KR102076282B1 - Sound network transfer system and method - Google Patents

Abstract

The present invention relates to a system and a method for transmitting a sound network, which amplifies a UTP signal transmitted from a sound network transmitter through a UTP cable in real time, by a digital-to-analog amplifier by networking the same. According to the present invention, a plurality of first sound source generator receive a sound source to convert the same into an electric first analog audio signal, and a sound network transmitter processes the first analog audio signal to a UTP signal to transmit the same through a UTP cable in real time. Also, a distributor distributes the UTP signal, and a plurality of second sound source generators receive a sound source or generate the stored sound source as an electrical second analog audio signal. In addition, a digital mixer digitally mixes the distributed UTP signal and the second analog audio signal, and a power digital amplifier amplifies the distributed UTP signal or a signal mixed by the digital mixer in a digital manner, in a digital-to-analog manner. Furthermore, a plurality of sound source reproducers output the signal amplified by the power digital amplifier in the digital-to-analog manner as a sound source.

Description

Sound network transfer system and method

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a sound network transmission system and method. More particularly, the present invention relates to a sound network transmission system and method for amplifying a UTP signal transmitted in real time through a UTP cable from a sound network transmitter into a digital analog amplifier. It is about.

Acoustic devices such as amplifiers and speakers used to output voices or sounds (ie, sound sources) are distributed and used in large-scale facilities such as schools, playgrounds, government offices, and large buildings. This sound device is also controlled directly or remotely by a control device or a control computer via an audio mixer and a matrix switch.

The audio mixer is an equalizer and volume control switch that amplifies and outputs a small level signal input through a channel from various sources such as CD, DVD, MP3, cassette tape, hard disk, memory, microphone, line, etc. into a required level signal. It includes.

The matrix switch freely selects the connection between the amplifier and the speaker, and connects them in various combinations. The matrix switch outputs the voice or sound (ie, sound source) by connecting the signal output from the audio mixer to the configured amplifier and speaker. At this time, when there is an abnormality by monitoring the state of acoustic devices such as amplifiers and speakers, the broadcast sound is output using another amplifier or speaker that is normally driven.

Acoustic devices such as amplifiers and speakers are spread out over a large area of large facilities such as schools, playgrounds, and public offices, and there are many constraints for centralized management. When broadcasting to a specific area, there is no method to transmit other than the pre-installed method. Also, in the case of amplifiers and speakers distributed in different places, to check the operating status, the amplifier can be used by using a circuit check method. You should check the condition of the speaker and the speaker yourself.

Korean Patent No. 10-0788875 (registered Dec. 18, 2007) describes a remote acoustic device control system, including: multiple amplifiers; Multiple speakers; Sound source generator; A matrix switch connecting the output of the sound source generator to a combination of one or more amplifiers and speakers; A circuit state test apparatus electrically connected to the amplifiers and the speakers to check an abnormal state of the amplifiers and the speakers; A control computer for setting a combination of the amplifier and the speaker according to the input information of the broadcast menu and generating a connection control signal of the combination of the amplifier and the speaker according to this setting; A sound control system of a school which transmits an output signal of a circuit state test apparatus to a control computer, and includes a control device for driving a matrix switch according to a connection control signal of a combination of an amplifier and a speaker of the control computer, which is broadcasted from the control computer. The menu for setting includes a broadcasting menu and a sub broadcasting menu, and the broadcasting menu includes morning broadcasting, lunch broadcasting, example broadcasting, and emergency broadcasting. The sub menu includes broadcasting status checking, broadcasting status changing, and scheduled broadcasting. It is equipped with at least all grades, all grades, and all grades of broadcasting. When checking the broadcasting state or changing the broadcasting state, the circuit state tester is driven to detect the state of the amplifier and the speaker and display the state on the control computer. When is selected, broadcasting is given priority to a specific channel preset in case of emergency. It is characterized in that it is configured to be transmitted. According to the disclosed technology, it is possible to selectively broadcast to the entire area or designated place in public offices, schools, etc., so that the sound control system can be optimally operated, and in advance for transmission in a specific channel from the control computer in case of an emergency situation It is set up as possible and broadcast transmission is possible in the first place, so that you can quickly respond to emergency situations in public offices, schools, etc., while controlling and managing from a remote location using a control device or a control computer, you can select various sound sources It can output and detect abnormality of amplifier or speaker, which can prevent broadcasting error due to malfunction of amplifier or speaker, and even if broadcasting status change is selected as well as broadcasting status checking is selected. Circuit condition tester is activated to detect the condition of amplifier and speaker Is configured to open the display can more effectively prevent the broadcast failure in advance.

