MULTIFUNCTION TWO LINE TELEPHONE SYSTEMThe present invention relates to telephones and specifically to a multifunction two line telephone which offers a user the features of two lines, transfer of calls, conference calling and hold, all within a circuit design which is simple and reliable.
The invention uses concepts described in UnitedStates Patents 3, 470, 322 and 3, 567, 867, assigned to the same assignee as the instant application. Those patents disclose a conference and transfer circuit wherein a SCR (Triac) switch is connected in series with the windings of a transformer for coupling the lines of a two line telephone together in a conference call. That circuitry enables its use in all types of telephone signalling and exchange systems because the SCR effects line switching on the passage of line current to or through zero. The present invention uses on opto-isolated SCR (Triac) transformer connection with other elements to produce a multifunction telephone well suited to today's small business or home.
More particularly, the patents disclose a conference connection and call transfer device for effecting call transfer or conference connection between two or more mutually remote telephone subscribers at a subscriber station having a plurality application to all types of telephone signalling exchange systems including step-bystep, cross-bar and solid state. The lines are inductively coupled by means of a transformer having a winding for each of the lines to be coupled. Coupling is effected through a series-connected, bi-directional triode switch in each line circuit, whereby automatic disconnect is effected upon hanging up of the remote telephone subscriber set. Manual switch means are provided for switching a controlling telephone hand-set from the seized line to another line, at which time the transformer winding associated with the seized line serves as a terminal impedance for the line matching that of a hand-set to keep the line seized.
The two line telephone of the present invention operates with five pushbutton switches ; one pushbutton each for LINE 1 and LINE 2, a CONFERENCE pushbutton and pushbuttons for HOLD and INTERCOM. The controls from these pushbuttons are gated to drive five relays, a LINE select relay, a CONFERENCE relay, an INTERCOM relay, and two CLEAR relays one for each of LINE 1 and LINE 2. Two line circuits are employed which are isolated from each other via optoisolation devices. In addition, the hold/conferencing triode switches are also opto-isolated. The use of such isolation elements simplifies the circuit in that only a single power supply transformer is required for both lines.
This is accomplished since the ground systems for each line are isolated from each other.
The principal object of this invention is the provision of a two line telephone for the home and small office which provides conferencing, intercom and hold features.
Another object of the invention is the provision of a two line telephone which uses only a single transformer as the line circuits are opto-isolated.
An additional object of the present invention is to provide a hold/conferencing function in a telephone using the TRIAC switch connections of U. S. Patents 3, 470, 322 and 3, 567, 867.
BRIEF DESCRIPTION OF THE DRAWINGThese as well as further objects and advantages of the invention will become apparent to those skilled in the art from a review of the following detailed specification and the accompanying drawings in which : Fig. 1 is a schematic diagram of a portion of the two line telephone circuit showing the pushbuttons, the relays and the gates ;Fig. 2 is a schematic diagram of the line circuit for one of the two telephone lines ;Fig. 3 is a schematic diagram of another portion of the two line telephone showing INTERCOM circuit ; andFig. 4 is a schematic diagram of another portion of the circuit for the two line telephone showing the ringers, the conference connections and a portion of the line circuit.
DETAILED DESCRIPTIONFigs. 1-4 of the drawings show the entire schematic for the two line telephone of the present invention.
Electrical leads which overlap from one Fig. to another are denoted with a capital letter. Matching the Figs.. of the drawings with the leads matched by their capital letters will correctly connect the Figs. to form the composite schematic.
In Fig. 1, numerals 2, 4, 6, 8 and 10 denote control pushbutton switches on a telephone. Numeral 2 denotes a LINE 1 control button ; numeral 4 is a LINE 2 control button ; numeral 6 is a CONFERENCE control button ; numeral 8 is a HOLD button ; and numeral 10 is an INTERCOM control switch. Each of the pushbutton switches has one of its terminals grounded via a ground connection 24. The ungrounded terminals of each of the pushbuttons are connected to a source of voltage, V+, via a line 12, through suitable bias resistors, 1, 3, 5, 7 and 9. These ungrounded terminals are connected to the remainder of the telephone circuit via lines 14, 16, 18, 20 and 22.
More specifically, the line 14 connects the pushbutton 2 to one input of a gate 26. The line 16 connects the pushbutton 4 to one input of a gate 28. Together, the gates 26 and 28 comprise the line selection flip-flop. The line 16 also connects the pushbutton 4 to gates 32, 38 and 42. The pushbutton 2 is similarly connected to the gates 32, 38 and 40 via the line 14. The pushbutton 6 is connected to the gates 30 and 34 via the line 18. The push button 8 is connected to gates 46 and 48 via the line 20. the pushbutton 10 is connected to a gate 36 via line 22.
The gates 30 and 32 are connected together t6 form the CONFERENCE flip-flop. The gates 36 and 38, similarly form the INTERCOM-flip-flop.
