if the impedance between the A line and the B line of the subscriber circuit (SLC) (41) and the ground is unbalanced, the influence of the induction signal as noise on the voice is much less. Become.

Based on the above consideration, the present invention promotes downsizing and economicization of the subscriber circuit. FIG. 1 is a diagram showing the principle of the present invention. FIG. 1 (a) shows the principle of the present invention (claim 1), and FIG. 1 (b) shows the principle of the present invention (claim 2). Figure (c) shows the principle of the present invention (claim 3), and Figure (d) shows the principle of the present invention (claim 4).
(e) shows the principle of the present invention (Claim 5), and FIG. 6 (f) shows the principle of the present invention (Claim 6).

In FIG. 1, 100 is a power feeding circuit,
300 is a subscriber line. The subscriber circuit is a subscriber line (3
00) is supplied with a direct current from the line B to the line A.

The power supply circuit (100) has a resistance value in a predetermined range for a DC signal and an impedance of a predetermined value or more for an audio signal.

[0022]

In the present invention (claim 1), the line B is
It connects with the positive power supply (V +) which supplies a higher voltage than the earth (E) via the above-mentioned electric power feeding circuit (100), and also connects the line A to the earth (E).

Therefore, a positive power source (V
The direct current flowing from the + to the ground (E) is supplied via the power supply circuit (100), the line B and the line A, and only one set of power supply circuits (100) is used.

Further, in the present invention (claim 2), the B line is connected to a positive power source (V +) which supplies a higher voltage than the ground (E), and the A line is connected via a power feeding circuit (100). And connect to the earth (E).

Therefore, a positive power source (V
The direct current flowing from the + to the ground (E) is supplied via the B line, the A line and the power supply circuit (100), and only one set of power supply circuits (100) is used.

Further, in the present invention (claim 3), the B line is connected to the ground (E) through the power feeding circuit (100),
Further, the line A is connected to a negative power source (V-) that supplies a lower voltage than the ground (E).

Therefore, the subscriber line (3) has the earth (E)
From the power supply circuit (100), the line B and the line A, a direct current flowing to the negative power source (V−) is supplied, and only one set of power supply circuits (100) is used.

Further, in the present invention (claim 4), the B line is connected to the ground (E) and the A line is connected to the feeding circuit (10).
0) to a negative power source (V-) that supplies a lower voltage than the ground (E).

Therefore, the subscriber line (3) is connected to the earth (E).
From the B line, the A line and the power supply circuit (100), a DC current flowing to the negative power source (V−) is supplied, and only one set of power supply circuits (100) is used.

Further, in the present invention (Claim 5), the B line is connected to the positive power source (V +) which supplies a higher voltage than the earth (E) through the power feeding circuit (100), and the A line. Is connected to a negative power supply (V−) that supplies a lower voltage than the ground (E).

Therefore, a positive power source (V
The direct current flowing from the + to the negative power source (V-) is supplied from the power supply circuit (100), the B line and the A line, and only one set of the power supply circuits (100) is used.

Further, in the present invention (claim 6), the B line is directly connected to the positive power source (V +) supplying a higher voltage than the ground (E), and the A line is connected to the power supply circuit (100). Via a negative power supply (V-) that supplies a lower voltage than the ground (E).

Therefore, a positive power source (V
The DC current flowing from the positive line (+) to the negative power source (V-) via the B line, the A line, and the power supply circuit (100) is supplied, and only one set of power supply circuits (100) is used.

Therefore, the subscriber line to be accommodated is sufficiently short,
When it is not necessary to consider the influence of the inductive signal, it is possible to complete the power feeding circuit as one set, and the miniaturization and economicization of the subscriber circuit can be greatly promoted.

[0035]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of the present invention will be described below with reference to the drawings. FIG. 2 is a diagram showing a power supply circuit according to an embodiment of the present invention (claims 1, 3, and 5), and FIG.
4 and 6) are diagrams showing a power supply circuit according to an embodiment. The same reference numerals denote the same objects throughout the drawings. The accommodation format of the target subscriber line (3) shall be the remote equipment accommodation format shown in Fig. 4 (b).

