JPH06268764A - Modem - Google Patents

Abstract

PURPOSE:To provide a modem thin in structure and excellent in transmission characteristic. CONSTITUTION:The transmitting side circuit 3 of a network control part 1 is constituted of a first photocoupler 8, a first resistor 9, and a first operational amplifier 10 which inputs the output voltage of the first resistor and reference voltage, and whose output terminal is connected to the primary side of the first photocoupler; and a current equal to the current flowing through the first resistor 9 is generated across both two phototransistors 6, 7 constituting the first photocoupler. On the other hand, a receiving side circuit 4 is constituted of a second photocoupler 15 whose primary side is connected to a public exchange line network 12, a third photocoupler 19, and a second operational amplifier 21 which inputs the output signals of these second and third photocouplers and whose output terminal is fed back to the primary side of the third photocoupler, and the distortion of the second photocoupler is removed by the second operational amplifier.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a modem provided between a data processing device and a public switched line network, and in particular, while electrically insulating the data processing device and the public switched line network, The present invention relates to a configuration of a network control unit for exchanging data between the data processing device and the public switched network.

[0002]

2. Description of the Related Art In order to perform data communication via a public switched line network, a network control unit (NCU) is used.
Unit) is indispensable. Conventionally, in the field of telephone technology, for example, "transistor technology special NO8"
(CQ Publisher, published August 20, 1991), 76th
As described on pages 85, 85, a line controller method, a choke-isolation transformer method, a diode-active-L and isolation transformer method, and a speech network are used as a network control device. Methods and the like are known (see FIG. 3).

[0003]

However, all of the above-mentioned conventional network control devices use a line transformer or an insulating transformer, so that there is a disadvantage in that the external dimensions tend to be large. That is, since the outer dimensions of a transformer having a better transmission characteristic tend to be larger, if one tries to obtain a practically sufficient transmission characteristic,
Even the smallest one has a thickness of about 1 cm, which limits the miniaturization and thinning of the modem. Therefore, in order to further reduce the size and thickness of the modem, it is essential to develop a network control unit that does not use a transformer.

The present invention has been made to solve the above problems, and an object thereof is to provide a modem which is thin and has excellent transmission characteristics.

[0005]

In order to achieve the above-mentioned object, the present invention is a modem which comprises a network control unit and a modulation / demodulation unit, and which is provided between a data processing device and a public switched line network. The transmission side circuit and the reception side circuit of the network control unit,
An optical coupling element that electrically insulates the modulation / demodulation section from the public switched line network and exchanges data between the modulation / demodulation section and the public switched network, and a distortion of an output signal of the optical coupling element. And a distortion removing circuit for removing the signal.

[0006]

[Function] An optical coupling element such as a photocoupler or a semiconductor relay electrically insulates the devices connected to the primary side and the secondary side, and is connected to the secondary side from the device connected to the primary side. An element that enables data transmission to a device. Therefore, by providing this optical coupling element in both the transmission side circuit and the reception side circuit of the network control unit, the modulation / demodulation unit connected to this is electrically insulated from the public switched line network, while these modulation / demodulation units are provided. It is possible to perform bidirectional data transmission with the public switched network. Since the optical coupling element is a small electronic component that can be mounted on the circuit board that constitutes the modulation / demodulation unit, by using the optical coupling element instead of the conventional transformer, it is possible to reduce the outer dimensions of the modem, particularly the thickness. Since the photocoupler, especially the photocoupler, does not have a good linearity with respect to the input voltage, simply providing a photocoupler instead of the conventional transformer will distort the transmission signal and the reception signal and increase the bit error rate. , Reliable data transmission cannot be performed. When a distortion removing circuit that removes distortion of the output signal of the optical coupling element is added to the optical coupling element, the linearity of the output signal with respect to the input voltage is improved, so that highly reliable data transmission becomes possible.

[0007]

[First Embodiment] FIG. 1 shows the configuration of a modem according to the first embodiment. The modem of this example comprises a network control unit 1 and a modulation / demodulation unit 2 as shown in the figure. However, as the modulation / demodulation unit 2, a publicly known one can be applied as it is, and therefore detailed illustration is omitted and the network is omitted. Only the control unit 1 is illustrated.

