An impedance blocking filter circuit is provided for use in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances above 20 KHz due to the customer's terminal equipment from an ADSL network unit and/or home networking interface unit. The filter circuit includes first, second, and third inductors connected in series between a first input terminal and a first common point. A first resistor has its one end connected also to the first common point and its other end connected to a first output terminal. Fourth, fifth and sixth inductors are connected in series between a second input terminal and a second common point. A second resistor has its one end also connected to the second common point and its other end connected to a second output terminal. A capacitor has its ends connected across the first and second common points. In other aspects, the filter circuit also includes switching means for eliminating shunt additive capacitance, correction circuit means reducing significantly return loss, and switch suppression circuit means for eliminating transients.
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0. 39. A telecommunication impedance blocking filter circuit, comprising:
at least one input terminal;
at least one output terminal;
a first filter stage disposed in electrical series between said at least one input and output terminals;
a second filter stage disposed in electrical series with said first filter stage, said second stage comprising a capacitor and switch disposed in series with at least one another; and
a suppression circuit disposed electrically between said at least one input terminal and said second filter stage, said suppression circuit being adapted to at least mitigate voltage transients generated through actuation of said switch from being fed back to said at least one input terminal.
0. 35. A telecommunication impedance blocking filter circuit, comprising:
at least one input terminal;
at least one output terminal;
a first filter stage disposed in electrical series between said at least one input and output terminals;
a second filter stage disposed in electrical series with said first filter stage, said second stage comprising a capacitor and switch disposed in series with at least one another; and
a suppression circuit disposed in electrical series with said first and second filter stages, said suppression circuit being adapted to suppress voltage transients occurring within said filter circuit as the result of actuation of said switch during at least one of an on-hook to off-hook, or off-hook to on-hook, transient.
0. 18. A telecommunication impedance blocking filter circuit, comprising:
at least one input terminal;
at least one output terminal;
a first filter stage disposed in electrical series between said at least one input and output terminals;
a second filter stage disposed in electrical series with said first filter stage, said second stage comprising a capacitor and switch disposed in series with at least one another;
a third filter stage disposed in electrical series with said second filter stage; and
a fourth filter stage disposed in electrical series with said third filter stage, said fourth stage being specifically adapted to reduce return loss;
wherein at least one of said first through fourth stages comprises a suppression circuit.
0. 38. A telecommunications circuit comprising:
first and second circuit paths disposed substantially in electrical parallel to one another between respective sets of inputs and output terminals, said first and second circuit paths each comprising a plurality of inductive elements;
a capacitor and switch disposed in series with at least one another, said capacitor and switch being disposed electrically between said first and second circuit paths; and
a suppression circuit disposed electrically between said first and second circuit paths, said suppression circuit being adapted to suppress voltage transients occurring within said filter circuit as the result of actuation of said switch during at least one of an on-hook to off-hook, or off-hook to on-hook, transient.
0. 45. A telecommunication impedance blocking filter circuit, comprising:
a plurality of input terminals;
a plurality of output terminals;
a first filter stage disposed in electrical series between said at input and output terminals;
a second filter stage disposed in electrical series with said first filter stage, said second stage comprising a capacitor and switch disposed in series with at least one another; and
a suppression circuit disposed electrically between said first and second filter stages, said suppression circuit being adapted to at least mitigate voltage transients generated through actuation of said switch due to connected equipment transients from being fed back to said input terminals in order to mitigate the effect of said transients on external equipment connected to said input terminals.
0. 28. A telecommunications filter circuit, comprising:
first and second input terminals;
first and second output terminals;
at least first and second inductors disposed in electrical series between said first input and first output terminals;
at least third and fourth inductors disposed in electrical series between said second input and second output terminals;
at least one switch inductively coupled to at least one of said first and third inductors, said switch disposed in electrical series with at least one capacitor between first and second common points, said common points being in electrical series with said first and second output terminals, respectively; and
a suppression circuit coupled between said common points and said input terminals, said suppression circuit being adapted to at least mitigate voltage transients generated through actuation of said at least one switch due to connected equipment transients from being fed back to said input terminals.
