JP2004319009A - Transmission system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a transmission system realizing transmission/reception of an information signal only between predetermined devices. <P>SOLUTION: In order to transmit a 1-bit signal from an acoustic information reader 2 to an amplifier 3, a transmission notifying signal is first transmitted from a first control means 17 through a first signal line 4 to a second control means 36. When the second control means 36 receives the transmission notification signal and understands the reception, generates a transmission permission signal, and transmits this signal through the first signal line 4 to the first control means 36. The acoustic information reader 2 does not transmit a 1-bit signal through a second signal line 5 to the amplifier 3 until the acoustic information reader 2 receives the transmission permission signal. The 1-bit signal is not transmitted/received unless mutual authentication is carried out by the acoustic information reader 2 and the amplifier 3. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a transmission system for transmitting a predetermined information signal between predetermined devices.
[0002]
[Prior art]
As a first prior art for transmitting a predetermined information signal between predetermined devices, for example, an audio information reading device that reads an audio information signal recorded on a disk-shaped recording medium such as a compact disk (CD). A transmission system including an amplifier and an amplifier has been put to practical use. When the acoustic information reading device is activated and reads the acoustic information signal from the disk-shaped recording medium, the read acoustic information signal is transmitted to the amplifier via the transmission cable. That is, the audio information reading device outputs the audio information signal regardless of the device to which the read audio information signal is transmitted, and unidirectionally transmits the audio information signal to the amplification device. Therefore, the audio information signal can be freely extracted from the output terminal of the audio information reading device that outputs the audio information signal.
[0003]
A speaker is connected to the amplifying device, and the acoustic information signal is amplified by the amplifying device and then converted into a sound wave by the speaker.
[0004]
In the above-described transmission system, for example, when a digital signal, which is a 1-bit signal subjected to delta-sigma modulation, is transmitted as an audio information signal, for example, the power of an audio reproducing apparatus is suddenly shut off during the transmission of the digital signal. Then, the amplitude of the signal is attenuated in the process of power-off, and an abnormal sound is generated from the speaker.
[0005]
The principle of the generation of the abnormal sound will be specifically described below. The analog component of the one-bit signal is determined by the width of the pulse train represented by “1” and “0” in the time axis direction. However, depending on the circuit that processes the 1-bit signal, the amplitude of the pulse train is related to the analog component. If the subsequent stage of the circuit that processes the pulse train is a transmission circuit that digitally processes “1” or “0” like a flip-flop, for example, the amplitude component of the signal particularly affects the analog component. Do not give. However, if the subsequent stage of the circuit is a transmission circuit such as a low-pass filter and an A / D (Analog / Digital) converter, the magnitude of the amplitude component is an analog component. Have an important effect. For example, it is this characteristic that the digital amplifier performs amplification by replacing the voltage value in the amplitude direction of the pulse train.
[0006]
The transmission system described above includes a transmission system circuit that processes the signal in an analog manner in order to output the audio information signal from the speaker. Therefore, when the amplitude of the input pulse train changes, the speaker may change depending on the way of the change. A modulated sound will be generated. In many cases, a transmission circuit that processes the signal in an analog manner processes a pulse train of a 1-bit signal with a voltage of 0 V as a low reference. In such a circuit, the analog component repeats “0” repeatedly. In the case of a pulse train, DC (
(Direct Current) offset exists. Therefore, when a pulse train of a 1-bit signal is input to such a circuit and the pulse train disappears suddenly, the DC offset changes, and an abnormal sound corresponding to this change is generated from the speaker.
[0007]
Further, when a waveform shaping circuit is provided in the amplifying device in order to remove the influence of noise received by the transmission cable or the like, the information signal is reconfigured by the waveform shaping circuit. In the waveform shaping circuit, when the amplitude of one of the information signal and the clock signal input together with the information signal becomes smaller than a predetermined threshold value, the output itself suddenly disappears. As a result, for example, an abnormal sound may be generated from a speaker connected to the amplifier. When the digital signal gradually attenuates or suddenly disappears, an abnormal sound is generated from the speaker due to a change in the waveform.
[0008]
As a second prior art for suppressing the occurrence of abnormal sounds from the speaker, a control command is transmitted to the other end of the cordless telephone through the communication channel when one of the cordless telephones disconnects while the parent device and the child device are talking on the communication channel. There is a transmission system that prevents the transmitted control command from becoming audible noise and being generated in the receiver of the other party, thereby causing discomfort. In this transmission system, a comparison circuit compares a pattern stored in advance with a pattern of a control signal, and if they match, the microcomputer controls the audio amplification device so that no audio is emitted from the speaker. (For example, Patent Document 1).
[0009]
[Patent Document 1]
JP-A-6-85728
[0010]
[Problems to be solved by the invention]
In the first prior art, there is a problem that a sound recording device that records a sound information signal is connected to an output terminal of the sound information reading device that outputs a sound information signal, and the sound information signal can be copied at will. is there. That is, a copyrighted work such as audio information can be copied by an unspecified number of audio recording devices, and thus copyright may be infringed.
[0011]
In the second prior art, a control command and a call signal are transmitted and received via one channel, and a predetermined time is always required to compare the control command by a comparison circuit. For this reason, noise caused by the control command can be reduced, but cannot be completely eliminated.
[0012]
An object of the present invention is to provide a transmission system that can transmit and receive a predetermined information signal only between predetermined devices.
[0013]
It is another object of the present invention to provide a transmission system capable of preventing abnormal sound generated due to a signal transmitted between predetermined devices.
[0014]
[Means for Solving the Problems]
The present invention generates and transmits a transmission notification signal indicating that a predetermined information signal is transmitted, and a first device that transmits the information signal by receiving transmission permission information, and a first device that transmits the information signal. In response to the transmission notification signal, when the reception of the information signal recognized by the transmission notification signal can be acknowledged, a transmission permission signal indicating that the information signal can be transmitted by the first device is generated. A second device that transmits to one device and receives an information signal transmitted from the first device;
A first transmission medium provided between the first device and the second device for transmitting a transmission notification signal and a transmission permission signal;
A transmission system provided between a first device and a second device and including a second transmission medium for transmitting an information signal.
[0015]
According to the present invention, in order to transmit a predetermined information signal from the first device to the second device, first, the first device transmits a transmission notification signal to the second device. When the transmission notification signal is received by the second device, when the reception can be acknowledged, a transmission permission signal is generated, and this signal is transmitted to the first device. The first device can transmit the predetermined information signal to the second device only by receiving the transmission permission signal.
[0016]
That is, even if the first device transmits the transmission notification signal, it does not transmit the predetermined information signal unless receiving the transmission permission signal from the second device. The second device does not generate the transmission permission signal unless it can understand the reception of the information signal. As described above, the predetermined information signal is not transmitted unless the first device and the second device perform mutual authentication. Therefore, transmission and reception of a predetermined information signal can be performed only between predetermined devices.
[0017]
Further, the transmission notification signal and the transmission permission information are transmitted by the first transmission medium, and the predetermined information is transmitted by the second transmission medium. Therefore, the predetermined information signal includes noise caused by the transmission notification signal and the transmission permission information. Is not included. Therefore, it is possible to prevent the predetermined information signal transmitted from the first device to the second device from deteriorating and deteriorating in quality.
