SE504521C2 - Multiplexer, protective switching unit, telecommunication network and method of multiplexing - Google Patents

Abstract

There is provided a multiplexer which in a multiplexing process selects an output signal from a plurality of input signals, a protection switch unit which includes one such demultiplexer and a telecommunications network which includes one such protection switch unit, the multiplexer has an output (OUT+, OUT-) and at least two inputs (IN1+, IN1-, IN2+, IN2-) where two input signals corresponding to the inputs are received. A first connection point (IN1+, IN2+) in each input is connected to a first transmission line (TLINE_1) via a respective first controllable signal forwarding device (Q1, Q2). An externally controllable switch means (S2, S1) is also connected to each output for forwarding a signal or at least a part thereof delivered to said input to a first transmission line (TLINE_1). The first transmission line (TLINE_1) is connected to a first connection point (OUT+) in the output, where a signal of good quality is obtained.

Description

504 521 10 15 20 25 30 35 2 There are a number of standard circuits for relatively easily and inexpensively multiplexing signals having bit rates of up to about 30 Mb / s. With higher bit rates, line impedances, terminations, wiring and component data place strict demands on the circuit solution.

Keeping line impedances as constant as possible means that special care may be taken in the realization of the circuit board foil. The work is further complicated if many input signals are to be multiplexed. The circuit solution with standard circuits in a multiplexer thus becomes expensive and draws a lot of current.

There are several ECL-type multiplexers, see for example one listed in WO93 / 17500. ECL multiplexers have a relatively high gain (in the range of 15 - 30 dB) which must be attenuated in one or a few additional circuits to obtain unchanged signal level. There are a number of problems with such attenuation. In case more than ten signals are to be multiplexed, several ECL multiplexers must be connected together and this leads to an even higher gain and further attenuation problems. In addition, due to the pin placement of these circuits, the wiring on circuit boards is significantly more difficult if constant impedance and delay are to be maintained.

There is no good way in the art for multiplexing in the above-mentioned transmission rate range. US-A-5 146 113 describes an integrated circuit with several elongate resistor strips on a circuit board which is there to provide a predetermined input and / or output impedance to a circuit board mounted circuit.

US-A-5 281 934 describes a microwave multiplexer which is made in its entirety in a microstrip.

DISCLOSURE OF THE INVENTION An object of the present invention is to provide a method for selecting output signal from a number of input signals in multiplexing, where good signal quality is obtained in a simple and inexpensive manner.

This object is achieved by a method where at least two input signals are received at the inputs corresponding to the signals and where an input signal is selectively passed from one of the inputs to a transmission conductor means, from which an output signal is obtained.

A further object is to provide a method for selecting output signal from a number of input signals during multiplexing, where distortion in the output signal can be reduced in a simple manner in later steps.

This object is achieved by a method where each input signal comprises two parts and where the two parts of an input signal are led from one of the inputs to each transmission conductor means.

A further object of the present invention is to provide a method for selecting output signal from a number of input signals in multiplexing, which in addition offers an output signal which has substantially the same signal level as or is only slightly amplified compared to input. - the needles.

This object is achieved by a method which further comprises amplifying the output signal from said transmission conductor means.

Another object of the present invention is to provide a multiplexer, a protection switching unit comprising such a multiplexer and a telecommunication network comprising such a protection switching unit, where good signal quality is obtained in a simple and inexpensive manner when selecting an output signal from several input signals.

This object is achieved by a multiplexer, a protection switching unit and a telecommunication network, where the multiplexer comprises two or more inputs and an output and has a first connection point in each input via each a first controllable forwarding means connected to a first transmission conductor means, which is connected to a first connection point in the end.

A further object of the invention is to provide a multiplexer, a protection switching unit comprising such a multiplexer and a telecommunication network comprising such a protection switching unit, where in addition distortion in output signals obtained from the multiplexer in a simple manner can be reduced in later steps.

This object is achieved by a multiplexer, a protection switching unit and a telecommunication network, where a second connection point in each input of the multiplexer is in addition via each a second controllable forwarding means connected to a second transmission conductor means, which is connected to a second connection point in the output.

A further object of the invention is to provide a multiplexer, a protection switching unit comprising such a multiplexer and a telecommunication network comprising such a protection switching unit, wherein output signals from the multiplexer also have substantially the same signal level as or only a slightly amplified variable signal level compared to the input signals. .

This object is achieved by a multiplexer, a protection switching unit and a telecommunication network, where an amplifier is connected between the input of the multiplexer and said transmission conductor means.