0. 1. An impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances from above 20 KHz due to the customer's terminal equipment from an ADSL network unit and/or home networking interface unit, said filter circuit comprising:
first and second third inductors connected in series between a first input terminal and a first common point;
said first inductor having its one end connected to said first input terminal and its other end connected to one end of said second inductor, said second inductor having its other end connected to said first common point;
third and fourth inductors connected in series between a second input terminal and a second common point;
said third inductor having its one end connected to said second input terminal and its other end connected to one end of said fourth inductor, said fourth inductor having its other end connected to said second common point;
first switching means having a first end and a second end and being responsive to DC loop current for electrically connecting said first end to said second end;
a first capacitor having a first end connected to said first common point and a second end connected to said first end of said switching means, said second end of said switching means being connected to said second common point;
a fifth inductor having a first end connected to said first common point and a second end connected to a first output terminal, and a sixth inductor having a first end connected to said second common point and a second end connected to a second output terminal;
second switching means having a first end and a second end and being responsive to said DC loop current for electrically connecting said first end to said second end;
a second capacitor having a first end connected to said sixth inductor at a first node and a second end connected to said first end of said second switching means, said second end of said second switching means being connected to said fifth inductor at a second node;
switch suppression circuit means interconnected between said first and second common points for preventing transients caused by actuation of said first and second switching means from being fed back into the incoming telephone lines; and
correction circuit means interconnected between said first and second nodes and said output terminals for significantly reducing return loss caused by inductive impedance when the customer's terminal equipment goes off-hook.
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0. 10. An impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances from above 20 KHz due to the customer's terminal equipment from an ADSL network unit and/or home networking interface unit, said filter circuit comprising:
first and second third inductors connected in series between a first input terminal and a first common point;
said first inductor having its one end connected to said first input terminal and its other end connected to one end of said second inductor, said second inductor having its other end connected to said first common point;
third and fourth inductors connected in series between a second input terminal and a second common point;
said third inductor having its one end connected to said second input terminal and its other end connected to one end of said fourth inductor, said fourth inductor having its other end connected to said second common point;
transistor switching means interconnected between said first and second common points and being responsive to DC loop current for eliminating shunt capacitance caused by other filter circuits connected to on-hook telephone sets;
a fifth inductor having a first end connected to said first common point and a second end connected to a first output terminal, and a sixth inductor having a first end connected to said second common point and a second end connected to a second output terminal; and
correction circuit means interconnected between said fifth and sixth inductors and said output terminals for significantly reducing return loss caused by inductive impedance when the customer's terminal equipment goes off-hook.
0. 11. An impedance blocking filter circuit as claimed in
0. 12. An impedance blocking filter circuit as claimed in
0. 13. An impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances from above 20 KHz due to the customer's terminal equipment from an ADSL network unit and/or home networking interface unit, said filter circuit comprising:
first and second third inductors connected in series between a first input terminal and a first common point;
said first inductor having its one end connected to said first input terminal and its other end connected to one end of said second inductor, said second inductor having its other end connected to said first common point;
third and fourth inductors connected in series between a second input terminal and a second common point;
said third inductor having its one end connected to said second input terminal and its other end connected to one end of said fourth inductor, said fourth inductor having its other end connected to said second common point;
first switching means having a first end and a second end and being responsive to DC loop current for electrically connecting said first end to said second end;
a first capacitor having a first end connected to said first common point and a second end connected to said first end of said switching means, said second end of said switching means being connected to said second common point; and
switch suppression circuit means interconnected between said first and second common points for preventing transients caused by actuation of said first switching means from being fed back into the incoming telephone lines.