[0018]
Also, the present invention provides the first device,
Power supply detecting means for detecting a state of the power supply;
When the power supply is in an abnormal state based on a detection result detected by the power supply detecting means, an abnormal signal transmitting means for transmitting an abnormality occurrence signal indicating that the power supply is in an abnormal state via the first transmission medium is provided. And
The second device includes:
An input unit interconnected with the second transmission medium and receiving an information signal;
An output unit that outputs an information signal input from the input unit to the outside,
Connection means provided between the input unit and the output unit, the connection means for disconnectably connecting the input unit and the output unit,
When an abnormality occurrence signal transmitted from the first device is received, the connection unit is controlled so that the information signal input from the input unit is output from the output unit to the outside before the input unit and the output unit are connected to each other. And a second control means for cutting.
[0019]
According to the present invention, when the power supply is in an abnormal state, the abnormal signal transmission unit transmits an abnormality occurrence signal to the second device via the first transmission medium. When the power supply becomes abnormal, the amplitude of the predetermined information signal transmitted from the first device changes, and the information signal changes to an information signal different from the predetermined information signal. When the second control unit of the second device receives the abnormality occurrence signal, before the information signal input from the input unit is output from the output unit to the outside of the amplifying device, the connection unit is controlled to control the input unit. Disconnect from the output unit. As a result, the predetermined information signal in the abnormal state is not output from the output unit.
[0020]
Also, the present invention provides the first device,
Power supply detecting means for detecting a state of the power supply;
When the power supply is in an abnormal state, based on a detection result detected by the power supply detection means, a signal cutoff means for cutting off transmission of an information signal is provided.
[0021]
According to the invention, the signal cutoff unit cuts off transmission of a predetermined information signal based on the state of the power supply detected by the power supply detection unit if the power supply is abnormal. Thereby, it is possible to prevent the predetermined information signal in the abnormal state from being transmitted to the second device.
[0022]
Further, according to the present invention, the first device is an audio information reading device that reads an audio information signal recorded on a recording medium,
The second device is an amplifying device,
The information signal is an acoustic information signal, and is represented by a 1-bit signal that is delta-sigma modulated.
[0023]
According to the present invention, a transmission notification signal and a transmission permission signal are transmitted and received before transmitting the audio information signal from the first device as the audio signal reading device to the second device as the amplification device. The acoustic signal reading device receives the transmission notification signal and transmits the acoustic information signal only to an amplifier that can transmit the transmission permission signal. That is, the audio signal reading device does not output an audio information signal to a device that is not mutually authenticated. Therefore, it is possible to prevent the acoustic information signal from being freely recorded on the recording medium by, for example, an acoustic information recording device that records the acoustic information signal. As a result, it is possible to prevent a literary work such as audio information from being copied by an unspecified number of audio recording devices, thereby preventing copyright infringement.
[0024]
Further, for example, when a predetermined information signal is transmitted from the sound reproducing device to the amplifying device, if the power of the sound reproducing device is suddenly cut off, the delta-sigma modulated 1-bit signal transmitted from the first device is During the power-off process, the amplitude is attenuated or suddenly disappears, resulting in an abnormal state. In such a state, it is prevented that the amplifying apparatus receives the abnormality occurrence signal and amplifies and outputs the 1-bit signal in the abnormal state to the outside. Therefore, for example, when a speaker or the like is connected to the output section of the amplifier, it is possible to prevent the speaker from generating an abnormal sound.
[0025]
Further, the present invention is a method for transmitting an acoustic signal in a transmission system having a first transmission medium and a second transmission medium, and transmitting an acoustic information signal from a first device to a second device, wherein the first device comprises: Transmitting a transmission notification signal indicating that a predetermined acoustic information signal is transmitted to the first device via the transmission medium;
When the second device can acknowledge the reception of the information signal recognized by the transmission notification signal in response to the transmission notification signal via the first transmission medium, the first device can transmit the information signal. Transmitting a transmission permission signal to the first device,
The first device transmits an acoustic information signal to a second device via a second transmission medium by receiving the transmission permission information.
[0026]
According to the present invention, in order to transmit an acoustic information signal from the first device to the second device, first, the first device transmits a transmission notification signal to the second device. When the transmission notification signal is received by the second device, when the reception can be acknowledged, a transmission permission signal is generated, and this signal is transmitted to the first device. The first device transmits the acoustic information signal to the second device for the first time by receiving the transmission permission signal.
[0027]
That is, even if the first device transmits the transmission notification signal, it does not transmit the acoustic information signal unless it receives the transmission permission signal from the second device. The second device does not generate the transmission permission signal unless it can understand the reception of the information signal. As described above, unless the first device and the second device perform mutual authentication, no acoustic information signal is transmitted. Therefore, transmission and reception of acoustic information signals can be performed only between predetermined devices.
[0028]
Further, the transmission notification signal and the transmission permission information are transmitted by the first transmission medium, and the predetermined information is transmitted by the second transmission medium. Therefore, noise caused by the transmission notification signal and the transmission permission information is included in the acoustic information signal. Not included. Therefore, it is possible to prevent the quality of the acoustic information signal transmitted from the first device to the second device from being degraded.
[0029]
BEST MODE FOR CARRYING OUT THE INVENTION
FIG. 1 is a block diagram showing a transmission system 1 according to one embodiment of the present invention. The transmission system 1 is an audio reproduction system, and includes an audio information reading device 2 as a first device, an amplification device 3 as a second device, a first signal line 4 as a first transmission medium, and a second transmission device. It includes a second signal line 5 as a medium and a speaker 6. In this embodiment, a connection means at least an electrical connection.
[0030]
The audio information reading device 2 includes a recording medium reading unit 11, a 1-bit extraction conversion unit 12, a reading-side external signal input unit 13, a reading-side 1-bit signal conversion unit 14, a reading-side input switching unit 15, A bit signal output unit 16, a first control unit 17, a 1-bit signal external output unit 18, a control switch 19, a read-side signal input / output unit 21, a power cord 22, a power switch 23, a main regulator unit 24, a voltage detection and control unit 25, a sub-regulator unit 26, and a capacitor 27.
[0031]
The recording medium reading unit 11 reads an audio information signal recorded on a disk-shaped recording medium such as a compact disk (Compact Disk: abbreviated CD) and a super audio CD (Super Audio CD: abbreviated SACD). The recording medium reading unit 11 has an optical pickup device for optically reading an acoustic information signal recorded on the disk-shaped recording medium.
[0032]
The one-bit extraction converter 12 is interconnected with the recording medium reading unit 12. When the audio information signal read by the recording medium reading unit 12 is represented by a 1-bit signal subjected to delta sigma modulation, the 1-bit extraction converter 12 outputs the 1-bit signal as it is. If the audio information signal read from the disk-shaped recording medium 12 is not represented by a delta-sigma-modulated 1-bit signal, the 1-bit extraction converter 12 performs delta-sigma modulation on the audio information signal, and Convert to a bit signal and output.
[0033]
In delta-sigma modulation, an analog signal is applied to an integrator by a circuit combining a 1-bit converter and an integrator, and the output is converted into a digital signal bit stream by the converter. The bit stream of this digital signal is a 1-bit signal. At this time, the digital signal converted by the converter is converted into an analog signal and fed back to the integrator. As a result, an error between the analog signal and the preceding signal output by the converter is input to the integrator. Therefore, finally, a one-bit signal that minimizes this error is generated.