Since Korean Patent No. 10-0499075 (registered on June 23, 2005) can control the volume control amplifier and the analog switch for output path selection in the audio mixer through a host computer, the volume level and output path of the audio signal are consequently changed. There is a convenience of selective control at a remote location, and has been described with respect to an audio controller capable of automatically outputting a predetermined audio signal input to an audio mixer through all channels with minimal remote control. According to the disclosed technology, the volume adjusting amplifiers for varying the volume level of the analog audio signal input for each channel according to the digital volume control signal for each channel, and the amplifier for volume adjustment in accordance with the digital output control signal for each channel applied An audio mixer comprising a plurality of groups of analog switches for switching an output path of an audio signal output from the audio signal; Output volume of input audio signal by outputting digital volume control signal for each channel according to command from host computer, and outputting digital output control signal for each channel according to command from host computer And an audio mixer control unit for designating a control unit, wherein the audio mixer control unit includes a memory storing control data for controlling mixer analog switches and data for controlling an output volume of the audio signal when an emergency command is received. It is done.

In the conventional sound network transmission system as described above, the transmission equipment is mainly composed of a hardware configuration, the control signal for controlling the transmission equipment is made by RS-232 or CAN method, the transmission signal is expressed In order to transmit a transmission signal to a losing place, installation of hardware equipment, various and complicated wiring work, etc. are necessary, and a lot of time, effort, and cost have been put into this process. Since the conventional sound network transmission system as described above is a hardware dependent system, the quality of the transmission equipment of each manufacturer is different, and it is necessary to purchase and install expensive transmission equipment in order to transmit the transmission signal of excellent quality. In addition, since it is displayed on the final output means through a large number of equipments in terms of the signal to be transmitted, a transmission delay occurs and a rapid response and evacuation is not performed in case of an emergency such as a fire. There is also a problem that can cause human and physical damage.

Korea Patent Registration No. 10-0788875 Korean Patent Registration No. 10-0499075

SUMMARY OF THE INVENTION The present invention has been made in an effort to solve the problems described above, and implements to amplify a UTP signal transmitted in real time through a UTP cable from a sound network transmitter into a digital analog amplifier. A sound network transmission system and method are provided.

In order to solve this problem, according to an aspect of the present invention, a plurality of first sound source generator for receiving a sound source and converting it into an electrical first analog audio signal; A sound network transmitter which processes the first analog audio signal converted by the first sound source generator into a UTP signal and transmits the same through a UTP cable in real time; A distributor for distributing the UTP signal transmitted from the sound network transmitter; A plurality of second sound source generators for receiving a sound source or generating a stored sound source as an electrical second analog audio signal; A digital mixer for digitally mixing the UTP signal distributed by the distributor and the second analog audio signal generated by the second sound source generator; A power digital amplifier for digitally analog amplifying the UTP signal distributed by the distributor or the digitally mixed signal from the digital mixer; And it provides a sound network transmission system comprising a plurality of sound source player for outputting the digital analog amplified signal from the power digital amplifier as a sound source.

In one embodiment, the sound network transmitter, processor unit for performing audio input control, encoding control, UTP signal processing control, UTP interface control, streaming processing control; A memory unit for storing programs and data necessary for the operation of the processor unit; An audio input unit for inputting a first analog audio signal converted by the first sound source generator according to audio input control of the processor unit; An encoding unit for encoding the first analog audio signal input from the audio input unit and transferring the encoded audio signal according to encoding control of the processor unit; A UTP signal processing unit for processing the encoded audio signal transmitted from the encoding unit into a UTP signal according to the UTP signal processing control of the processor unit; A UTP interface unit for interfacing the UTP signal processed by the UTP signal processing unit to the distributor in real time through a UTP cable according to the UTP interface control of the processor unit; And a streaming processor for streaming the UTP signal required for real-time transmission through the UTP cable according to the streaming processing control of the processor unit.