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The present invention is a continuation-in-part application based on prior Ser. No. 09/370,137 filed on Aug. 9, 1999, which is, in turn, a continuation-in-part application based on parent application Ser. No. 09/195,522 filed on Nov. 19, 1998, and entitled “Impedance Blocking Filter Circuit.” The present reissue application is a continuation application of prior application Ser. No. 10/408,030 filed Apr. 3, 2003 of the same title, which is a reissue of U.S. Pat. No. 6,212,259 issued Apr. 3, 2001 of the same title, which is a continuation-in-part application based on prior Ser. No. 09/370,137 filed on Aug. 9, 1999, now U.S. Pat. No. 6,181,777, which is, in turn, a continuation-in-part application based on parent application Ser. No. 09/195,522 filed on Nov. 19, 1998, now U.S. Pat. No. 6,188,750.
1. Field of the Invention
This invention relates generally to telecommunication systems and more particularly, it relates to an impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines from a telephone company's central office (C.O.) and subscriber or customer telephone equipment such as a telephone set located at a subscriber's premises so as to unconditionally block telephone impedance above 20 KHz.
2. Description of the Prior Art
The prior art appears to be best exemplified in the following U.S. Letters Patent which were developed in a search directed to the subject matter in this application:
4,613,732
4,823,383
4,742,541
5,642,416
4,743,999
5,802,170
In U.S. Pat. No. 4,823,383 issued to Cardot et al. on Apr. 18, 1989, there is disclosed a protection device for terminal equipment on telephone subscriber premises which includes a voltage surge protection circuit and/or a filter for providing protection against radio frequencies and interference. The filter is comprised of series inductors L1, L2, L3 and L5 interconnected between terminals E1 and S1 and series inductors L′1, L′2, L4 and L′5 interconnected between terminals E2 and S2. A capacitor C5 is connected between the junctions of the inductors L2, L3 and the inductors L′2, L4. The surge protection circuit includes thermistors TH1, TH2 and voltage limiters D1-D3.
In U.S. Pat. No. 5,802,170 issued to Smith et al. on Sep. 1, 1998, there is disclosed a customer bridge module for connecting telephone company wiring and subscriber telephone wiring in a telephone network interface apparatus. In one embodiment, the customer bridge module includes overcurrent protection and an RFI filter. The overcurrent protection is formed by positive temperature coefficient resistors 220, 222 and inductors. The RFI filter is formed by inductors 224a-224c, 226a-226c and capacitors 236a-236c. The inductors and capacitors are used to form a multi-pole low pass filter.
In U.S. Pat. No. 5,642,416 issued to Hill et al. on Jun. 24, 1997, there is disclosed an electromagnetic interference by-pass filter which suppresses RF noise currents conducted over the tip and ring leads to a telephone line-powered instrument. The filter includes first and second inductors 51, 53 and first and second capacitors 41, 43.
It is generally well-known these days that many telephone subscribers or customers also have a personal computer located on their premises. At times, the computer user receives ADSL (an acronym for Asymmetric Digital Subscriber Line) signals from the Internet over the same telephone lines via an Internet Server Provider (ISP). In order to increase the speed of downloading of information from the Internet, an ADSL network interface is typically purchased and installed between the incoming telephone lines and the user's computer. However, since one or more telephone subscriber terminal equipment such as telephone sets, facsimile machines and/or answering devices are also connected to the same incoming telephone lines via internal house wiring, ADSL interference problems may be caused by the terminal equipment which can significantly limit or reduce the data rate. In one situation, it has been experienced that the change of state from “on-hook” to “off-hook” of the telephone equipment and sometimes the telephone terminal equipment even being “on-hook” can create a resonance effect to occur so as to drop the impedance value to less than 10 Ω(Ohms) at a frequency as high as 500 KHz.
Accordingly, it would be desirable to provide an impedance blocking filter circuit for connection to the telephone terminal equipment causing the erratic input impedances. The impedance blocking filter circuit of the present invention is of a modular design so as to be easily connected in series with the offending telephone terminal equipment. The impedance blocking filter circuit blocks unconditionally any telephone impedances (e.g., open, short, capacitive, inductive, resonant, or any combination thereof) above the frequency of 20 KHz.