DESCRIPTION OF THE DRAWINGS Further advantages and objects of the invention will become apparent from the following detailed description of a preferred embodiment of the invention taken in conjunction with the accompanying drawings, in which Fig. 1 shows a block diagram of a telecommunication system according to the invention; Fig. 2 shows a circuit diagram of a multiplexer according to the invention and Fig. 3 shows a circuit diagram of an alternative embodiment of the multiplexer shown in Fig. 2.

PREFERRED EMBODIMENT Fig. 1 shows a block diagram of a telecommunication system, which works with CMI signals that are transmitted at transmission speeds in the range of approximately 140 - 155 Mb / s.

This system comprises a switch 1, which communicates with 10 a number of signal lines. Each signal line is connected to a protection unit (PU = Protection Unit) 2. only eight, but more or fewer can easily be considered. To The figure shows the protection units 2 inbound and from these departing signals are indicated by arrows facing respectively from the protection units 2. Each protection unit 2 is connected to the switch 1 via each terminal access unit (TAU = Terminal Access Unit) 3 (of these only eight even though they are in fact sixteen in the same way). How these terminal access units 3 do not form part of this invention and is something that the person skilled in the art is well versed in and thus does not need to be explained in more detail. What needs to be mentioned, however, is that these terminal access units 3 are relatively expensive, complicated and have such a high error rate that some form of protection switching is required. In order to prevent a signal line from becoming unusable, a spare terminal access unit 5 is provided, which when one of the ordinary terminal access units 3 is out of operation is switched on to replace it. The backup terminal access unit is connected between the switch 1 and a protection switch (PSU unit 4 years connected to each protection unit 2. Protection unit protection switch unit) 4. This protection switch 2 is mainly used to convert to the terminal access units 3 and the protection switching unit 4 input simple signals to differential signals and from the exchange 1 via the terminal access units 3 and the protection switching unit 4 outgoing differential signals to single signals. The protection switching unit 4 comprises a multiplexer or selector and a demultiplexer. The multiplexer is arranged to receive all the signals incoming on the lines and to selectively forward one of these and the demultiplexer is arranged to receive a signal departing from the exchange 1 and forward it to a selected signal conductor.

Fig. 2 shows an embodiment of the multiplexer according to the invention, which for simpler explanation is only shown with two inputs, despite the fact that it normally has sixteen inputs. A first of the inputs has a first and a second connection point IN1 + and IN1 - The first connection point IN1 + of the first input is connected via a resistor R2 to a first forwarding means Q2, which in this embodiment is an RF transistor. The resistor R2 is here connected to the emitter of the transistor Q2. The base of the transistor Q2 is connected via a resistor R9 to a voltage source VBB, which has such an internal impedance that the base is grounded with respect to the signal supplied to the connection point IN1 +. The collector of the transistor Q2 is connected via a resistor R41 to a transmission conductor means TLINE_1 arranged in the circuit board for the multiplexer. This transmission conductor means TLINE_1 is terminated at both ends with resistors R12 and R44, which resistors are in turn connected to a voltage source VCC, which may have the same voltage as the voltage source VBB.

The second connection point IN1- of the first input is in the same way as the first connection point IN1 + via a resistor R4, an RF transistor Q3 and a further resistor R43 connected to a second transmission conductor means TLINE_2 arranged in the circuit board for the multiplexer. Transistor Q3 is connected with its base to the source VBB via a resistor R11. The second transmission conductor means TLINE_2 is also terminated with resistors R7 and R45, which are connected to the source VCC.

The respective emitters of the first and second transistors Q2 and Q3 are connected to one end of a first externally controlled switching means or switch S2 via a resistor R31 and R33, respectively. The other end of the switch S2 is connected to earth.

A second input with its connection points IN2 + and IN2- are connected in exactly the same way via a resistor R1, an RF transistor Q1 and a resistor R40 and via a resistor R3, an RF transistor Q4 and a resistor R42, respectively, to the first and the other transmission conductor means TLINE_1 and TLINE_2, respectively. The respective bases of the transistors Q1 and Q4 are connected to the source VBB via resistors R8 and R10. The respective emitters of the transistors Q1 and Q4 are connected in the same way as at the first input to a second externally controlled switch S1 via resistors R30 and R32, which switch S1 connects to earth in the same way. Q3 and Q4 with associated components are located along the transmission conductor means Transistors Q1, Q2, TLINE_1 and TLINE_2 so that mismatches and reflections are minimal. In addition, additional inputs are correspondingly located along these two transmission conductor means TLINE_1 and TLINE_2.