In one embodiment, the UTP signal processing unit, characterized in that to process the UTP signal to be connected to the distributor through a UTP network.

In one embodiment, the sound network transmitter, in accordance with the AVB control of the processor unit in order to control the time of the signal stream between the UTP network nodes during the real-time transmission of the UTP signal over the UTP cable, bandwidth to manage the competition between signal traffic It further comprises an AVB unit for adjusting the.

In one embodiment, the AVB unit, characterized in that for reserving the available Ethernet bandwidth for AVB traffic.

In one embodiment, the AVB unit is characterized in that in the case of the AVB packet is transmitted in a slot regularly allocated.

In one embodiment, the AVB unit is characterized in that all nodes in the AVB domain share a virtual clock so that the AVB packet has a presentation time as to when the media packet should be executed.

In an embodiment, the sound network transmitter may further include a network control / management unit for controlling and managing the UTP network according to the network control / management control of the processor unit.

In one embodiment, the sound network transmitter, according to the time synchronization control of the processor unit to match the time synchronization between the devices connected to the UTP network, to prevent the loss of the UTP signal transmitted by the time synchronization and transmission quality Characterized in that it further comprises a time synchronization unit to ensure.

According to an embodiment, the sound network transmitter may transmit / receive a synchronization message for synchronizing precise time between the devices connected to the UTP network according to the transmission / reception control of the processor unit, and synchronize the message for the time synchronization procedure of the time synchronization unit. The load is characterized by.

According to another feature of the invention, a plurality of first sound source generator for receiving a sound source to convert the electrical first analog audio signal; A sound network transmitter processing the first analog audio signal as a UTP signal and transmitting the same through a UTP cable in real time; Distributing the UTP signal by a distributor; Generating, by a plurality of second sound source generators, a sound source or an stored sound source as an electrical second analog audio signal; Digitally mixing the distributed UTP signal and the second analog audio signal by a digital mixer; A digital analog amplifying of the distributed UTP signal or the digitally mixed signal by the digital mixer by a power digital amplifier; And outputting, by the plurality of sound source players, the digital analog amplified signal from the power digital amplifier as a sound source.

The present invention provides a sound network transmission system and method for amplifying a UTP signal, which is networked and transmitted in real time from a sound network transmitter through a UTP cable, into a digital analog amplifier, thereby purchasing expensive equipment. There is no need to install and installation of hardware equipment and wiring work is simple, so that time, effort and cost can be reduced. Also, in terms of transmitted signals, real-time can be guaranteed to prevent the delay of transmission time. In case of emergency, rapid response and evacuation can be made, which has the effect of preventing human and physical damage in advance.

According to the present invention, by configuring the system by the UTP cable to transmit the audio data in real time through the UTP cable, it is possible to reduce the cost required for the system construction, signal attenuation and noise inflow according to the existing coaxial and analog cable wiring In addition, the transmission quality can be prevented and the transmission quality can be prevented from being deteriorated according to the performance characteristics of the equipment required for system configuration.

1 is a diagram illustrating a sound network transmission system according to an exemplary embodiment of the present invention.
FIG. 2 is a diagram illustrating a sound network transmitter in FIG. 1.
3 is a view for explaining the power digital amplifier in FIG.
FIG. 4 is a diagram illustrating a front portion of the power digital amplifier shown in FIG. 1.
FIG. 5 is a diagram illustrating a rear portion of the power digital amplifier shown in FIG. 1.
6 is a view for explaining the clip limiter switch shown in FIG.
FIG. 7 is a diagram illustrating a speaker output terminal of FIG. 5.
FIG. 8 is a diagram illustrating an XLR / TRS combo balanced input terminal in FIG. 5.
FIG. 9 is a diagram illustrating a parallel mode and a stereo mode by the mode selection switch in FIG. 5.
FIG. 10 is a diagram illustrating a bridged mono mode by the mode selection switch in FIG. 5.
11 is a flowchart illustrating a sound network transmission method according to an embodiment of the present invention.
12 is a flowchart illustrating the digital analog amplification step in FIG. 11.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. However, since the description of the present invention is merely an embodiment for structural or functional description, the scope of the present invention should not be construed as being limited by the embodiments described in the text. That is, since the embodiments may be variously modified and may have various forms, the scope of the present invention should be understood to include equivalents for realizing the technical idea. In addition, the objects or effects presented in the present invention does not mean that a specific embodiment should include all or only such effects, the scope of the present invention should not be understood as being limited thereby.