Accordingly, it is a general object of the present invention to provide an impedance blocking filter circuit which effectively and efficiently eliminates ADSL interference caused by telephone terminal equipment.
It is an object of the present invention to provide an impedance blocking filter circuit for connection to telephone terminal equipment causing the erratic input impedances.
It is another object of the present invention to provide an impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedance above 20 KHz due to the customer's terminal equipment from an ADSL network interface unit and/or home networking interface unit.
It is still another object of the present invention to provide an impedance blocking filter circuit which is of a modular design so as to be easily connected in series with the offending telephone terminal equipment.
It is still yet another object of the present invention to provide an impedance blocking filter circuit which is comprised of six inductors, two resistors, and a capacitor.
In accordance with a preferred embodiment of the present invention, there is provided an impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances above 20 KHz due to the customer's terminal equipment from an ADSL network interface unit and/or home networking interface unit. The filter circuit includes first, second and third inductors connected in series between a first input terminal and a first common point. The first inductor has its one end connected to one end of the second inductor. The second inductor has its other end connected to one end of the third inductor. The third inductor has its other end connected to the first common point. A first resistor has its one end also connected to the first common point and its other end connected to a first output terminal.
The filter circuit further includes fourth, fifth and sixth inductors connected in series between a second input terminal and a second common point. The fourth inductor has its one end connected to the second input terminal and its other end connected to one end of the fifth inductor. The fifth inductor has its other end connected to one end of the sixth inductor. The sixth inductor has its other end connected to the second common point. A second resistor has its one end also connected to the second common point and its other end connected to a second output terminal. A capacitor has its one end connected to the first common point and its other end connected to the second common point.
The foregoing applies specifically to the disclosure of the parent application Ser. No. 09/195,522. A third embodiment of an impedance blocking filter circuit of the present invention added by way of this continuation-in-part application is quite similar to the schematic diagram of
In addition, a fourth embodiment of an impedance blocking filter circuit of the present invention also added by way of this continuation-in-part application includes all of the components of the third embodiment and further has added successively seventh and eight inductors L7, L8; a second capacitor C2 and a second reed switch K2 connected in series; and ninth and tenth inductors L9, L10.
In a fifth embodiment, there is provided an impedance blocking filter circuit which is quite similar to the schematic circuit diagram of
In a sixth embodiment, there is provided an impedance blocking filter circuit which includes all of the components of the fifth embodiment and further has added successively seventh and eight inductors L7,L8; a second capacitor C2 and a second reed switch K2 connected in series; and ninth and tenth inductors L9,L10. The second reed switch K2 is also housed within the multi-sectioned bobbin structure.
A seventh embodiment of an impedance blocking filter circuit of the present invention is added by way of this second continuation-in-part application which is quite similiar to the filter circuit of
Further, an eighth embodiment of an impedance blocking filter circuit of the present invention also added by way of this second continuation-in-part is substantially identical to the third-order filter circuit of
In a ninth embodiment, there is provided an impedance blocking filter circuit which is quite similar to the schematic circuit diagram of
These and other objects and advantages of the present invention will become more fully apparent from the following detailed description when read in conjunction with the accompanying drawings with like reference numerals indicating corresponding parts throughout, wherein:
FIG. 10(a) is a top plan view of a dual winding inductor device housing one or two reed switches for use in the filter circuits of
FIG. 10(b) is a side elevational view of the dual winding inductor device of FIG. 10(a);
FIG. 11(a) is a top plan view of a current sensor unit for housing a single inductor and a single reed switch for alternate use in the filter circuits of
FIG. 11(b) is a side elevational view of the current sensor unit of FIG. 11(a);
FIG. 14(a) is a side view of a multi-sectioned bobbin structure for use in the filter circuits of
FIG. 14(b) is schematic diagram of the multi-sectioned bobbin structure of FIG. 14(a);
FIG. 16(a) is an end view of an alternate deal winding inductor device housing two reed switches;
FIG. 16(b) is a side elevational view of the dual winding inductor device of FIG. 16(a);
Referring now in detail to the drawings, there is illustrated in
The central office 12 includes a telephone office switch 20 and an Internet Service Provider (ISP) 22. The telephone office switch 20 is used to send voice signals via a low-pass filter 24 and a surge protector 26 to the telephone line 16. The ISP 22 transmits ADSL data signals to a modem 28 which are then sent to the telephone lines 16 via a high-pass filter 30 and the surge protector 26. It should be understood that the voice signals from the telephone office switch 20 and the ADSL data signals from the ISP 22 can be transmitted simultaneously to the telephone lines 16. Further, the voice signals (speech) are in the frequency band between 300 and 3400 Hz, and the ADSL data signals are in the frequency band between 20 KHz and 1.1 KHz.