[0034]
The reading-side external signal input unit 13 is an interface for inputting a predetermined signal to the acoustic information reading device 2 from outside the acoustic information reading device 2. The predetermined signal is, for example, an analog signal representing an audio information signal.
[0035]
The read-side 1-bit signal conversion unit 14 is interconnected with the read-side external signal input unit 13 and delta-sigma modulates a predetermined signal from the read-side external signal input unit 13 to convert it into a 1-bit signal and output it. I do.
[0036]
The read-side input switching unit 15 selectively connects the one-bit extraction conversion unit 12 and the one-bit signal conversion unit 14 to the one-bit signal output unit 16. The read-side input switching unit 15 has two input terminals and one output terminal. One of the two input terminals is mutually connected to the output side of the 1-bit extraction and conversion unit 12, and the other is mutually connected to the output side of the read-out 1-bit signal conversion unit 14. The output terminal is connected to the 1-bit signal output unit 16. The selection of the connection by the read-side input switching means 15 is manually performed by an operator, for example.
[0037]
The 1-bit signal output unit 16 receives the 1-bit signal from the read-side input switching unit 15 and outputs the 1-bit signal to the 1-bit signal external output unit 18 under the control of the first control unit 17. .
[0038]
FIG. 2 is a waveform diagram showing a 1-bit signal and a clock signal output from 1-bit signal output section 16. In the one-bit signal and the clock signal shown in FIG. 2, the horizontal axis represents time, and the vertical axis represents amplitude. The 1-bit signal output unit 16 simultaneously outputs a 1-bit signal and a clock signal corresponding to the 1-bit signal and defining a 1-bit interval t1 in the 1-bit signal.
[0039]
The 1-bit signal external output unit 18 is an interface for outputting a 1-bit signal to the outside of the audio information reading device 2. The 1-bit signal external output unit 18 is mutually connected to one end of the second signal line 5. The 1-bit signal external output section 18 outputs the 1-bit signal and the clock signal from the 1-bit signal output section 16 to the second signal line 5.
[0040]
The first control unit 17 controls the 1-bit signal output unit 16 to output a 1-bit signal, which is a predetermined information signal, to the 1-bit signal output unit 16. Further, the first control means 17 generates a transmission notification signal indicating that the one-bit signal is transmitted, and transmits the signal via the control switch 19 and the read-side signal input / output unit 21. Further, the first control means 17 receives a transmission permission signal from the amplifier 3. The detailed processing operation of the first control means 17 will be described later. The first control unit 17 is connected to the read-side signal input / output unit 21 via the control switch 19. The first control means 17 is realized by, for example, a microcomputer.
[0041]
Further, the first control unit 17 transmits a strobe signal and a clock signal for permitting communication via the control switch 19.
[0042]
When the transmission notification signal and the transmission permission signal are not being transmitted or received, the first control means 17 transmits the steady signal maintained at a predetermined constant signal level to the control switch 19 and the read-side signal input / output unit 21. To send through.
[0043]
The control switch 19 is realized by, for example, a gate element and a relay. The control switch 19 is controlled by the voltage detection and control unit 25. For example, when the control switch 19 is realized by a gate element such as an AND (AND) gate and a NAND (NAND) gate, the gate element has a two-input condition. A signal is input to the other input terminal of the control signal from a voltage detection and control unit 25 described later.
[0044]
Further, for example, when the control switch 19 is realized by a relay, a voltage detection and control (described later) from an input terminal for conducting (ON) or non-conducting (OFF) the control switch 19 from the voltage detection and control unit 25 is performed. The control signal from the control unit 25 is input. When the control switch 19 is realized by a relay, the switch is opened, so a pull-down resistor for determining the potential is connected to the first signal line 4.
[0045]
The reading-side signal input / output unit 21 is an interface for transmitting a predetermined signal from the acoustic information reading device 2 to the outside and receiving a predetermined signal from the outside. The read-side signal input / output unit 21 is mutually connected to one end of the first signal line 4.
[0046]
The power cord 22 is connected to a main regulator unit 24 via a power switch 23. A plug is provided at one end of the power cord 22, and the plug is connected to an outlet of a commercial AC power supply. The power switch 23 connects or disconnects the power cord 22 and the main regulator unit 24. By closing the contact of the power switch 23, power is supplied to the main regulator unit 24. The switching operation of the power switch 23 is performed by an operator.
[0047]
The main regulator unit 24 converts the voltage of the commercial AC power supplied via the power cord 22 and the power switch 23 into a predetermined voltage, and then rectifies and outputs the DC voltage. The main regulator unit 24 is realized by, for example, a switching regulator. The input terminal of the main regulator unit 24 is mutually connected to the power switch 23.
[0048]
The voltage detection and control unit 25 is mutually connected to an output terminal of the main regulator unit 24, and detects a state of a power supply, specifically, a voltage converted by the main regulator unit 24. Then, the voltage detection and control unit 25 determines whether or not the power supply is in an abnormal state from the detected voltage value, and when it determines that the power supply is in an abnormal state, gives a control signal to the control switch 19 to perform control. The switch 19 is controlled to transmit an abnormality occurrence signal from the signal input / output unit 21.
[0049]
The voltage detection and control unit 25 is realized by, for example, an A / D converter built-in microcomputer or a circuit in which a comparator and a microcomputer are combined. As the detection position where the voltage detection unit 25 detects the voltage, a position that does not have a large time constant and reacts in a short time as soon as the power is turned off is selected.
[0050]
The detailed processing operation of the voltage detection and control unit 25 will be described later. The voltage detection and control unit 25, the control switch 19, and the first control unit 17 constitute an abnormal signal transmission unit.
[0051]
The sub-regulator unit 26 includes a plurality of regulators. The sub-regulator 26 is connected to the main regulator 24 and converts the voltage converted by the main regulator 24 into a predetermined voltage. The sub-regulator unit 26 supplies power to each unit of the audio information reading device 2, for example, the 1-bit extraction conversion unit 12, the reading 1-bit signal conversion unit 14, the 1-bit signal output unit 16, and the first control unit 17.
[0052]
One end of a capacitor 27 is connected between the output terminal of the main regulator unit 24 and the input terminal of the sub-regulator unit 26. The other end of the capacitor 27 is grounded. Thus, even if the contact of the power switch 23 is opened and power is no longer supplied to the main regulator 24, a sharp drop in the voltage input to the sub regulator 26 can be prevented. Therefore, it is possible to prevent the sub-regulator 26 and the components of the acoustic information reading device 2 from failing due to a sudden voltage change.
[0053]
The amplification device 3 includes a 1-bit signal input unit 31, an amplification-side external signal input unit 32, an amplification-side 1-bit signal conversion unit 33, an amplification-side input switching unit 34, a waveform shaping unit 35, and a second control unit. 36, a volume adjusting unit 37, a 1-bit amplifying unit 38, a mute output control element 39, an amplifying-side external output unit 41, and an amplifying-side signal input / output unit 42.
[0054]
The 1-bit signal input unit 31 is an interface for inputting a 1-bit signal and a clock signal from outside the amplification device 3. The 1-bit signal input unit 31 is mutually connected to the other end of the second signal line 5.