On the other hand, the meaning of the terms described in the present invention will be understood as follows.

Terms such as "first" and "second" are intended to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

When a component is referred to as being "connected" to another component, it should be understood that there may be other components in between, although it may be directly connected to the other component. On the other hand, when a component is said to be "directly connected" to another component, it should be understood that there is no other component in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring", should be interpreted as well.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as "include" or "have" refer to features, numbers, steps, operations, components, parts, or parts thereof described. It is to be understood that the combination is intended to be present and does not exclude in advance the possibility of the presence or addition of one or more other features or numbers, steps, actions, components, parts or combinations thereof.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art unless otherwise defined. Generally, the terms defined in the dictionary used are to be interpreted to coincide with the meanings in the context of the related art, and should not be interpreted as having ideal or excessively formal meanings unless clearly defined in the present invention.

Now, a sound network transmission system and method according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating a sound network transmission system according to an exemplary embodiment of the present invention.

Referring to FIG. 1, the sound network transmission system 100 may include a plurality of first sound source generators 110-1 to 110 -N, a sound network transmitter 120, a distributor 130, and a plurality of sound sources. Second sound source generators 140-1 to 140-M, digital mixers 150, a plurality of power digital amplifiers 160, a plurality of sound source players 170-1 to 170-4 ).

The first sound source generators 110-1 to 110 -N are microphones (for example, 40 or more microphones in the case of a stage). The first sound source generators 110-1 to 110 -N receive a voice or sound (that is, a sound source) and perform electrical first analog audio. The signal is converted into a signal, and the converted first analog audio signal is transferred to the sound network transmitter 120.

The sound network transmitter 120 processes the first analog audio signal transmitted from the first sound source generators 110-1 to 110 -N as a UTP signal, for example, a UTP (Unshielded Twisted pair) cable (for example, CAT-5E, etc.) in real time to the distributor (130).

The distributor 130 distributes the UTP signal received from the sound network transmitter 120 through the UTP cable and transmits the distributed UTP signal to the digital mixer 150 and the power digital amplifier 160.

In an embodiment, the distributor 130 is, for example, a hub, a main distribution frame (MDF) / intermediate distribution frame (IDF), or the like of the sound network transmitter 120 to be described below. It may include components similar to or identical to the configuration, and may transmit the distributed UTP signal to the digital mixer 150 and the power digital amplifier 160 in real time.

The second sound source generators 140-1 to 140-M are wireless microphones, CDs, DVDs, MP3s, cassette tapes, hard disks, memories, lines, etc., and receive or store voices or sounds (that is, sound sources). The voice or sound (ie, sound source) is generated as an electrical second analog audio signal, and the generated second analog audio signal is transmitted to the digital mixer 150.

The digital mixer 150 digitally mixes the UTP signal received from the distributor 130 through the UTP cable and the second analog audio signal transmitted from the second sound source generators 140-1 to 140-M, and the corresponding digital mixing. The signal (ie, the digital mixing signal) is transmitted to the power digital amplifier 160 through the UTP cable.

In one embodiment, the digital mixer 150 may include components similar to or identical to the configuration of the sound network transmitter 120 to be described below, and the digital mixed signal (ie, the digital mixing signal) may be connected through a UTP cable. It can be transmitted to the power digital amplifier 160 in real time.

The power digital amplifier 160 includes an AD / DA converter, an amplifier, and the like, and digitally receives the UTP signal received from the distributor 130 through the UTP cable or the digital mixing signal received from the digital mixer 150 through the UTP cable. Analog amplification, the digital analog amplified signal (ie, digital analog amplified signal) is transmitted to the sound source player (170-1 ~ 170-4).