The network control section 1 comprises a transmitting side circuit 3 and a receiving side circuit 4. The transmission side circuit 3 includes a first photocoupler 8 that is a combination of one light emitting diode 5 and two phototransistors 6 and 7 having the same characteristics that receive light from the light emitting diode 5, and a transmission signal a. A first resistor 9 for converting the voltage of the first resistor 9 and an output voltage of the first resistor 9 and a reference voltage are input, and an output terminal is connected to the primary side light emitting diode 5 of the first photocoupler. Operational amplifier 1
Of the two phototransistors, the output end of one phototransistor 7 is connected to the public switched line network 12 through the diode bridge 11, and the output end of the other phototransistor 6 is connected. It is fed back to the input end of the light emitting diode 5.

The receiving side circuit comprises a light emitting diode 13 and a phototransistor 14, a second photocoupler 15 in which the public switched network 12 is connected to the primary side light emitting diode 13, and the second photocoupler 15. A second resistor 16 for converting the output current from the secondary side phototransistor 14 into a voltage, a third photocoupler 19 including a light emitting diode 17 and a phototransistor 18, and a secondary of the third photocoupler 19. The third resistor 20 for converting the output current from the side phototransistor 18 into a voltage and the output voltages of the second and third photocouplers are input, and the output end is the primary side light emission of the third photocoupler 19. The second operational amplifier 21 is fed back to the diode 17.

The operation of the network control section 1 according to this embodiment will be described below. When an operational amplifier 10 having a very large gain is used, the potential of the plus side input terminal and the minus side input of the operational amplifier 10 are described. Since the potential of the terminal becomes substantially equal, the bias voltage is hardly applied to the light emitting diode 5. The transmission signal a is supplied to the other phototransistor 6 through the first resistor 9, so that the current I ₁ flowing through the first resistor 9 and the current I ₂ flowing through the other phototransistor 6 Are equal.
The current I ₂ flowing through the other phototransistor 6 is supplied to the light emitting diode 5 to cause the light emitting diode 5 to emit light. Since the two phototransistors 6 and 7 that receive this light are adjusted to have the same characteristics, the currents flowing through these two phototransistors 6 and 7 are equal. Therefore, the current I ₁ flowing through the first resistor 9
And a current I ₃ flowing through the one phototransistor 7
Since and are equal, the phototransistor 7
A signal corresponding to the transmission signal a is output to the output end of the signal irrespective of its characteristics, and the transmission signal without distortion can be placed on the public switched line network 12 via the diode bridge 11.

On the other hand, via the diode bridge 11,
When the reception signal b from the public switched line network 12 is input to the light emitting diode 13 of the second photocoupler 15, the light emitting diode 13 emits light, and the light is received by the phototransistor 14, and the phototransistor 14 Is output to the positive terminal of the second operational amplifier 21.
Further, the signal differentially amplified by the second operational amplifier 21 is input to the light emitting diode 17 of the third photocoupler 19, the light emission of the light emitting diode 17 is received by the phototransistor 18, and the phototransistor 18 is received. Is output to the negative terminal of the second operational amplifier 21. Therefore, when the second photocoupler 15 and the third photocoupler 19 having the same characteristics are used, the potentials at both ends of the phototransistor 14 and the potential at both ends of the phototransistor 18 become equal to each other, and the distortion of a plurality of orders occurs. Since it is canceled, the undistorted reception signal corresponding to the reception signal b can be taken out from the output terminal of the second operational amplifier 21 regardless of the characteristics of the photocouplers 15 and 19.

The modem of the above-described embodiment electrically insulates the modulation / demodulation unit 2 and the public switched line network 12 from each other and allows bidirectional data transmission between the modem unit 2 and the public switched line network 12. Since the photocouplers 8, 15 and 19 which can be made smaller than the transformer are used as the device, the external dimensions of the modem, particularly the thickness, can be made smaller than those using the conventional transformer. Also, photo couplers 8, 15, 1
Since the distortion removing circuit for removing the crossover distortion of 9 is provided, the linearity of the output signal with respect to the input signal is improved, and highly reliable data transmission can be performed.