[0055]
The amplification-side external signal input unit 32 is an interface for inputting a predetermined signal from outside the amplification device 3. The predetermined signal is, for example, an analog signal indicating predetermined information.
[0056]
The amplification-side 1-bit signal converter 33 has the same configuration as the above-described read-side 1-bit signal converter 14. The amplification-side 1-bit signal converter 33 converts a predetermined signal input from the amplification-side signal input unit 32 into a 1-bit signal by delta-sigma modulation and outputs the signal.
[0057]
The amplification-side input switching unit 34 selectively connects the 1-bit signal input unit 31 and the amplification-side 1-bit signal conversion unit 33 to the waveform shaping unit 35. The selection of the connection by the amplification-side input switching means 34 is performed by the second control means 36.
[0058]
The amplification-side input switching unit 34 is realized by, for example, a combination circuit of a multiplexer and a gate element.
[0059]
FIG. 3 is a block diagram illustrating an example of a configuration of the amplification-side input switching unit 34. The amplification-side input switching unit 34 illustrated in FIG. The multiplexer 61 is provided with input terminals A0, A1, B0, B1, output terminals OUT1, OUT2, and a switching input terminal SELECT. The multiplexer 61 connects the input terminals A0 and A1 to the output terminals OUT1 and OUT2 by supplying a high (H) level signal or a low (L) level signal from the second control means 36 to the switching input terminal SELECT. , Or input terminals B0 and B1 are connected to output terminals OUT1 and OUT2, respectively.
[0060]
The input terminals A0 and A1 are mutually connected to the output side of the 1-bit signal input unit 31, for example, a 1-bit signal is supplied to the input terminal A0, and a clock signal is supplied to the input terminal A1. The input terminals B0 and B1 are interconnected with the output side of the amplification-side 1-bit signal converter 33. For example, the input terminal B0 is supplied with a 1-bit signal, and the input terminal B1 is supplied with a clock signal. The output terminals OUT1 and OUT2 are mutually connected to the waveform shaping means 35.
[0061]
FIG. 4 is a block diagram illustrating another example of the configuration of the amplification-side input switching unit 34. The amplification-side input switching unit 34 shown in FIG. 4 is realized by a gate element, that is, a combination circuit 71 of logic gates. The amplification-side input switching section 34 is configured to include first to fourth AND gates 72 to 75, first and second OR gates 76 and 77, and an inverter 78. One input terminals A0 and A1 of the first and third AND gates 72 and 74 are mutually connected to the output side of the 1-bit signal input unit 31. For example, a 1-bit signal is applied to input terminal A0, and a clock signal is applied to input terminal A1. The other input terminals of the first and third AND gates 72 and 74 are connected to each other, and are connected to the second control means 36 via the switching input terminal SELECT.
[0062]
One input terminals B0 and B1 of the second and fourth AND gates 73 and 75 are mutually connected to the output side of the amplification-side 1-bit signal conversion unit 33. For example, a 1-bit signal is applied to input terminal B0, and a clock signal is applied to input terminal B1. The other input terminals of the first and third AND gates 72 and 74 are connected to each other and to the output terminal of the inverter 78. The input terminal of the inverter 78 is connected to the second control means 36 via the switching input terminal SELECT.
[0063]
Output terminals of the first and second AND gates 72 and 73 are connected to input terminals of the first OR gate 76, respectively. Output terminals of the third and fourth AND gates 74 and 75 are connected to input terminals of the second OR gate 77, respectively. The output terminal OUT0 of the first OR gate 76 and the output terminal OUT1 of the second OR gate 77 are mutually connected to the waveform shaping means 35.
[0064]
By providing a high (H) level signal or a low (L) level signal from the second control means 36 to the switching input terminal SELECT, the input terminals A0 and A1 are connected to the output terminals OUT1 and OUT2, respectively. Terminals B0 and B1 are connected to output terminals OUT1 and OUT2, respectively.
[0065]
The waveform shaping unit 35 receives the 1-bit signal from the amplification-side input switching unit 34, adjusts the waveform of the 1-bit signal, and outputs the adjusted signal.
[0066]
FIG. 5 is a diagram illustrating the waveform shaping unit 35. The waveform shaping means 35 is realized by a D flip-flop. A 1-bit signal is input to the D terminal 35A of the D flip-flop, and a clock signal is input to the CK terminal 35B. Thereby, the waveform of the 1-bit signal is shaped based on the clock signal, and the shaped 1-bit signal is output from the Q terminal 35C of the D flip-flop.
[0067]
If the peak value A1 of the input 1-bit signal and the clock signal is larger than a predetermined threshold value A2, the waveform shaping unit 35 completely suppresses the noise effect on the signal system such as the second signal line 5. Can be. Thus, the 1-bit signal output from the waveform shaping unit 35 can be shaped into the same signal as the 1-bit signal output from the 1-bit signal output unit 16.
[0068]
The predetermined threshold A2 is determined by the input threshold of the waveform rectifier 35. Therefore, the predetermined threshold value A2 is determined by the elements constituting the waveform shaping means 35. For example, if the waveform shaping means 35 is a CMOS (
In the case of using a metal oxide semiconductor (Contemporary Metal Oxide Semiconductor) element, the predetermined threshold value A2 is about 0.7 × (supply voltage to this CMOS element). Further, for example, when the waveform shaping means 35 is configured by a TTL (Transistor Transistor Logic) element, the predetermined threshold value is about 0.4 × (supply voltage to this TTL element). However, since the threshold value varies depending on each element, a predetermined threshold value A2 is set with a margin for the value obtained by each of the above equations.
[0069]
The volume adjusting unit 37 is a volume adjusting unit. An input terminal of the volume adjusting unit 37 is mutually connected to an output terminal of the waveform shaping unit 35. The volume adjusting means 37 has a variable resistor, and can change the resistance value to adjust the volume output from the speaker 6 described later. The adjustment of the volume by the volume adjusting means 37 is performed by the operator.
[0070]
The 1-bit amplifier 38 receives the 1-bit signal output from the volume adjusting unit 37 and power-amplifies the 1-bit signal. The 1-bit amplifying unit 38 includes a low-pass filter, converts a 1-bit signal into an analog signal, and outputs the analog signal.
[0071]
The mute output control element 39 is realized by a switching element capable of transmitting an analog signal, for example, a relay. The mute output control element 39 disconnectably connects the output terminal of the 1-bit amplifying section 38 and the amplification-side external output section 41. The mute output control element 39 is controlled by the second control means 36 to open and close its contact.
[0072]
The amplification-side external output unit 41 is an interface for outputting the 1-bit signal power-amplified by the 1-bit amplification unit 38 to the outside. The amplification-side external output section 41 is mutually connected to the mute output control element 39. The amplification-side input switching section 34 and the mute output control element 39 are connection means for disconnectably connecting the 1-bit signal input section 31 as an input section and the amplification-side external output section 41 as an output section.
[0073]
The second control unit 36 controls the amplification-side input switching unit 34 and the mute output control element 39 to disconnect or connect the 1-bit signal input unit 31 and the amplification-side external output unit 41. The second control means 36, in response to the transmission notification signal, can recognize that the information signal recognized by the transmission notification signal can be received by the acoustic information reading device 2 when it can transmit the 1-bit signal. A transmission permission signal is generated and transmitted to the acoustic information reading device 2. The second control means 36 is realized by, for example, a microcomputer.