The subscriber's premises 14 includes a Network Interface Device (NID)/surge protector unit 32 which is connected to the incoming telephone lines 16 on its input side and is connected to the subscriber's internal wiring or house wiring 34 on its output side via a demarcation RJ-11 jack and plug unit 36. As can be seen, the subscriber's premises further includes a number of terminal equipment such as a plurality of telephone sets 40. At times, the computer user will be downloading information to a personal computer 38 from the Internet by receiving ADSL data signals transmitted by the ISP 22.
In order to optimize the downloading of this information from the Internet, the user can purchase and install an ADSL network interface unit 42 for connection between the computer 38 and a RJ-11 jack and plug unit 44. The ADSL network interface unit 42 includes a high-pass filter 41 connected to the RJ-11 unit 44 and an internal modem 43 connected to the computer 38. The RJ-11 unit 44 is connected to the house wiring 34 for receiving the ADSL signals from the telephone lines 16. However, it will be observed that the plurality of telephone sets 40 are also connected to the same house wiring 40 via RJ-11 units 46, 48 and 50, respectively.
If it were not for the impedance blocking filter circuits 18 in the present invention, the output impedance from each of the telephone sets 40 would be connected in parallel with the input impedance of the ADSL unit 42. Since the output impedances from the telephone sets are subject to wide variations due to, for example, changing from “on-hook” to “off-hook” so as to present either an open, a short, capacitive, inductive, resonant, or any combination thereof at frequencies above 20 KHz, this erratic impedance can significantly affect the rate of the ADSL data signals being received by the computer 38 via the ADSL network interface unit 42.
Therefore, the main purpose of the impedance blocking filter circuit of the present invention is to isolate the terminal equipment (telephone sets) impedances from the ADSL unit 42 and the house wiring 34 so as to eliminate degradation of the performance of the ADSL unit 42. Further, the impedance blocking filter circuit serves to attenuate the ADSL data signal from being received by the telephone sets 40 in order to prevent non-linear conversion to voice band signals. Moreover, to facilitate the installation required by the customer, the filter circuit is contained in the modular housing 18.
As can best be seen from
In
The inductors L5, L3, L1 and the resistor R1 are connected in series between the first or tip input terminal 66 and the first or tip output terminal 70. Similarly, the inductors L6, L4, L2 and the resistor R2 are connected in series between the second or ring input terminal 68 and the second or ring output terminal 72. The inductors L5 and L6 are each preferably formed of a ferrite toroid. The inductors L3 and L4 have the same inductance values, and the inductors L1 and L2 have the same inductance values. The inductors L1 and the first resistor R1 are connected together at a common point A and to one side of the capacitor C1. The inductor L2 and the second resistor R2 are connected together at a common point B and to the other side of the capacitor C1. The resistors R1 and R2 also have the same values.