A differential amplifier D_AMP has an input and is with a first connection point + I in it connected to the first transmission conductor means TLINE_1 at the resistor R44 and with a second connection point -I therein to the second transmission conductor means TLINE_2 at the resistor R45.

The amplifier D_AMP finally has an output with two connection points + 0 and -0 which are connected to each connection point OUT + and OUT- respectively in the output. Resistors R44 and R45 could also be included in the amplifier D_AMP.

The transmission conductor means TLINE_1 and TLINE_2 are in the preferred embodiment manufactured as each a microstrip arranged in the circuit board foil, to which the transistors are connected. These microstrips are preferably straight, have an identical length and have a substantially uniform width. What is important in the execution of these, however, is that the two transistors at each input have the same long path to the amplifier's D_AMP connection points + I and -I in the input. Optionally, however, the transmission conductor means TLINE_1 and TLINE_2 may be slightly narrower at the points where the transistors are connected to match the impedance of a microstrip to the extra capacitance that a passive transistor supplies to it. An alternative for adapting the impedances of the transmission conductor means to the capacitances of the passive transistors is to select the value of the terminating resistors R7, R12, R44 and R55 to correspond to the transmission conductor means with the extra distributed capacitances which the inputs supply.

Another possible variant of the transmission conductor means are parallel line lines (stripline) which are arranged in the intermediate layer of the circuit board. However, an embodiment with such transmission conductor means requires that the transistors be connected to these by means of bushings, which, however, gives rise to a somewhat more difficult adaptation problem than when the transistors are connected to a microstrip. However, the inputs and outputs of the multiplexer are often arranged in the form of parallel plane lines extending through the interior of the circuit board.

The multiplexer according to Fig. 2 works with differential signals, which gives less distortion in the signals leaving the multiplexer. The multiplexer works in the following way. Two inputs are received at each input IN1 +, IN1- and IN2 +, IN2- (only two inputs are shown to understand the circuit, but in reality sixteen inputs are usually received via sixteen inputs, but other numbers can also be received, for example four or eight).

One of the inputs, for example the first, is activated by means of the first externally controlled switch S2, which activates the transistors Q2 and Q3 connected to the input when it is closed. The second input is passive, ie the second switch S1 is switched off. These switches can be designed in many ways by those skilled in the art, for example as transistors. Switches S1 and S2 are controlled by a control circuit arranged in said protection switching unit, which closes switches in dependence on which of the previously mentioned terminal access units is not in operation. This control could also take place directly from the previously mentioned gear.

When the first switch S2 is closed, the transistors Q2 and Q3 are biased and the input signal is passed through the transistors Q2 and Q3 to the transmission conductor means TLINE_1 and TLINE_2. The signal propagates in both directions on these transmission conductor means TLINE_1 and TLINE_2 and a half of the signal which has substantially half the amplitude of the input signal is received in the amplifier D_AMP. For the above reasons, this amplifier could just as easily be located at the other end of the transmission conductor means TLINE_1 and TLINE_2. Due to the termination resistors R7, R12, R44 and R55, the mismatch at the connection points of the active input to the transmission conductor means TLINE_1 and TLINE_2 does not generate any reflexes. The amplifier D_AMP then amplifies the signal to such a level that the output signal receives the same signal level as the input signal. The amplifier's D_AMP amplification can be adapted to also take into account losses in cables and connectors.

The grounded base stages of transistors Q2 and Q3 in the active input provide accurate termination impedance, since this is largely determined by the emitter series resistance if the bias current is sufficiently high. This provides good termination of incoming signals, which prevents reflections. The output impedance of the collector becomes high in relation to the load to be driven, ie the transmission conductor body. Any variation of the collector impedance does not affect the output signal level and the signal quality to any great extent. Crosstalk from passive inputs becomes low in the multiplexer because the current to the transistors of the passive inputs is turned off and the base of these transistors of the inputs acts as a barrier. If the signal source is also switched off, only noise and crosstalk from the conductors need to be blocked.

Transistors Q1, Q2, Q3 and Q4 can alternatively be connected slightly differently. In this variant, the connection points in each input are connected to the respective base via a resistor each and to the voltage source VBB via a resistor each. In addition, the emitters of the transistors at the respective input must be connected via additional resistors.

This solution thus requires more components in the multiplexer than the previous one and also requires additional components such as a capacitor and choke in order to be activated from the remote end, ie the end from which the signal comes.

In addition, the capacitance between base and emitter in the transistors gives greater crosstalk than in the previously described case. The signal quality is also difficult to get good.