[0074]
Further, when the second control means 36 receives the abnormality occurrence signal, the second control means 36 controls the amplification-side input switching section 34 and the mute output control element 39 to connect the 1-bit signal input section 31 and the amplification-side external output section 41 with each other. Disconnect. The detailed processing operation of the second control means 36 will be described later. The second control means 36 is mutually connected to the amplification-side signal input / output unit 42.
[0075]
The amplification-side signal input / output unit 42 is an interface for transmitting a predetermined signal transmitted from the second control unit 36 to the outside of the amplification device 3 and receiving a predetermined signal from the outside. The amplification-side signal input / output unit 42 is mutually connected to the other end of the first signal line 4.
[0076]
The amplifying device 3 is provided with a power switch, a power cord, and a regulator (not shown). By connecting the power cord to the outlet and closing the contact of the power switch, for example, the power cord, the amplification-side 1-bit signal conversion section 33, the waveform shaping circuit 35, the second control means 36 and the 1-bit amplification section 38 Power is supplied via a power switch and a regulator.
[0077]
The first signal line 4 is provided between the acoustic information reading device 2 and the amplification device 3 and transmits a transmission notification signal, a transmission permission signal, and an abnormality occurrence signal. The first signal line 4 is realized by, for example, a metal cable.
[0078]
In the present embodiment, the first signal line 4 includes a first A signal line for transmitting the above-described strobe signal, a first B signal line for transmitting the clock signal, a transmission permission signal from the acoustic information reading device 2, and an abnormality occurrence signal. And a first D signal line for transmitting a transmission permission signal from the amplifying device 3.
[0079]
In a state in which the transmission notification signal, the transmission permission signal, and the abnormality occurrence signal are not transmitted and received, the first control means 17 transmits a steady signal maintained at a predetermined constant signal level to the second control means 36. I have. The transmission notification signal, the transmission permission signal, and the abnormality occurrence signal are transmitted or received between the first control means 17 and the second control means 36 by changing the peak value of the stationary signal.
[0080]
The second signal line 5 is provided between the acoustic information reading device 2 and the amplifying device 3 and transmits a 1-bit signal. The second signal line 5 is realized by, for example, a metal cable. The second signal line 5 includes a plurality of signal lines. In the present embodiment, the second signal line 5 includes two signal lines of the above-described signal line for transmitting the 1-bit signal and the signal line for transmitting the clock signal.
[0081]
In the embodiment of the present invention, second signal line 5 may include a plurality of signal lines for transmitting 1-bit signals.
[0082]
The speaker 6 is connected to the amplification-side external output unit 41, converts a 1-bit signal, which is an acoustic information signal, into a sound wave, and outputs the sound wave.
[0083]
FIG. 6 is a flowchart showing the operation of the first control means 17 when transmitting a 1-bit signal from the acoustic information reading device 2 to the amplifying device 3.
[0084]
When the reading of the acoustic information signal from the disc-shaped recording medium by the acoustic information reading unit 11 is started, the process proceeds from step A0 to step A1, and the operation is started. In step A1, a transmission notification signal indicating that a predetermined information signal is transmitted is generated, and the process proceeds to step A2. The transmission notification signal is configured to include predetermined data. The predetermined data is represented, for example, by “10011001”.
[0085]
In step A2, a strobe signal, a transmission notification signal, and a clock signal are transmitted to the amplifier 3, and the process proceeds to step A3. The strobe signal, the transmission notification signal, and the clock signal transmitted from the first control unit 17 are transmitted to the amplification device 3 via the control switch 19, the read-side signal input / output unit 21, and the first signal line 4.
[0086]
In step A3, it is determined whether a transmission permission signal has been received. If it is determined in step A3 that the transmission permission signal has been received, the process proceeds to step A4. On the other hand, if it is determined in step A3 that the transmission permission signal has not been received, step A3 is repeated after a predetermined time.
[0087]
The transmission permission signal is configured to include predetermined data. The predetermined data is represented by, for example, “10011001” obtained by inverting each bit data of the transmission notification signal. The first control means 17 determines whether the received data matches the predetermined data.
[0088]
In step A4, the 1-bit signal output unit 16 is controlled to output a 1-bit signal from the 1-bit output control unit 16 to the 1-bit signal external output unit 18, and the operation proceeds to step A5 to end the operation. As a result, a 1-bit signal is output from the 1-bit signal output unit 16, and the 1-bit signal is transmitted to the amplifier 3 via the 1-bit signal external output unit 18 and the second signal line 5. The flowchart shown in FIG. 6 can be terminated by opening the contact of the power switch 23.
[0089]
FIG. 7 is a flowchart showing the operation of the voltage detection and control unit 25. When the contact of the power switch 23 is closed, the process moves from step B0 to step B1. In step B1, the voltage output from the main regulator unit 24 is detected, and the process proceeds to step B2. In step B2, it is determined whether the power supply is in an abnormal state, that is, whether the voltage is abnormal information. Specifically, it is determined whether the voltage value detected in step B1 is equal to or higher than a predetermined voltage value. If it is determined in step B1 that the voltage is abnormal, that is, smaller than the predetermined voltage value, the process proceeds to step B3. On the other hand, if it is determined in step B2 that the voltage is not in an abnormal state, that is, if it is determined that the voltage is equal to or higher than a predetermined voltage value, the process proceeds to step B1.
[0090]
The predetermined voltage value indicates how long after the supply of power from the power supply is interrupted and the abnormal sound is generated from the speaker 6, and at that time, the acoustic information reading device 2 transmits the abnormal sound to the amplifying device 3. A method of attenuating each signal transmitted through one signal line 4 and a one-bit signal transmitted through second signal line 5, and attenuating a voltage supplied from a power supply circuit to a circuit element transmitting each signal For example, it is obtained from the control time of the voltage detection and control means 25, the response time of the amplifier 3, and the like. The predetermined voltage value is determined so that various conditions are comprehensively matched so that, for example, a short-term power supply fluctuation does not cause an over-response.
[0091]
In Step B3, the control switch 19 is controlled. For example, when the control switch 19 is implemented by a logic gate element such as an AND gate and a NAND gate, the logic gate element has a two-input condition. And a control signal from the voltage detection and control unit 25 for controlling the control switch 19 is input to the other input terminal as a condition signal.
[0092]
Further, for example, when the control switch 19 is realized by a relay, the control switch 19 is controlled by using a control signal for controlling the control switch 19 from the voltage detection and control unit 25 as a relay switching signal.
[0093]
As a result, the abnormality occurrence signal is transmitted to the amplification device 3 via the read-side signal input / output unit 21 and the first signal line 4, and the operation ends.
[0094]
When the contact of the power switch 23 is closed, the first control means 17 sends out the above-mentioned steady signal. In step B3, the voltage detection and control unit 25 controls the control switch 19 to change the steady-state signal with the second control means 36 for a time t2 or more. Thereby, the abnormality occurrence signal is transmitted.