As previously pointed out, the primary purpose of the impedance blocking filter circuit 59 is to block the impedances from the telephone set at above the frequency of 20 KHz from reaching the house wiring 34, thereby preventing adverse performance of the ADSL network unit 42 (FIG. 1). In particular, the ADSL data signals being in the frequency range of 20 KHz and 1.1 MHz are mainly blocked by the inductors L1 and L2. However, it has been experienced that some telephone sets have an input capacitance of less than 5 nf which can cause resonant impedances to occur within the ADSL band. In order to eliminate this undesirable effect, the capacitor C1 is used to lower any resonance into an acceptable dead band at around the 10 KHz frequency. Further, the capacitor C1 also provides additional attenuation of the ADSL signals so as to prevent driving the telephone impedance into a non-linear region and converting the high frequency ADSL signals into audible signals which can be heard by the subscriber or converted to another ADSL band and cause ADSL interference. While they may still exist other minor resonances in the telephone set in the frequency range of between 20 KHz and 60 KHz, their undesirable effect is significantly reduced by the resistors R1 and R2 which produce a de-Q effect. It should be noted that the inductors L1 and L2 are formed as separate inductors so as to avoid longitudinal impedance problems as well as blocking differential impedances.
Since the inductors L1 and L2 have their own frequency limitations (e.g., self-resonant frequency), the inductors L3 and L4 are provided so as to block the telephone impedances in the frequency band of 1 MHz to 20 MHz. These inductors L3, L4 are necessary when phoneline home networking interface units (
For completeness in the disclosure of the above-noted filter circuit but not for purposes of limitation, the following representative values and component identifications are submitted. These values and components were employed in a filter circuit that was constructed and tested, and which provides high quality performance.
PART
TYPE or VALUE
L1, L2
10 mH
L3, L4
220 μH
L5, L6
ferrite toroid, 75 μH
C1
20 nf
R1, R2
22 Ω
With these above values being used, the input impedance of the impedance blocking filter circuit 59 was plotted for various telephone equipment impedances (e.g., open, short, capacitive, inductive, resonant, or a combination of these conditions) as a function of frequency and is illustrated in FIG. 5. As can be seen from the various curves, the input impedance across the input terminals 66, 68 of the impedance blocking filter circuit 59 for any telephone impedances connected across its output terminals 70, 72 is equal to or greater than 2 K Ohms at frequencies above 40 KHz.
The impedance blocking filter circuit 59 of
Based upon tests connected on the third-order filter circuit of
While the filter circuit of
In order to overcome this current transient problem, the inventors have developed fast current limiting protection circuitry 74 for providing protection against the “off-hook” transients. In
In use, the current limiting protection circuitry 74 replaces the resistors R1 and R2 of FIG. 3. The first and second input terminals 76, 80 of the protection circuitry 74 are connectable to the common points A and B of
In normal on-hook operation, the transistors Q1 and Q2 are rendered conductive and have an on-resistance value of about 10 Ohms. When the telephone set goes “off-hook” into high ringing voltage, the gate-to-source voltage of the forward conducting FET will become more negative due to the resistors R1a, R2a. As a result, the resistance of the transistors Q1, Q2 will go very high which will limit the current spikes to approximately 70-100 mA. The transistor Q1 serves to limit the current flowing in a first direction, and the transistor Q2 serves to limit the current flow in a reverse direction. Further, the varistors RV1, RV2 defining transient protection means function to clamp transients caused by lightning and power shorts from damaging or destroying the FETs Q1, Q2.
In view of continuing increased use of home computers and the high demand for accessing of information from the Internet in the last decade or so, many of the subscribers will be multi-PC homes. As shown in
In order to solve this problem, the inventor has developed a home network demarcation filter 84 as shown in dotted lines in
From the foregoing detailed description, it can thus be seen that the present invention provides an impedance blocking filter circuit used in telecommunication systems for interconnecting between incoming telephone lines and customer's terminal equipment so as to unconditionally block impedances above 20 KHz due to the customer's terminal equipment from an ADSL network interface unit and/or home networking interface unit. The impedance blocking filter circuit is comprised of six inductors, two resistors, and a capacitor.