In FIG. 2, the power supply circuit in FIG.
(100) is the resistance (71₁) To (71_Four), Tran
Dista (72₁) And (72₂), Operational amplifier (73
₁), And a capacitor (74₁) Composed of B
Line side power supply circuit (7_B) And also in Fig. 3
The power supply circuit (100) in FIG.
_Five) To (71₈), Transistor (72₃)and
(72_Four), Operational amplifier (73₂), And capacitors
(74₂) Side power supply circuit (7)_A) To
It is equivalent.

First, an embodiment of the present invention (claim 1) is
This will be described with reference to FIG. In the embodiment of the present invention (claim 1), the first power source (V _X ) in FIG.
+), And the second power source (V _Y ) is ground (E).

In FIG. 2, when the analog telephone (2) is in the off-hook state and a loop circuit is formed inside, the first power source (V _X ) [= positive power source (V +)] to the B line side power feeding circuit ( DC current flowing to the second power source (V _Y ) [= ground (E)] via the resistor (71 ₁ ) and transistor (72 ₁ ) in 7 _B ), the line B and the line A, and the analog telephone ( 2) will be supplied.

At this time, the voltage generated across the resistor (71 ₁ ) is the same as that of the transistor (72 ₁ ) and the operational amplifier (73).
By the action of _1), the resistance (71 ₃₎ and (will be determined by the resistance ratio of 71 _4), as a result, the DC impedance of the line B side feeding circuit (7 _B) (Z _7B) is [R
₇₁₁ (R ₇₁₃ + R ₇₁₄ ) ÷ (R ₇₁₁ + R ₇₁₃ )], and it is found that the B-line side power supply circuit (7 _B ) realizes a constant resistance power supply circuit.

For a voice signal, a resistor (71 ₁ )
The voltage generated across both ends of the resistor (71 ₃ )
And a parallel circuit of a capacitor (74 ₁ ) and a resistor (71
₄ ) and the impedance ratio to
It turns out that the line side feeding circuit (7 _B ) realizes a high impedance for the voice signal.

Further, the transistor (72 ₂ ) and the third power source (V _Z ) are connected to the analog telephone (2) by the remote unit (4).
If installed close to, or an analog telephone (2)
When the loop resistance of (1) is significantly smaller than the standard value, the analog telephone (2) is prevented from being supplied with an excessive amount of direct current.

The third power source (V _Z ) supplies a voltage such that the transistor (72 ₂ ) maintains the cutoff state when the direct current supplied to the analog telephone (2) is less than or equal to the limiting current. ₂ ) is supplied to the base terminal and the direct current supplied to the analog telephone (2) exceeds the current limit, the transistor (7)
Since the emitter voltage of 2 ₂ ) decreases, the transistor (7
2 ₂ ) becomes conductive, and the voltage across the resistor (71 ₁ ) is limited by the third power supply (V _Z ). As a result, the direct current supplied to the analog telephone (2) is the limited current. Will be maintained.

[0043] As apparent from the above description, according to the embodiment of the present invention (claim 1), from the analog telephone (2), the first power source (V _X) [= positive supply (V +)], DC current flowing to the ground (E) is supplied via the B line side power supply circuit (7 _B ) and the B and A lines, and only one set of B line side power supply circuit (7 _B ) is used. Will not be
Compared with the conventional power supply circuit [see FIG. 5], the miniaturization and economic efficiency are greatly promoted.

Next, in the embodiment of the present invention (claim 3), the first power source (V _X ) in FIG. 2 is ground (E) and the second power source (V _Y ) is a negative power source (V-). ) Is the same as the embodiment of the present invention (Claim 1), the analog telephone (2) is connected to the B line side power supply circuit (7) from the earth (E).
_{Since a} DC current flowing to the negative power source (V−) is supplied via the lines _B ), B and A, detailed description thereof will be omitted.