<Second Embodiment> FIG. 2 shows the configuration of a network control unit of a modem according to the second embodiment. The network control unit of this example removes the distortion of the photocoupler in the transmission side circuit with the pulse width modulation circuit and filter of the transmission signal, and the distortion of the photocoupler in the reception side circuit with the pulse width modulation circuit and filter of the reception signal. Is removed. In FIG. 2, reference numeral 3 indicates a transmission side circuit, and reference numeral 4
Indicates a receiving side circuit.

The transmission side circuit 3 has a sampling clock c.
A first pulse width modulation circuit 31 that pulse-width modulates the transmission signal a in synchronization with k, and a first photocoupler 32 to which the output signal of the first pulse width modulation circuit 31 is supplied to the primary side.
And a first filter 33 that demodulates the signal generated in the first photocoupler 32 into an original transmission signal and transmits it to the public switched line network 12.

The first pulse width modulation circuit 31 has a constant current diode 34 to which a power supply voltage Vcc is supplied and a capacitor 35 for storing an output current of the constant current diode 34.
And a comparator 36 which receives the sawtooth wave appearing at both ends of the capacitor 35 and the transmission signal a as inputs, and a pulse width modulation signal of the transmission signal a at the output end of the comparator 37. Output a ₁ . The first photocoupler 32 includes a light emitting diode 38 and a field effect photodiode 39, and the output end of the photodiode 39 is connected to the input end of the first filter 33. The first filter 33 is composed of an inductor 40 and a capacitor 41, and the output terminal of the first filter 33 has a diode bridge 11
It is connected to the public switched line network 12 via.

The receiving side circuit 4 includes a diode bridge 11
Received signal b transmitted from the public switched network 12 via
A pulse width modulation circuit 51 for pulse width modulation in synchronization with a sampling clock ck, a second photo coupler 52 to which an output signal of the second pulse width modulation circuit 51 is supplied to the primary side, The second filter 5 that demodulates the signal generated in the second photocoupler 52 into the original received signal and takes it out.
3 and 3.

The second pulse width modulation circuit 51 includes first and second transistors 5 whose emitters are commonly coupled.
4, 55, a first resistor 56 connected to the collector side of the first transistor 54, and a second transistor 55.
A second resistor 57 connected to the base side of the first resistor and a third resistor 58 connected to the emitter sides of the first and second transistors 54 and 55, and a second constant current The diode 60 and the second capacitor 61
And a sawtooth wave generation circuit 62 including the first transistor 54. The second pulse width modulation circuit 51 inputs the sawtooth wave output from the sawtooth wave generation circuit 62 and the reception signal b transmitted via the public switched line network 12 to the comparator 59, At the output end, the pulse width modulated received signal b
Output ₁ A third photocoupler 63 is provided between the sampling clock generation source and the sawtooth wave generation circuit 62 to electrically insulate the sampling clock generation source from the public switched line network 12. .

The second photocoupler 52 is composed of a light emitting diode 64 and a field effect type photodiode 65. The primary side light emitting diode 64 receives the pulse width modulated reception signal b _{1 and} receives the secondary signal. The output end of the side photodiode 65 is connected to the input end of the second filter 53.

The second filter 53 is an operational amplifier 66.
, A capacitor 67, and resistors 68 and 69 form a single feedback type low-pass filter, and the signal generated at the output end of the second photocoupler 52 is demodulated to the original reception signal b.