[0095]
That is, when the voltage detection and control unit 25 controls the control switch 19, an abnormality occurrence signal that is different from the steady signal transmitted from the first control unit 17 is transmitted to the second control unit 36. The time t2 negotiated with the second control means 36 is a time of a state changed from a steady signal which may be caused by a change in communication, that is, a steady signal when the transmission notification signal and the transmission permission signal are transmitted. Is set sufficiently longer than the time when the peak value changes.
[0096]
The voltage detection and control unit 25 determines that the amplitude value of the 1-bit signal or the clock signal is gradually reduced due to a change in the voltage supplied to each unit of the audio information reading device 2 when the audio information reading device 2 is disconnected from the power supply for some reason. In such a case, an acoustic information signal in an abnormal state is output to the speaker 6, and time control is performed so that the speaker 6 does not generate an abnormal sound. This is because, when a voltage abnormality occurs, the voltage detection and control unit 25 detects the voltage, determines the detection result, and transmits a detection response time t3 until an abnormality occurrence signal is transmitted, and a 1-bit signal for each unit. The transmission related components, that is, the 1-bit extraction and conversion unit 12, the read-side 1-bit signal conversion unit 14, the 1-bit signal control output unit 16, the voltage decay time t4 of the sub-regulator unit 26, and the second control unit 36 The response time t5 from when the abnormality occurrence signal is received to when it is determined that the abnormality occurrence signal is received can be realized by managing the time constant in total.
[0097]
In order to prevent abnormal sound from being generated from the speaker 6, the detection response time t3 and the response time t5 are set as short as possible, and the voltage decay time t4 is set as long as possible. These relationships are represented by the following equation (1).
(T3 + t5) <t4 (1)
[0098]
When the acoustic information reading device 2 is disconnected from the power supply for some reason, first, the voltage of the main regulator unit 24 is attenuated, and the voltage of each sub-regulator unit 26 is attenuated from the time when the voltage cannot be supplied to each sub-regulator unit 26. Begin to. In order to achieve the time constant as shown in the above equation (1), the circuit related to the transmission of the 1-bit signal and the sub-regulator supplying the voltage detection and control unit 25 have a slow attenuation of the supplied voltage. Avoid sharing the power supply with other circuits. The power supply may be increased by providing an electrolytic capacitor or the like in the sub-regulator as necessary. With such a configuration, it is possible to reliably prevent abnormal sound from being generated from the speaker 6 when the power is inadvertently turned off.
[0099]
When the first signal line 4 is constituted by a plurality of signal lines, the transmission of the abnormality occurrence signal is performed by any one or a plurality of the plurality of signal lines.
[0100]
FIG. 8 is a flowchart showing the operation of the second control means 36. When the contact of the power switch of the amplifier 3 is closed, the process proceeds from step C0 to step C1. In step C1, it is determined whether a transmission notification signal has been received. If it is determined in step C1 that the transmission notification signal has been received, the process proceeds to step C2. On the other hand, if it is determined in step C1 that the transmission notification signal has not been received, step C1 is repeated after a predetermined time.
[0101]
In step C2, it is determined whether or not the reception of the information signal recognized by the transmission notification signal can be acknowledged. As described above, the transmission permission signal is configured to include predetermined data, and the second control unit 36 determines whether or not the received data matches the predetermined data.
[0102]
If it is determined in step C2 that the reception can be understood, the process proceeds to step C3. On the other hand, if it is determined in step C2 that the reception cannot be acknowledged, step C2 is repeated after a predetermined time.
[0103]
In Step C3, the acoustic information reading device 2 generates a transmission permission signal indicating that the predetermined information signal can be transmitted, and proceeds to Step C4. As described above, the transmission permission signal is configured to include the predetermined data as described above, and is realized by, for example, data obtained by inverting each bit data of the transmission notification signal.
[0104]
In step C4, a transmission permission signal is transmitted, and the process proceeds to step C5. The transmission permission signal transmitted from the second control unit 36 is transmitted to the acoustic information reading device 2 via the amplification-side signal input / output unit 42 and the first signal line 4.
[0105]
In step C5, the input switching unit 34 is controlled to connect the 1-bit signal input unit 31 and the waveform shaping unit 35, and at the same time, sends a predetermined control signal to the mute output control element 39, and proceeds to step C6. . As a result, the 1-bit signal input section 31 and the amplification-side external output section 41 are connected to the amplification-side input switching section 34, the waveform shaping section 35, the volume adjustment section 37, the 1-bit amplification section 38, and the mute output control element. 39.
[0106]
The second control means 36 sends a predetermined signal, for example, an H (high) level signal or an L (low) level signal to the input switching section 34 and the mute output control element 39 to control them.
[0107]
In step C6, it is determined whether an abnormality occurrence signal has been received. If it is determined in step C6 that the abnormality occurrence signal has been received, the process proceeds to step C7, and if it is determined that the abnormality occurrence signal has not been received, step C6 is repeated after a predetermined time.
[0108]
In step C7, the input switching section 34 is controlled to disconnect the 1-bit signal input section 31 and the waveform shaping section 35, and the mute output control element 39 is controlled to control the 1-bit signal input section 31 and the external amplification side. After disconnecting the output unit 41, the process proceeds to step C8, and the operation ends. The flowchart shown in FIG. 7 can be ended by opening the contact point of the power switch of the amplifier 3.
[0109]
Further, in still another embodiment of the present invention, in the above-described step C7, the mute output control element 39 is controlled to disconnect the 1-bit amplifying section 38 and the amplifying-side external output section 41. By controlling the input switching unit 34, the 1-bit signal input unit 31 and the waveform shaping unit 35 are disconnected. By disconnecting the mute output control element 39 near the amplification-side external output section 41 first, the occurrence of abnormal sound from the speaker 6 can be reliably prevented.
[0110]
FIG. 9 is a diagram illustrating an example of a communication format when the acoustic information reading device 2 and the amplification device 3 transmit and receive the transmission notification signal and the transmission permission signal. FIG. 9 shows a strobe signal transmitted by the first A signal line, a clock signal transmitted by the first B signal line, and a transmission notification as a data signal transmitted from the acoustic information reading device 2 transmitted by the first C signal line. 5 shows a signal and a transmission permission signal which is a data signal transmitted from the amplifying device 3 via the first D signal line. In the strobe signal, clock signal, transmission notification signal, and transmission permission signal shown in FIG. 9, the horizontal axis represents time, and the vertical axis represents amplitude.
[0111]
In the transmission system 1, as shown in the flowcharts of FIGS. 6 to 8, the initiative of communication is basically in the acoustic information reading device 2. The transmission notification signal, which is a strobe signal, a clock signal, and a data signal, is output from the acoustic information reading device 2.
[0112]
When communication is not performed between the acoustic information reading device 2 and the amplification device 3, the first A signal line, the first B signal line, the first C signal line, and the first D signal line have a predetermined constant level of steady state. A signal is being transmitted. Here, it is assumed that the predetermined constant signal is a high (H) level signal.
[0113]
When transmitting the information notification signal, the acoustic information reading device 2 changes the signal level of the first A signal line from high (H) to low (L) and transmits the strobe signal. Along with this, a clock signal is transmitted from the acoustic reading device 2 via the first B signal line, and a data signal is transmitted via the first C signal line. The data signal is transmitted in a range of the first half time T1 of the time T0 during which the strobe signal and the clock signal are transmitted.