While the second-order impedance blocking filter 59 of FIG. 3 and the third-order impedance blocking filter 59a of
The shunt capacitance problem is caused by the added capacitance from all of the filter circuits connected to the on-hook phones. The return loss problem is due to the fact that the series inductances of the impedance blocking filter circuit connected to the telephone set going “off-hook” will cause a resonance to occur in the frequency range of 2-5 KHz with the total capacitance seen, which is equal to the sum of the line capacitance plus the capacitance from the filter circuits. Further, as the total capacitance is increased this will also cause a lower resonant frequency which will create a phase shift so as to unbalance the telephone hybrid. As a result, the side tone level of the “off-hook” telephone set to increase.
In order to overcome this problem, there is provided in
In particular, the reed switch K1 connected in series with the capacitance C1 is connected between the common points A and B. Further, the first tank circuit TC1 is comprised of a first winding inductor W1, a capacitor C3, and a resistor R3 all connected together in parallel and between the common point A and the output tip terminal 70. Similarly, the second tank circuit TC2 is comprised of a second winding inductor W2, a capacitor C4, and a resistor R4 all connected together in parallel and between the common point B and the output ring terminal 72. In addition, there provided optionally a metal-oxide varistor D1 connected in series with the capacitor C1 and in parallel with the reed switch K1. The varistor D1 serves to protect the capacitor C1 from being damaged by transients when the telephone set is in the on-hook condition.
In use, when a telephone set goes “off-hook” DC loop current will flow which creates a DC magnetic field in the first and second winding inductors W1,W2. This will cause only the reed switch K1 of the filter circuit 59b connected to the “off-hook” telephone set to become actuated or closed by the DC magnetic field. As a consequence, the shunt additive capacitances from all of the filter circuits connected to the “on-hook” phones have been eliminated.
Moreover, the first winding inductor W1 and the capacitor C3 of the first tank circuit TC1 will cause a resonance to occur at the frequency of about 2 KHz. The impedance of the first tank circuit TC1 above the resonant frequency will appear as a capacitive reactance, which will substantially cancel the inductive reactance of the filter circuit 59b. The resistor R3 sets the Q or the slope of the resistance so as to best match the effects of the inductive impedance of the filter circuit. In this manner, the return loss at the “off-hook” phone set is significantly reduced, thereby increasing the side tone level of the telephone set. Similarly, the second winding inductor W2, the capacitance C4, and the resistor R4 of the second tank circuit TC2 operate in an identical manner to first winding inductor W1, the capacitor C3, and the resistor R3 of the first tank circuit TC1.
In
Referring still to
Further, an inductor L9 and an inductor L10 are added successively so as to produce a fifth-order filter circuit. Specifically, the inductor L9 is interconnected between the inductor L7 at the common point C and the first tank circuit TC1. The inductor L10 is interconnected between the inductor L8 at the common point D and the second tank circuit TC2.
In addition, a thermo-fuser F1 may be optionally connected in series the inductors L5, L3, L1, L7, L9 and the tank circuit TC1 which are arranged between the input tip terminal 66 and the output tip terminal 70. For example, the thermo-fuse F1 may be electrically interconnected between the input tip terminal 68 and the inductor L5. Typically, the thermo-fuse F1 is located physically adjacent to on e the inductors or the resistor in order to sense the highest temperature within the filter circuit. The fuse F1 provides a safety feature and will open when the sensed temperature of the filter circuit exceed a specified trip temperature. The fuse functions as a safety protection means for preventing the filter circuit from overheating and causing a fire due to a power cross on the phone lines.