In an alternative embodiment, which is shown in FIG.

D1, D4 and D3, each of which with its cathode is connected to the respective IN2 +, 3, the transistors are replaced with PIN diodes D2, connection point IN1 +, IN1- and IN2- in the input via a resistor R2 , R1, R4 and R3 and directly to the respective transmission conductor means TLINE_1 and TLINE_2 via their anode. This circuit lacks the voltage source VBB and the resistors which were connected between this voltage source and the respective base of the transistors in the embodiment of Fig. 2. In addition, the resistors R31, R30, R33 and R32 connected between switches S1 and S2 and the connection points are replaced by impellers Z30. Z33 and Z32. identical and all other reference numerals are the dances Z31, In all other respects the circuits are the same. In this case, the termination impedance is determined in an active input, for example the first input of the series resistors R2, R4, the impedances Z31, Z33 and the series resistance in the diodes D2, D4 and all subsequent transmission conductor means with terminations. Said impedances can be designed as only a resistor or a resistor in series with an inductor. Resistors in series with an inductor provide high impedance, which means that all current entering the diodes D1, D2, D3 and D4 also goes out to the transmission conductor means TLINE_1 and TLINE_2. The mismatch between the diode and the transmission conductor means in this embodiment becomes much larger than in the embodiment in Fig. 2. However, this does not generate any reflections if the adaptation at the other connection points of the transmission conductor means is good.

The resistance variation of the diodes from diode to diode does not to any great extent affect the input impedance to the transmission conductor means.

Claims (21)

