Double duty capacitor circuit and method

A method and circuit in which two filters connected to different inputs that do not operate at the same time share a common capacitor to thereby reduce the number of capacitors needed for the circuit. A filter that is connected to an input that is not operating may be selectively disabled by connecting a resistor form the disabled filter and the common capacitor to ground when the other input is being operated. The method and circuit find application in a telephone system in which a filter connected to a subscriber line interface circuit (SLIC) and a filter connected to a telephone system circuit that does not operate at the same time as the SLIC share a common capacitor.

BACKGROUND OF THE INVENTION 
The present invention relates to methods and circuits for selectively 
enabling one of two filters, and more particularly to a method and circuit 
for a telephone system in which two filters connected to different inputs 
share a common capacitor to thereby reduce the number of capacitors needed 
for the telephone system. 
Many systems may include passive filters that have resistors and 
capacitors, such as low pass and band pass filters. For example, and with 
reference to FIG. 1, an input 12 may provide a signal to filter 14 having 
a resistor R1 and a capacitor C1. The input signal is applied between node 
N1 and ground, and the filtered output appears at node N2. A separate 
filter 14 has heretofore been required for each input and output pair. 
When the system includes an integrated circuit (IC) the resistors in the 
filters may be integrated into the IC. However, the filters' capacitors, 
if larger than a few tens of picofarads, are discrete components that are 
not integrated into the IC Each filter may require one or more such 
capacitors and thus systems having a plurality of filters each with 
discrete component capacitors, such as audio frequency circuits in 
telephone systems, may find that considerable real estate is used by the 
discrete component capacitors. Further, discrete components may be costly 
and increase the time needed for assembly. 
Some of the systems include a plurality of circuits that are not operated 
at the same time so that the filter(s) associated with the circuits are 
not operated at the same time. For example, in a telephone system the ring 
trip detection circuit (RTDC) and the subscriber line interface circuit 
(SLIC) are not operated at the same time. The RTDC is connected to a 
subscriber's telephone line to determine when the telephone has been 
answered, but is disconnected form the line, and the SLIC is connected to 
the line, once the telephone has been answered. The SLIC and the RTDC each 
has a separate low pass filter, and it is desirable to reduce the number 
of components in the filters. 
Accordingly, it is an object of the present invention to provide a novel 
method and circuit with filters connected to inputs that operate at 
different times that obviates the problems of the prior art. 
It is another object of the present invention to provide a novel method and 
circuit in which filters connected to inputs that operate at different 
times share a common capacitor. 
It is yet another object of the present invention to provide a novel method 
and circuit in which two filters share a common capacitor and in which a 
resistor in one filter and the common capacitor are grounded when the 
other filter is operating. 
It is still another object of the present invention to provide a novel 
method and circuit in which two filters connected to circuits that do not 
operate concurrently share a common capacitor and in which a resistor in a 
filter in the circuit that is not operating is grounded when the other 
circuit is operating. 
It is further object of the present invention to provide a novel method and 
circuit for operating a telephone system in which a filter in a SLIC and a 
filter in a RTDC share a common capacitor and in which a resistor in the 
SLIC filter is grounded to disable the SLIC filter when the RTDC is 
operating, and in which a resistor in the RTDC filter is grounded to 
disable the RTDC filter when the SLIC is operating. 
These and many other objects and advantages of the present invention will 
be readily apparent to one skilled in the art to which the invention 
pertains from a perusal of the claims, the appended drawings, and the 
following detailed description of the preferred embodiments.