In FIG. 10(a), there is shown a top plan view of a dual winding inductor device T1 for use in the filter circuits of
In FIG. 11(a), there is depicted a top plan view of a current sensor unit CS for use in the filter circuits of
In
In
Referring still to
In FIG. 14(a), there is shown a side view of a wiring bobbin structure T2 having multiple sections S1-S4 for use in the circuits of
The inventor has designed purposely the bobbin structure T2 to include the narrow section S1(S3) on which is wound the higher frequency of the coil (e.g., inductor L3,L4) since there will be less winding capacitance so as to obtain a maximum useful frequency range. Further, by dividing the bobbin structure into a plurality of sections the beginning of the tip(ring) winding TW(RW) on pin 1 (pin 5) will be farther removed from the end of the tip (ring) winding on pin 4 (pin 8). As result, the interwinding capacitance will be reduce, thereby increasing the useful frequency range of the coil. The first reed switch K1 with pins 2 and 7 is disposed within the center of the bobbin structure T2 so as to be actuable by the windings TW, RW. Further, the second reed switch K2 with pins 3 and 6 may also be formed with the center of the bobbin structure and actuated by the same winding TW, RW.
While the impedance blocking filter circuit 59c of
In order to solve this switching transient problem, there is provided in
In use, when a telephone set goes “off-hook” DC loop current will flow which creates a DC magnetic field in the first and second inductors W1, W2. This will cause the reed switches K1, K2 of the filter circuit 59f connected to the “off-hook” telephone set to become actuated or closed by the DC magnetic field. As a result, transient spikes will be created. The capacitors C5 of the instant switch suppression circuit 74 will attenuate any voltage spikes that are generated. Further, the inductors L13, l14 serve to limit the maximum current which can flow in the reed switches K1, K2. In this fashion, the voltage spikes are prevented from being fed back into the line side of the phone set, thereby eliminating any potential interruption in the ADSL modem.
In FIG. 16(a), there is shown an end view of an alternate dual winding inductor device T1a which may be used instead of the inductor device T1 of FIG. 10(a). FIG. 16(b) is a side elevational view of the dual winding inductor device of FIG. 16(a). As will be noted, the inductor device T1a includes a ferrite core 114 formed of a first winding W1a and a second winding W2a having a pair of reed switch slots 116, 118. Reed switches K1a, K2a are placed initially on a printed circuit board 120. Next, the ferrite core 114 is disposed over the reed switches so that the leads thereof fit into the ferrite slots 116, 118. The leads of the windings and reed switches are then soldered so as to securely retain the inductor device T1a on top of the printed circuit board 120.
In
Specifically, the transistor Q1 has its collector connected to a common point F, its base connected to the common point F via the varistor D3, and its emitter connected to the common point E. The transistor Q2 has its collector also connected to the common point F, its base connected also to the common point E, and its emitter connected to the common point B. The resistor R5 is connected in parallel with the capacitor C6 and is interconnected between the the common points B and E. The varistor D4 is connected between the base and emitter junctions of the transistors Q1 and Q2. The capacitor C6 is connected between the common point A and the common point B. The capacitor C1 is connected between the common points A and F.
In use, when a telephone set goes “off-hook” DC loop current of 20 ma will cause one of the transistors Q1 of Q2 to be rendered conductive dependent upon the direction of the current. The collector of the transistor Q1 or Q2 can actually source or sink current due to the AC ringing and voice band signals. The reverse collector current capacity actually flows through the base-collector junction of the transistor. While the varistor D4 is shown as one device, it should be understood that the same may be formed of two forward-biased diodes disposed in each direction so as to protect the base-emitter junctions of the transistors Q1 and Q2. The varistor D3 also serves to protect the transistors Q1 and Q2 and can have a rating as low as 6-8 volts so as to prevent clamping of audio signals or as high as 200 volts so as to prevent clamping of ringing signals. The capacitor C5 serves to attenuate any voltage spikes that may appear. The resistor R5 is used to set the threshold current for turning on the transistors Q1 and Q2. The capacitor C6 serves to bypass the transistors in order to produce good longitudinal balance and to prevent pulsing during ringing and dialing.
In
While there has been illustrated and described what is at present considered to be a preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made, and equivalents may be substituted for elements thereof without department from the true scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the central scope thereof. Therefore, it is intended that this invention not be limited to the particular embodiment disclosed as the best mode contemplated for carrying out the invention, but that the invention will include all embodiments falling within the scope of the appended claims.
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