10 15 20 25 30 35 S21 5Û4 11 PATENTKRAV Method for selecting an output signal from a number of input signals during multiplexing, comprising the steps of receiving at least two input signals at inputs corresponding to the signals (IN1 +, IN1-, IN2 +, IN2-), characterized in that one or at least a first part of one of the input signals is selectively conducted from a first connection point (IN1 +) in one of the inputs of a first transmission conductor means (TLINE_1) via a first controllable forwarding means (Q2; D2) and that said input signal or the first part of said input signal is obtained from said first transmission conductor means an output signal or a first part of an output signal that has good signal quality. A method according to claim 1, characterized in that the input signals each comprise a first and a second part and that the output signal comprises a first part and a second part, the second part of said input signal being guided, simultaneously with the corresponding first part, from a second connection point (IN1-) in said one input to a second transmission conductor means (TLINE_2) via a second controllable diversion means (Q3; D4) and that the second part of the output signal is obtained from said second transmission conductor means. Method according to one of the preceding claims, characterized in that the forwarding means (Q2, Q3, Q1, Q4: D2, D4, D1, D3) connected to the inputs (IN1 +, IN1-, IN2 +, IN2-) are controlled to forward the input signals from the inputs to said transmission conductor means (TLINE_1, TLINE_2) of a switching means corresponding to each input, externally controlled (S2, S1). Method according to any one of the preceding claims, characterized in that the output signal obtained from said transmission conductor means (TLINE_1, TLINE_2) is amplified. Multiplexer having at least two inputs (IN1 +, IN1-, IN2 +, IN2-) and one output (OUT +, OUT-), a first connection point (IN1 +, IN2 +) in each input connected to a common conductor (TLINE_1) via each a first controllable forwarding means (Q2, Q1; D2, D1) and to each input a connected externally controlled coupling means (S2, S1) for connecting said first forwarding means to to forward a signal pressed over the input or at least a part of it to the common conductor, characterized in that the common conductor (TLINE_1) is a first transmission conductor means, which is connected to a first connection point (UT +) at the output. Multiplexer according to claim 5, characterized in that a second connection point (IN1-, IN2-) in each input is connected to a second transmission conductor means (TLINE_2) via each a second controllable diversion means (Q3, Q4; D4, D3), which second transmission conductor means is connected to a second connection point (OUT-) in the output, to which the coupling means (S2, S1) are also arranged to control said second diversion means. Multiplexer according to claim 5 or 6, characterized in that said transmission conductor means (TLINE_1, TLINE_2) are each one in the circuit board of the multiplexer. arranged microstrip. Multiplexer according to any one of claims 5 to 7, characterized in that said transmission conductor means (TLINE_1, TLINE_2) are each a parallel plane line arranged in the circuit board for the multiplexer. Multiplexer according to any one of claims 5 - 8, characterized in that an amplifier (D_AMP) is connected between one end of said transmission conductor means (TLINE_1, TLINE_2) and the output (UT +, UT-) for amplifying signals obtained from said transmission conductor means. Multiplexer according to one of Claims 5 to 9, characterized in that the conduction means (Q1, Q2, Q3, Q4) are transistors, the emitter being connected to the connection point (IN2 +, IN1 +, IN1-, IN2-) in the corresponding input via a resistor (R1, R2, R4, R3), the collector is connected to said transmission conductor means (TLINE_1, TLINE_2) and the base is grounded with respect to the signal supplied to the connection point in the corresponding input. 10 15 20 25 30 35 504 521 13 Multiplexer according to one of Claims 5 to 9, characterized in that the conduction means (D1, D2, D3, D4) are diodes. Multiplexer according to any one of claims 5 to 11, characterized in that said transmission conductor means (TLINE_1, TLINE_2) are terminated / terminated with resistors (R12, R44, R7, R4s). Protective switching unit (4) comprising a multiplexer, which has at least two inputs (IN1 +, IN1-, IN2 +, IN2-) and one output (OUT +, OUT-), a first connection point (IN1 +, IN2 +) in each input of the multiplexer is connected to a common conductor (TLINE_1) via a first controllable forwarding means (Q2, Q1: D2, D1) and to each input there is also connected an externally controlled coupling means (S2, S1) for controlling said first forwarding means for forwarding a signal applied across the input or at least a part thereof to the common conductor, characterized in that the common conductor (lLINE_1) is a first transmission conductor means, which is connected to a first connection point (UT +) at the output of the multiplexer. Protective switching unit (4) according to claim 13, characterized in that a second connection point (IN1-, IN2-) in each input of the multiplexer is connected to a second transmission conductor means (TLINE_2) via each a second controllable forwarding means (Q3, Q4: D4, D3), which second transmission conductor means is connected to a second connection point (OUT-) at the output of the multiplexer, to which the coupling means (S2, S1) are also arranged to control said second diversion means. Protective switching unit (4) according to claim 13 or 14, characterized in that an amplifier (D_AMP) is connected between one end of said transmission conductor means (TLINE_1, TLINE_2) and the output (UT +, UT-) of the multiplexer for amplifying said transmission conductor means. signals. Protective switching unit (4) according to one of Claims 13 to 15, characterized in that the forwarding means (Q1, Q2, Q3, Q4) at each input of the multiplexer are transistors, where the emitter is connected to the connection point (IN2 +, jN1 +, IN1-, IN2-) in the corresponding input via a resistor (R1, R2, R4, R3), the collector is connected to said transmission conductor means (TLINE_1, TLINE_2) and the base is grounded with respect to the signal supplied to the connection point in the corresponding input. Protective switching unit (4) according to one of Claims 13 to 15, characterized in that the diverting means (D1, D2, D3, D4) in the multiplexer are diodes. Protective switching unit (4) according to any one of claims 13 - 17, characterized in that said transmission conductor means (TLINE_1, TLINE_2) is arranged on a circuit board for the multiplexer and is terminated / terminated with resistors (R12, R44, Rv, 1). : 45). A telecommunication network comprising two or more wires connected to a switch (1) via each terminal access unit (3), each line also being connected to a protection switching unit (4), which in turn is connected to the switch via a backup terminal access unit (5), wherein the protection switching unit comprises a multiplexer having an input (IN1 +, IN1-, IN2 +, IN2-) for each line and an output (UT +, OUT-), where a first connection point (IN1 +, IN2 +) in each input on the multiplexer is connected to a common conductor (TLINE_1) via each a first controllable forwarding means (Q2, Q1: D2, D1) and to each input there is also connected an externally controlled connecting means (S2, S1) for controlling said first forwarding means to forward a signal pressed across the input or at least a part thereof to the common conductor, characterized in that the common conductor (TLINE_1) is a first transmission conductor means, which is connected to a first connection point (UT +) at the output of the multiplexer. Telecommunication network according to claim 19, characterized in that a second connection point (IN1-, IN2-) in each input of the multiplexer included in the protection switching unit (4) is connected to a second transmission conductor means (TLINE_2) via each a second controllable diversion means (Q3, Q4; D4, D3), which second transmission conductor means is connected to a second connection point (OUT-) at the output of the multiplexer, to which the coupling means (S2, S1) are also arranged to control said other forwarding means. Telecommunication network according to any one of claims 19 or 20, characterized in that an amplifier (D_AMP) is connected between one end of said transmission conductor means (TLINE_1, TLINE_2) and the output (UT +, UT-) of the multiplexer for amplification of said transmission conductor means obtained from .