[0114]
If the amplifier 3 can accept the data from the audio information reading device 2, the amplification device 3 extracts the data from the clock signal transmitted from the audio information reading device 2 and the data signal transmitted through the first C signal line. Read the meaning of the data transmitted by the signal. When this data indicates a transmission notification signal, it is determined whether or not the signal can be received according to the flowchart of FIG. 3, and the strobe signal and the clock signal are transmitted according to the clock signal transmitted from the acoustic information reading device 2. The data indicating the transmission permission information is transmitted to the sound reproducing device 2 by the first C signal line in the range of the second half of the set time T0. When the content of the signal permission signal can be confirmed, the acoustic information reading device 2 starts transmitting the acoustic information signal from the second signal line 5.
[0115]
In the embodiment of the present invention, the case where the acoustic information reading device 2 transmits the acoustic information signal to the amplifying device 3 has been described, but the transmission of the acoustic information signal transmitted from the acoustic information reading device 2 to the amplifying device 3 is performed. Even in the case of stopping, the same communication is performed between the first control means 17 and the second control means 36, and the second control means 36 controls the mute output control element 39 so that the speaker 6 does not generate an abnormal sound. And the amplification-side input switching unit 34.
[0116]
As described above, in the transmission system 1, only when the first control means 17 of the audio information reading device 2 and the second control means 36 of the amplifying device 3 mutually approve via the first signal line 4, the audio information reading device 2 , A 1-bit signal is transmitted to and received from the amplifier 3. Thus, transmission and reception of 1-bit signals can be performed only between predetermined devices. That is, it is not possible to freely record a 1-bit signal by connecting, for example, a sound recording device that is not mutually recognized to the 1-bit signal external output unit 18 of the acoustic information reading device 2. Therefore, since the audio information signal cannot be freely recorded on the recording medium, there is no possibility that the copyright is infringed.
[0117]
When the power supply is in an abnormal state, the acoustic information reading device 2 transmits an abnormality occurrence signal via the first signal line 4. Upon receiving the abnormality occurrence signal, the second control means 36 of the amplifying device 3 switches the amplification-side input switching before the 1-bit signal input from the 1-bit signal input unit 31 is output from the amplification-side external output unit 41. By controlling the section 34 and the mute output control element 39, the 1-bit signal input section 31 and the amplification-side external output section 41 are disconnected.
[0118]
As a result, the acoustic information signal in an abnormal state is not output from the amplification-side external output unit 41. Therefore, even if the power cord 22 is inadvertently pulled out of the power outlet or the contact of the power switch 23 is opened, it is possible to prevent the abnormal sound from being emitted from the speaker 6. Therefore, it is possible to prevent a problem that an undesired abnormal sound is emitted and the user of the transmission system 1 is surprised and uncomfortable.
[0119]
In still another embodiment of the present invention, the selection of the connection by the read-side input switching unit 15 may be performed by the first control unit 17.
[0120]
Further, in still another embodiment of the present invention, when an abnormal state of the power supply is detected by voltage detection and control section 25, the voltage detection means and control section 25 output a predetermined signal indicating the abnormal state to first signal. A configuration for transmitting to the control means 17 is also possible. When receiving the predetermined signal indicating that the power supply is in an abnormal state, the first control means 17 controls the 1-bit signal output unit 16 to cut off the transmission of the 1-bit signal. As a result, the predetermined information signal in the abnormal state is not transmitted to the amplifying device 3, and it is possible to prevent the speaker 6 from generating an abnormal sound. In this case, the first control unit 17 and the 1-bit signal output unit 16 are signal blocking units.
[0121]
Further, in still another embodiment of the present invention, when an abnormal state of the power supply is detected by the voltage detection and control unit 25, the voltage detection unit and the control unit 25 notify the first control unit 17 of a predetermined state indicating the abnormal state. A signal may be transmitted. When receiving a signal indicating that the power supply is in an abnormal state, the first control means 17 generates an abnormality occurrence signal and transmits the signal to the first signal line 4 via the control switch 19 and the read-side signal input / output unit 21. . In this case, since the control switch 19 does not need to be provided, the apparatus is further simplified.
[0122]
In still another embodiment of the present invention, a filter is provided between the mute output control element 39 and the amplification-side external output unit 41 so that the sound wave output from the speaker 6 has a predetermined frequency band. May be cut.
[0123]
FIG. 10 is a block diagram showing a part of an audio information reading device in a transmission system according to another embodiment of the present invention. The transmission system of the present embodiment has the same configuration as the transmission system 1 of the above embodiment, and uses a Zener diode 101 and a ground resistor 102 instead of the voltage detection and control unit 25. The voltage is detected by the Zener diode 101 and the ground resistor 102. Further, the control switch 19 of the present embodiment is realized by an AND gate.
[0124]
The anode of the Zener diode 110 is mutually connected to the output terminal of the main regulator unit 26, and the cathode is mutually connected to one input terminal of the control switch 19. Further, the cathode is grounded via a grounding resistor 102 having a predetermined resistance value.
[0125]
With such a configuration, the potential of the cathode of the Zener diode 101 is reduced, and the voltage supplied to the control switch 19 is reduced to near the input threshold of the AND gate. The voltage supplied to the control switch 19 is a voltage higher than a threshold value by a predetermined value. When the output voltage of the main regulator unit 24 decreases due to the power being cut off, the voltage applied to the Zener diode 101 decreases. When the voltage applied to the Zener diode 101 becomes smaller than the Zener voltage, the potential of the cathode of the Zener diode 101 sharply drops. As a result, the voltage input to the AND gate, which is the control switch 19, drops, and the input voltage changes from a high (H) level to a low (L) level smaller than the input threshold. It becomes a low (L) level. Thus, when the power is inadvertently turned off, the abnormality occurrence signal can be quickly transmitted to the amplifier 3.
[0126]
With such a configuration, the voltage detection and control unit 25 realized by a microcomputer or the like can be omitted, and the device can be simplified, and the same effect as the transmission system 1 can be obtained with a simple configuration. Can be achieved.
[0127]
FIG. 11 is a block diagram showing a part of an acoustic information reading device in a transmission system according to still another embodiment of the present invention. The transmission system of the present embodiment has the same configuration as the transmission system 1 of the embodiment shown in FIG. 1, and uses a resistor 103 instead of the Zener diode 101 of the acoustic information reading device shown in FIG. The voltage is detected by the resistor 103 and the ground resistor 102. Further, the control switch 19 of the present embodiment is realized by an AND gate.
[0128]
One end of the resistor 103 is mutually connected to the output end of the main regulator unit 26, and the other end is mutually connected to one input end of the control switch 19. The one end is grounded via a grounding resistor 102 having a predetermined resistance value.
[0129]
With such a configuration, the potential at one end of the resistor 103 is reduced, and the voltage supplied to the control switch 19 is reduced to near the input threshold of the AND gate. The voltage supplied to the control switch 19 is a voltage higher than a threshold value by a predetermined value. When the power supply is cut off and the output voltage of the main regulator section 24 drops, the voltage applied to the resistor 103 drops. As a result, the voltage input to the AND gate, which is the control switch 19, drops, and the input voltage changes from the high (H) level to the low (L) level, which is smaller than the input threshold, so that the output of the control switch 19 becomes , Low (L) level. Thereby, when the power is inadvertently turned off, an abnormality occurrence signal can be quickly transmitted to the amplifier 3.