The network control unit of the second embodiment supplies the transmission signal a ₁ (pulse signal) pulse-width modulated by the first pulse width modulation circuit 31 to the first photo coupler 32, and Since the reception signal b ₁ (pulse signal) pulse-width modulated by the second pulse width modulation circuit 51 is supplied to the second photocoupler 52, the transmission signal a or the reception signal b, which is an analog signal, is directly photoed. Coupler 3
A signal with less distortion can be extracted as compared with the case of being supplied to 2 or 52, and deterioration of the bit error rate due to poor linearity of the photocoupler 32 or 52 can be prevented. In addition, the comparator 59 provided in the transmission side circuit 4
To the emitter-coupled first and second transistors 5
4, 55 and the first to third resistors 56 to 58, it can be driven by the DC voltage contained in the public switched line network 12 and electrically insulated from the public switched line network 12. Since it is not necessary to provide a dedicated power supply, the configuration can be simplified. Besides, it has the same effects as the network control unit of the first embodiment.

In each of the above-described embodiments, only the case where the photocoupler is used as the optical coupling element has been described, but other optical coupling elements such as a semiconductor relay can be used.

[0022]

As described above, according to the present invention,
Since the network control unit is configured by using the optical coupling element, the network control unit, and hence the modem integrally manufactured by including the network control unit, can be downsized and thinned. In addition, since the distortion elimination circuit that eliminates the distortion of the optical coupling element is incorporated in the circuit that constitutes the network control unit, the linearity of the output signal with respect to the input voltage of the optical coupling element is improved, and highly reliable data transmission is possible. It will be possible.

[Brief description of drawings]

FIG. 1 is a circuit diagram of a network control unit of a modem according to a first embodiment.

FIG. 2 is a circuit diagram of a network control unit of a modem according to a second embodiment.

FIG. 3 is a circuit diagram illustrating a network control device according to a conventional example.

[Description of Codes] 1 network control unit 2 modulation / demodulation unit 3 transmission side circuit 4 reception side circuit 6 first photocoupler 10 first operational amplifier 12 public switched network 15 second photocoupler 19 third photocoupler 21 2 operational amplifier 31 1st pulse width modulation circuit 32 1st photocoupler 33 1st filter 51 2nd pulse width modulation circuit 52 2nd photocoupler 53 2nd filter

Claims (3)

[Claims] 1. A modem comprising a network control unit and a modulation / demodulation unit, which is interposed between a data processing device and a public switched line network, wherein a transmission side circuit and a reception side circuit of the network control unit are:
An optical coupling element that electrically insulates the modulation / demodulation section from the public switched line network and exchanges data between the modulation / demodulation section and the public switched network, and a distortion of an output signal of the optical coupling element. A modem including a distortion removing circuit for removing the signal. 2. A modem comprising a network control section and a modulation / demodulation section, which is interposed between a data processing device and a public switched line network, wherein a transmission side circuit of the network control section is provided with one light emitting diode and A first photocoupler that integrally combines two phototransistors having the same characteristics for receiving light from a light emitting diode; a first resistor that converts a transmission signal into a voltage;
A first resistor which receives an output voltage of the first resistor and a reference voltage and has an output end connected to the primary side of the first photocoupler.
Of the two phototransistors, the output terminal of one of the two phototransistors is connected to the public switched line network, and the other output terminal of the two phototransistors is connected to the light emitting diode. The receiving side circuit of the network control unit is fed back to the input end, and the receiving side circuit of the third side is provided separately from the second photocoupler whose primary side is connected to the public switched line network. A photocoupler, and a second operational amplifier in which output signals of the second and third photocouplers are input and an output terminal is fed back to the primary side of the third photocoupler. Modem to do. 3. A modem comprising a network control section and a modulation / demodulation section, which is interposed between a data processing device and a public switched line network, wherein a transmission side circuit of the network control section is synchronized with a sampling clock. A first pulse width modulation circuit for pulse width modulating a transmission signal, a first photo coupler to which an output signal of the first pulse width modulation circuit is supplied to a primary side, and a secondary of the first photo coupler. And a first filter for demodulating the signal generated at the side into an original transmission signal and transmitting the signal to the public switched line network, and a receiving side circuit of the network control unit is synchronized with a sampling clock to the public side. A second pulse width modulation circuit for pulse width modulating the data signal transferred through the switching network; a second photo coupler to which an output signal of the second pulse width modulation circuit is supplied to the primary side; 2 photo couplers Modem, characterized by being configured and a second filter for demodulating the signal generated on the secondary side to the original transmission signal.