Gates 40 and 42 serve to clear the connections toLINES 1 or 2. The inputs to gate 40 are the LINE 1 pushbutton 2 via line 14, the output from a time delay RC circuit 196, and the output from opto-isolator 104. The inputs to gate 42 are the LINE 2 pushbutton 4 via line 16, the output from a second time delay RC circuit 198 and the output from opto-isolator 124. The inputs to the INTERCOM flipflop (gates 36, 38) are the INTERCOM pushbutton 10 via line 22, the LINE 1 pushbutton 2 via line 14, the LINE 2 pushbutton 4 via line 16 and the output of a comparator 186.
The input to gate 34 is solely the CONFERENCE pushbutton 6 via line 18. The input to gate 30 is the CONFERENCE pushbutton 6 via line 18. Gate 32 receives as inputs, the LI-NE 1 pushbutton 2 via line 14 and the LINE 2 pushbutton 4 via line 16.
The output of the gate 26 is connected to another gate 44. The gate 44 also receives as inputs, the output from the gates 30 and 36. The output of the gate 28 is connected to a gate 46 which gate is also connected to the HOLD pushbutton 8 via a line 20. Another gate, 48, gates the output of the gate 26 with the HOLD pushbutton 8 via THELINE 20. The output of the gate 44 is connected to a line select relay driver circuit consisting of transistor 54, DPDT relay 56 and a diode 58. This portion of the circuit controls the selection of LINE 1 or LINE 2.
The output of the gate 46 is gated in a gate 50 with the output of the gate 34. The output of gate 48 is connected to one input of a gate 52 along with the output of a gate 34. The output of the gate 36 is connected to another relay driver circuit which includes a transistor 66, a relay 70 and a diode 68. This relay driver circuit controls the INTERCOM connections.
The output of the gates 40 and 42 control respective relay driver circuits consisting of the transistor 11, the relay 17, and associated circuitry for gate 40 ; and the transistor 13, the relay 15 and associated circuitry for the gate 42. The output of the CONFERENCE relay driver circuit (transistor 60, etc.), is connected to a light emitting diode 19 to illuminate same during a CONFERENCE connection.
The output of gate 50 is connected to one input of a gate 72. The output of a gate 52 is connected to one input of a gate 74. The other input of gate 72 is the output of an opto-isolator 108. The other input to gate 74 is the output of the opto-isolator 130. Gates 72 and 74 are connected to the opto-coupled triacs 142 and 140, respectively via respective transistor drivers 76 and 78.
The two telephone lines for the telephone of the present invention are shown in Fig. 2 at numerals 80 and 82, and 84, 86. Numerals 80, 82 denote, respectively, the tip and ring telephone lines for LINE 2, while numerals 84, 86 are, respectively, the tip and ring telephone lines for LINE 1. Two identical line circuits, shown generally at 92 forLINE 1 and at 94 for LINE 2, are provided. As these line circuits are 1dentical, only the LINE 1 circuit 92 will be described in detail herein.
Specifically, the tip and ring lines, 84 and 86, are protected by varistor element 90 coupled between the lines. A relay 17, driven by the CLEAR LINE 1 relay driver transistor 11 discussed above and shown in Fig. 1, is connected across lines 84 and 86. A diode bridge circuit 96 is coupled across the lines 84, 86. The output of the bridge circuit 96 is connected as an input to a comparator 98 and as an input to another comparator, 102. Comparator 98 will be referred to as a'low comparator'while comparator 102 will be referred to as a'high comparator'.
The output of the low comparator 98 is connected to another comparator 100. The output of the comparator 100 is connected to the opto-isolator 104 at the cathode thereof.
The output of the high comparator 102 is connected to another comparator 106. The output of the comparator 106 is connected to the cathode of the opto-isolator 108. The output of the wpto-isolator 104 is connected to a gate 110 and to the gate 40 as previously described. The output of the opto-isolator 106 it connected to a gate 114 and to the gate 72 as previously described. The gates 110 and 114 are connected to LED 112 which constitutes the illuminated light in the LINE 1 pushbutton 2.power is provided from an oscillator 202, Fig. 1, connected to the primary winding 204 of a transformer. The secondary windings of the transformer are shown at numeral 116 in the LINE 1 circuit 92 (Fig. 2) and at numeral 132 in the LINE 2 circuit 94 (Fig. 4). Another oscillator 200 is directly connected to the gate 110 in the LINE 1 circuit 92 and to the gate 134 In the LINE 2 circuit 94 to provide the flashing rate for the LED's when in BOLD.
As can be aven, the LINE 2 circuit 94 is the same as the LINE 1 circuit 92 with diode bridge 118 connected to lines 90 and 22, the tip and ring telephone lines. Numeral 136 Is the illuminated LED In the LINE 2 pushbutton 4.
As previously discussed, the CONFERENCE andTRANSFER functions are implemented using the transformer coupling technique disclosed In U.S. patents 3,470,322 and 3, 567, 867 further improved by utilizing an opto-isolated drive and a relay contact to short the transformer winding for hold. The patente circuit in the present telephone is shown in Fig. 4 coupled to the windings of transformer 144.