In the embodiment of the present invention (claim 5), the first power source (V _X ) in FIG. 2 is the positive power source (V +) and the second power source (V _Y ) is the negative power source (V-). Other than that, there is no difference from the embodiment of the present invention (Claim 1), and the analog telephone (2) is provided with the B line side power supply circuit (7 _B ), the B line and the A line from the positive power source (V +). Via negative power supply (V-)
Since a direct current flowing through is supplied, detailed description will be omitted.

Next, an embodiment of the present invention (claim 2) will be described with reference to FIG. In the embodiment of the present invention (claim 2), the first power source (V _X ) in FIG.
+), And the second power source (V _Y ) is ground (E).

In FIG. 3, when the analog telephone (2) is in an off-hook state and a loop circuit is formed inside, the first power source (V _X ) [= positive power source (V +)] to the B line,
Transistor (72) in A line, A line side power supply circuit (7 _A )
₃₎ and through a resistor (71 ₅₎ the second power source (V _Y)
The direct current flowing in [= ground (E)] is supplied to the analog telephone (2).

At this time, the A-line side power supply circuit (7_A) DC
Impedance (Z_7A) Is the above-mentioned B line side power supply circuit
(7_B), [R₇₁₅(R₇₁₇ + R₇₁₈) ÷
(R₇₁₅+ R ₇₁₇)], And the A-line side power supply circuit (7_A)
Realizes a constant resistance power supply circuit.

For the audio signal, the A line side power supply circuit (7 _A ) is similar to the B line side power supply circuit (7 _B ) described above.
A high impedance is realized by the action of the capacitor (74 ₂ ).

Further, the transistor (72 ₄ ) and the fourth power source (V _W ) are the same as the transistor (72 ₂ ) and the third power source (V _Z ) in the above-mentioned B line side power feeding circuit (7 _B ) and are analog telephones. If (2) is installed in the immediate vicinity of the remote device (4), or if the loop resistance of the analog telephone (2) is significantly smaller than the standard value, the analog telephone (2) will receive more DC current than necessary. It serves to limit the supply.

As is clear from the above description, according to the embodiment of the present invention (Claim 2), the analog telephone (2) has the first power source (V _X ) [= positive power source (V +)] B
DC current flowing to the ground (E) is supplied via the line, the A line, and the A line side power supply circuit (7 _A ), and only one set of the A line side power supply circuit (7 _A ) is used. That means
Compared with the conventional power supply circuit [see FIG. 5], the miniaturization and economic efficiency are greatly promoted.

Next, in the embodiment of the present invention (claim 4), the first power source (V _X ) in FIG. 3 is ground (E) and the second power source (V _Y ) is a negative power source (V-). ) Is the same as the embodiment of the present invention (Claim 2), and the analog telephone (2) is connected to the B line, A line and A line from the earth (E).
Since a direct current flowing through the negative power source (V-) is supplied via the line side power supply circuit (7 _A ), detailed description thereof will be omitted.

In the embodiment of the present invention (claim 6), the first power source (V _X ) in FIG. 3 is the positive power source (V +) and the second power source (V _Y ) is the negative power source (V-). Other than that, there is no difference from the embodiment of the present invention (Claim 2), and the analog telephone (2) is provided with the B line, A line and A line side power supply circuit (7 _A ) from the positive power source (V +). Via negative power supply (V-)
Since a direct current flowing through is supplied, detailed description will be omitted.

It is to be noted that FIGS. 2 and 3 are merely examples of the present invention until now. For example, the configuration of the power supply circuit (100) is as follows.
The present invention is not limited to the B line side power supply circuit (7 _B ) and the A line side power supply circuit (7 _A ) shown in the figure, and many other modifications are considered. Does not change. Needless to say, the subscriber line accommodation type which is the subject of the present invention is not limited to the illustrated remote device accommodation type.