[0130]
Further, with such a configuration, the voltage detection and control unit 25 realized by a microcomputer or the like can be omitted, and the device can be simplified, and the same effect as that of the transmission system 1 can be obtained with a simple configuration. Can be achieved.
[0131]
In still another embodiment of the present invention, the power supply from the one-bit extraction conversion part 12 to the one-bit signal output part 16 is strengthened, that is, power is supplied from the one-bit extraction conversion part 12 to the one-bit signal output part 16. By installing an electrolytic capacitor or the like in the sub-regulator 26, the decay time of the 1-bit signal and the clock signal when the power is turned off is delayed, and the output port of the first control means 17 to the control switch 19 is changed due to power fluctuation. By selecting and using a port whose output signal attenuates quickly, the same effect as in the transmission system 1 can be achieved.
[0132]
【The invention's effect】
As described above, according to the present invention, information signals can be transmitted and received only between predetermined devices. Therefore, an apparatus that cannot receive a transmission notification signal and generate a transmission permission signal cannot receive an information signal from the first device. That is, when the first device is an information reproducing device, the information signal reproduced by the information reproducing device is output only to a predetermined device, and thus may be output to an information recording device and recorded. Is prevented.
[0133]
Further, the transmission notification signal and the transmission permission information are transmitted by the first transmission medium, and the predetermined information is transmitted by the second transmission medium. Therefore, the predetermined information signal includes noise caused by the transmission notification signal and the transmission permission information. Is not included. Therefore, it is possible to prevent the quality of the predetermined information signal transmitted from the first device to the second device from deteriorating.
[0134]
Further, according to the present invention, the sound reproducing device does not output the sound information signal to a sound recording device or the like that is not mutually authenticated. Therefore, the acoustic information signal cannot be freely recorded on the recording medium by the acoustic recording device. As a result, it is possible to prevent a literary work such as audio information from being copied by an unspecified number of audio recording devices, thereby preventing copyright infringement.
[0135]
For example, when a predetermined information signal is transmitted from the sound reproducing device to the amplifier, even if the power of the sound reproducing device is suddenly cut off, the abnormal 1-bit signal is prevented from being output to the outside of the amplifier. Is done. Therefore, for example, when a speaker or the like is connected to the output section of the amplifier, it is possible to prevent the speaker from generating an abnormal sound. For this reason, it is possible to prevent a problem that an undesired abnormal sound is emitted and the user of the transmission system is surprised and uncomfortable.
[0136]
Further, according to the present invention, it is possible to transmit and receive an acoustic information signal only between predetermined devices. Therefore, an apparatus that cannot receive a transmission notification signal and generate a transmission permission signal cannot receive an information signal from the first device. That is, when the first device is an information reproducing device, the information signal reproduced by the information reproducing device is output only to a predetermined device, and thus may be output to an information recording device and recorded. Is prevented.
[0137]
Further, the transmission notification signal and the transmission permission information are transmitted by the first transmission medium, and the predetermined information is transmitted by the second transmission medium. Therefore, noise caused by the transmission notification signal and the transmission permission information is included in the acoustic information signal. Not included. Therefore, it is possible to prevent the quality of the acoustic information signal transmitted from the first device to the second device from being degraded.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a transmission system 1 according to an embodiment of the present invention.
FIG. 2 is a waveform diagram showing a 1-bit signal and a clock signal output from a 1-bit signal output unit 16;
FIG. 3 is a block diagram illustrating an example of a configuration of an amplification-side input switching unit 34;
FIG. 4 is a block diagram showing another example of the configuration of the amplification-side input switching unit 34.
FIG. 5 is a diagram showing a waveform shaping unit 35;
FIG. 6 is a flowchart showing the operation of the first control means 17 when transmitting a 1-bit signal from the acoustic information reading device 2 to the amplifying device 3.
FIG. 7 is a flowchart showing the operation of the voltage detection and control unit 25.
FIG. 8 is a flowchart showing the operation of the second control means 36.
FIG. 9 is a diagram illustrating an example of a communication format when the acoustic information reading device 2 and the amplifying device 3 transmit and receive a transmission notification signal and a transmission permission signal.
FIG. 10 is a block diagram showing a part of an audio information reading device in a transmission system according to another embodiment of the present invention.
FIG. 11 is a block diagram showing a part of an audio information reading device in a transmission system according to still another embodiment of the present invention.
[Explanation of symbols]
1 Transmission system
2 Sound information reading device
3 Amplifier
4 First signal line
5 Second signal line
17 First control means
25 Power supply detection and control unit
31 1-bit signal input section
36 Second control means
41 External output unit
42 Amplification side input switching unit
39 Mute output control element

Claims (5)

A first device that generates and transmits a transmission notification signal indicating that a predetermined information signal is transmitted, and that transmits the information signal by receiving transmission permission information;
In response to the transmission notification signal transmitted from the first device, when the reception of the information signal recognized by the transmission notification signal can be acknowledged, the transmission indicating that the first device can transmit the information signal. A second device that generates a permission signal and transmits the signal to the first device, and receives an information signal transmitted from the first device;
A first transmission medium provided between the first device and the second device for transmitting a transmission notification signal and a transmission permission signal;
A transmission system, comprising: a second transmission medium provided between the first device and the second device for transmitting an information signal. The first device includes:
Power supply detecting means for detecting a state of the power supply;
When the power supply is in an abnormal state based on a detection result detected by the power supply detecting means, an abnormal signal transmitting means for transmitting an abnormality occurrence signal indicating that the power supply is in an abnormal state via the first transmission medium is provided. And
The second device includes:
An input unit interconnected with the second transmission medium and receiving an information signal;
An output unit that outputs an information signal input from the input unit to the outside,
Connection means provided between the input unit and the output unit, the connection means for disconnectably connecting the input unit and the output unit,
When an abnormality occurrence signal transmitted from the first device is received, the connection unit is controlled so that the information signal input from the input unit is output from the output unit to the outside before the input unit and the output unit are connected to each other. 2. The transmission system according to claim 1, further comprising a second control unit for disconnecting. The first device includes:
Power supply detecting means for detecting a state of the power supply;
3. The transmission system according to claim 1, further comprising a signal cutoff unit that cuts off transmission of an information signal when the power supply is in an abnormal state based on a detection result detected by the power supply detection unit. The first device is an audio information reading device that reads an audio information signal recorded on a recording medium,
The second device is an amplifying device,
The transmission system according to any one of claims 1 to 3, wherein the information signal is an acoustic information signal, and is represented by a 1-bit signal that is delta-sigma modulated. An audio signal transmission method in a transmission system that has a first transmission medium and a second transmission medium and transmits an audio information signal from a first device to a second device, wherein the first device is connected via the first transmission medium. Transmitting a transmission notification signal indicating that a predetermined acoustic information signal is transmitted to the first device;
When the second device can acknowledge the reception of the information signal recognized by the transmission notification signal in response to the transmission notification signal via the first transmission medium, the first device can transmit the information signal. Transmitting a transmission permission signal to the first device,
An audio signal transmission method, wherein the first device transmits an audio information signal to the second device via the second transmission medium by receiving the transmission permission information.

Images