Specifically, an opto-coupled triac 142 lz connected to one side of transformer 144. The LED cathode cf the optocoupled triac 142 1s connected to the output of the gate 72, tig. tw via transistor 76 and to the tip line of LINE 1 telephone line via connection 21. The ring line 86 of LINE t In alto connected to the transformer 144 via line 19. A relay 148 is connected across the winding of transformer 144 to provide the BOLD function. This relay contact is opened for conference operation.
Another opto-coupled triac t40 In connected to the other winding 144a of the transformer 144. This opto-coupled triae 140 In connected to the tip line 80 of the LITE 2 telephone line via line 23. The LED cathode of the optocoupled triac 140 lr connected to the output of the gate 74 via transistor 78. The ring line 82 of LINE 2 is connected to transformer 144 via line 25. A relay 146 is connected across winding 144a of the transformer 144 to provide theHOLD connection. This relay contact is opened for conference operation.
Lines 19 and 21 also connect the LINE 1 tip and ring lines 84 and 86 to a telephone"ring"circuit 152, 164.
The LINE 2"ring"is generated by 150, 162 and is connected to the LINE 2 tip and ring lines via lines 27 and 29. As these"ring"circuits are standard in the telephone arts, no further description will be made herein.
Numerals 31 and 33 denote the connection points for connection of the telephone of the present invention to the remainder of the telephone system. The line select relay 158 connects either ring line 86 or ring line 82 to'terminal 31, while the INTERCOM relay 35 connects either the line select relay 158 or INTERCOM tip line 190 to terminal 31.
Similarly, tip lines 84 or 80 can be connected to terminal 33 via line select relay 160 while INTERCOM relay 156 connects to either the line select relay 160 or directly to ground.
Turning now to the remainder of the circuit shown in Fig. 3, AC power from a step down transformer is connected to the telephone via terminals 182 and 184 which is rectified in bridge 180 and connected to a voltage regulator 178. The power supply is, in turn, connected in usual fashion to the standard touch-tone decoder circuits shown / generally at 166, 170 and 168, 172 for the INTERCOM function. As these are standard telephone circuits known to those skilled in the art, no further explanation will be made thereof herein.
The INTERCOM function is implemented by the circuit shown in Fig. 3 connected to the INTERCOM tip and ring terminals 190, 192. Specifically, INTERCOM tip terminal 190 is connected to an INTERCOM relay 35, touch-tone decoder 166 and 168, and to the comparators 186 and 188. The output of comparator 188 is connected to the INTERCOM LED 37. The output of the comparator 186 is connected to the gate 38 in the INTERCOM flip-flop.
A talk battery for the INTERCOM circuit may be provided as is shown at numeral 194.
The circuit functions to present the user with the following capability. First, the user can push either theLINE 1 pushbutton 2 or the LINE 2 pushbutton 4, then lift the receiver to place a call in the normal manner. The pushbuttons 2 and 4 will indicate the status of each line : if the light is OFF, the line is available, if the light is solidly ON, the line is in use, and if the light is slowly blinking, the line is in HOLD.
To answer a call, the two ringers 150 and 152 are provided, one for each line with each ringer making different tones to distinguish the lines. The LED for the line being called will flicker indicating which line is being called.
To place a call on HOLD, the HOLD pushbutton 8 is depressed. To retrieve a call on HOLD, the LINE 1 or the LINE 2 buttons, 2 or 4 are used. When a call is on HOLD, the LED will flash slowly. If another station answers the call, the LED display will change to solid ON indicating that-. the LINE is in use.
To establish a CONFERENCE, a call is made or received on either LINE 1 or LINE 2. The CONFERENCE pushbutton 6 is then depressed. Specifically, a call can be placed on LINE 1, then placed in HOLD. LINE 2 is selected and another call is placed on LINE 2. The CONFERENCE is initiated by simply pushing the CONFERENCE pushbutton 6.
The initiator can leave the CONFERENCE by hanging up. To return to normal operation, either LINE 1 or LINE 2 pushbuttons 2 or 4 is depressed which disables the CONFERENCE and places the other LINE in HOLD.
INTERCOM is used by simply depressing the INTERCOM pushbutton 10, then dialing the other station's number.
INTERCOM is released by pushing either the LINE 1 or theLINE 2 pushbuttons 2 or 4 and the telephone connection is returned to an outside line.
In responding to INTERCOM, the INTERCOM pushbutton at the receiving telephone is depressed and the receiver is removed. Again, the return to an outside line is accomplished using the LINE 1 or 2 pushbuttons 2 or 4.
The telephone of the present invention is designed to continue to operate if AC power is lost. The phone will operate as a single line telephone on LINE 1. Both of the ringers 150 and 152 will continue to operate but the lights,LINE 2, HOLD, CONFERENCE and INTERCOM will not operate.
If an incoming line is disconnected, the LED for that line will blink as if the line is on HOLD. Depressing the blinking line pushbutton in this condition will cause the telephone to generate a buzzing sound.