[0055]

As described above, according to the present invention, in the subscriber circuit, when the subscriber line to be accommodated is sufficiently short and it is not necessary to consider the influence of the inductive signal, one power feeding circuit is sufficient. This makes it possible to greatly reduce the size and cost of the subscriber circuit.

[Brief description of drawings]

FIG. 1 is a diagram showing the principle of the present invention, wherein FIG. 1 (a) shows the principle of the present invention (claim 1), and FIG. 1 (b) shows the principle of the present invention (claim 2). Figure (c) shows the principle of the present invention (Claim 3), Figure (d) shows the principle of the present invention (Claim 4), and Figure (e) shows the principle of the present invention (Claim 5). Shows the same figure
(f) shows the principle of the present invention (claim 6).

FIG. 2 is a diagram showing a power supply circuit according to an embodiment of the present invention (claims 1, 3, and 5).

FIG. 3 is a diagram showing a power supply circuit according to an embodiment of the present invention (claims 2, 4, and 6).

FIG. 4 is a diagram exemplifying the accommodation format of a subscriber line.
(a) shows the exchange direct accommodation type, and (b) shows the remote device accommodation type.

FIG. 5 is a diagram showing an example of a conventional power feeding system.

[Explanation of symbols]

1 Switch 2 Analog telephone 3,300 Subscriber line 4 Remote device 5 Multiple line 6 _A , 7 _A A line side power supply circuit 6 _B , 7 _B B line side power supply circuit 11, 41 Subscriber circuit (SLC) 12 Network (NW) ) 13, 42 Demultiplexing circuit (MDPX) 20 Home 71 Resistor 72 Transistor 73 Operational amplifier 74 Capacitor 100 Power supply circuit

Claims (6)

[Claims] 1. A line from a line B to a subscriber line (300)
A subscriber circuit for supplying a direct current in the direction of a line, wherein the B line has a resistance value of a predetermined range for a DC signal and an impedance of a predetermined value or more for a voice signal. ) Is connected to a positive power source (V +) that supplies a higher voltage than the ground (E), and the line A is connected to the ground (E). 2. A line from a line B to a subscriber line (300)
In a subscriber circuit that supplies a direct current in the direction of the line, the B line is connected to a positive power source (V +) that supplies a higher voltage than the ground (E), and the A line is connected to a predetermined DC signal. A power feeding system characterized by being connected to ground (E) via a power feeding circuit (100) having a resistance value in a range and having an impedance of a predetermined value or more with respect to an audio signal. 3. From line B to line A to the subscriber line (300)
A subscriber circuit for supplying a direct current in the direction of a line, wherein the B line has a resistance value of a predetermined range for a DC signal and an impedance of a predetermined value or more for a voice signal. ) Is connected to the ground (E), and the A line is connected to a negative power source (V−) that supplies a lower voltage than the ground (E). 4. A line from a line B to a subscriber line (300)
In a subscriber circuit supplying a direct current in the direction of the line, the line B is connected to the ground (E), and the line A has a resistance value in a predetermined range with respect to a direct current signal, and a voice signal. A power feeding system characterized by being connected to a negative power source (V-) that supplies a lower voltage than the ground (E) via a power feeding circuit (100) having an impedance of a predetermined value or more. 5. The line B to the line A to the subscriber line (300)
A subscriber circuit for supplying a direct current in the direction of a line, wherein the B line has a resistance value of a predetermined range for a DC signal and an impedance of a predetermined value or more for a voice signal. ) Is connected to a positive power source (V +) that supplies a higher voltage than the ground (E), and the A line is connected to a negative power source (V-) that supplies a lower voltage than the ground (E). A power supply method characterized in that 6. A subscriber line (300) to a line B to A
In a subscriber circuit that supplies a direct current in the direction of the line, the B line is connected to a positive power source (V +) that supplies a higher voltage than the ground (E), and the A line is connected to a predetermined DC signal. It is connected to a negative power supply (V-) that supplies a lower voltage than the earth (E) through a power supply circuit (100) having a resistance value in the range and having an impedance of a predetermined value or more for an audio signal. A power supply method characterized in that