DESCRIPTION OF PREFERRED EMBODIMENTS 
With reference now to FIG. 2, an embodiment of the present invention may 
include two filters, each connected to a separate input, that share a 
common capacitor. A first input 20 may provide a signal to first filter 22 
that includes resistor R.sub.A and capacitor C.sub.COMMON. A second input 
24 may provide a signal to second filter 26 that includes resistor R.sub.B 
and the capacitor C.sub.COMMON. Inputs 20 and 24 do not operate (e.g., 
provide input signals) at the same time and thus do not provide output 
signals to their respective outputs at the same time. As illustrated in 
FIG. 2, the outputs need not be common. 
When input 20 is operating and filter 22 is to operate therewith, switch 
SW.sub.A may be closed and switch SW.sub.B opened. When the switches are 
in this configuration, resistor R.sub.B is grounded so that filter 26 is 
disabled, and capacitor C.sub.COMMON is grounded so that filter 22 is 
operable. Conversely, when input 24 is operating and filter 26 is to 
operate therewith, switch SWB may be closed and switch SW.sub.A opened. 
Resistor R.sub.A is grounded so that filter 22 is disabled, and capacitor 
C.sub.COMMON is grounded so that filter 26 is operable. 
FIG. 3 illustrates another embodiment of the invention in which a 
double-pole switch SW.sub.AB is used (the arrangement of components is 
depicted differently in FIG. 3 although the components are connected as in 
the embodiment of FIG. 2). 
With reference now to FIG. 4, the present invention may find application in 
a telephone system that includes a subscriber telephone 30 connected to a 
subscriber line interface circuit (SLIC) 32. SLIC 32 connects telephone 30 
to a central office and provides a variety of services that are well known 
in the art and need not be discussed herein. SLIC 32 may include a low 
pass filter 34 that operates when SLIC 32 is operating. Telephone system 
also include other circuits, some of which do not operate at the same time 
as a SLIC. For example, a ring trip detector 36 detects when telephone 30 
has been answered by providing to comparator 38 a signal indicative of the 
voltage (or current) across resistor 40. The voltage (or current) across 
resistor 40 is form a dc signal from ring generator 42. Telephone 30 has 
been answered when the dc signal across resistor 40 exceeds a 
predetermined value. The signal from detector 36 to comparator 38 passes 
through low pass filter 44. 
Each of filters 34 and 44 may include a resistor R.sub.A, R.sub.B and may 
share a common capacitor 46, to thereby reduce the number of capacitors 
required to operate the telephone system. When SLIC 32 is transmitting an 
audio frequency signal to telephone 30, switches 50 and 52 are closed 
connecting SLIC 32 to the telephone line and switches 54 and 56 are open 
disconnecting ring generator 42 and ring trip detector 36. SLIC 32 may use 
low pass filter 34 for its battery feed function, while ring trip detector 
36 has no need for filter 44. Accordingly, switch 58 is closed to ground 
resistor R.sub.A and disable filter 44, and to ground common capacitor 46 
and enable operation of filter 34. 
Conversely, when telephone 30 is being called switches 54 and 56 are closed 
to connect ring generator 42 and ring trip detector 36 to the telephone 
line. Switches 50 and 52 are open to disconnect SLIC 32. Ring trip 
detector 36 uses low pass filter 44 to detect ring trip, while SLIC 32 has 
no need for filter 34. Accordingly, switch 60 is closed to ground resistor 
RB and disable filter 34, and to ground common capacitor 46 and enable 
operation of filter 44. SLIC 32 may include an integrated circuit and 
switches 58 and 60 may be integrated into the integrated circuit. 
With further reference to FIG. 4, further switches 62 and 64 may be added 
to the ring detector 36 connection to improve isolation of ring generator 
42 by shunting resistors 66 and 68 to ground. Ring generator 42 normally 
provides a ring signal at all times, so that when SLIC 32 is connected to 
the telephone line and ring trip detector 36 is disconnected, resistors 66 
and 68 carry the ring signal to detector 36. Detector 36 will deliver an 
output of some kind to resistor R.sub.A in filter 44. Even though resistor 
R.sub.A is grounded by switch 58 during this time, a ring signal may still 
reach capacitor 46 if switch 58 has a high "on" resistance. When switch 58 
has high "on" resistance, the output of filter 44 may not be solidly 
grounded and resistor R.sub.A could couple some of the ring signal into 
capacitor 46 and thus into SLIC 32 through filter 34. Switches 62 and 64 
present this from happening by shunting resistors 66 and 68 to ground. 
When detector 36 is being used, switches 62 and 64 are open. 
While preferred embodiments of the present invention have been described, 
it is to be understood that the embodiments described are illustrative 
only and the scope of the invention is to be defined solely by the 
appended claims when accorded a full range of equivalence, many variations 
and modifications naturally occurring to those of skill in the art form a 
perusal hereof.