In one embodiment, the power digital amplifier 160 may include components similar to or identical to the configuration of the sound network transmitter 120 to be described below, and the digital analog amplified signal (ie, the digital analog amplified signal) in real time. It can be transmitted to the sound source player (170-1 ~ 170-4).

The sound source regenerators 170-1 to 170-4 output, for example, a digital analog amplified signal received from the power digital amplifier 160 as voice or sound (that is, sound source) as a speaker or the like.

Sound network transmission system 100 having the configuration as described above, by implementing a network to amplify the UTP signal transmitted in real time through the UTP cable from the sound network transmitter 120 to the power digital amplifier 160, There is no need to purchase and install the equipment, and the installation and wiring of hardware equipment is simple, which saves time, effort, and cost. Also, in terms of the transmitted signal, real-time can be guaranteed to prevent delay of transmission time. Therefore, in the event of an emergency such as a fire, a quick response and evacuation can be made, which has the effect of preventing human and physical damage in advance.

Sound network transmission system 100 having the configuration as described above, by configuring the system by the UTP cable to transmit the audio data in real time through the UTP cable, it is possible to reduce the cost required to build the system, the existing coaxial And it is possible to block the signal attenuation and noise inflow due to the analog cable wiring, and also to prevent the deterioration of the transmission quality according to the performance characteristics for each equipment necessary for the system configuration.

FIG. 2 is a diagram illustrating a sound network transmitter in FIG. 1.

Referring to FIG. 2, the sound network transmitter 120 includes a processor 121, a memory 122, an audio input 123, an encoding 124, and a UTP signal processor. 125, a UTP interface unit 126, and a streaming processor 127.

The processor 121 performs various signal operations, command processing, data storage, control, etc., performs audio input control on the audio input unit 123, performs encoding control on the encoding unit 124, and performs a UTP signal. UTP signal processing control is performed to the processing unit 125, UTP interface control is performed to the UTP interface unit 126, and streaming processing control is performed to the streaming processing unit 127.

In an embodiment, the processor unit 121 may process multiple tasks at the same time as a multi-core processor.

The memory unit 122 stores programs and data (or various environment variable data) necessary for the operation of the processor unit 121.

The audio input unit 123 inputs the first analog audio signal transmitted from the first sound source generators 110-1 to 110 -N to the encoding unit 124 according to the audio input control of the processor 121.

In an embodiment, the audio input unit 123 may accommodate a plurality of analog audio channels.

The encoding unit 124 is a block for signal processing, and encodes the first analog audio signal input from the audio input unit 123 according to the encoding control of the processor 121 to convert the encoded audio signal into the UTP signal processing unit 125. Pass it on.

In one embodiment, the encoder 124 converts the first analog audio signal input from the audio input unit 123 into an encoded audio signal in order to have a shorter delay time when transmitting the UTP signal through the UTP network. I can let you.

The UTP signal processing unit 125 is a part for processing a physical signal to be connected to the distributor 130 through the UTP network, and is transmitted from the encoding unit 124 according to the UTP signal processing control of the processor unit 121. The encoded audio signal is processed as a UTP signal and transferred to the UTP interface unit 126.

The UTP interface unit 126 is a portion directly connected to a UTP cable to interface a UTP signal having a transmission speed of 1 Gbps or more. The UTP signal is transmitted from the UTP signal processor 125 according to the UTP interface control of the processor 121. The signal is interfaced to the distributor 130 in real time through the UTP cable.

The streaming processor 127 is a transport protocol part such as IEEE 1722, and streams a UTP signal that requires real time transmission through a UTP cable according to the streaming processing control of the processor 121.

The sound network transmitter 120 having the above-described configuration may further include an audio video bridging (AVB) unit 128.

The AVB unit 128 is a UTP network node (for example, a distributor 130, a digital mixer, and a power digital amplifier) in real time transmission of a UTP signal through a UTP cable under the AVB control of the processor unit 121. (160, etc.) to control the time of the signal stream and to adjust the bandwidth to manage the competition between the signal traffic.

In one embodiment, the AVB unit 128 may reserve the available Ethernet bandwidth for AVB traffic, and may prevent collisions because the Ethernet bandwidth is reserved.

In an embodiment, the AVB unit 128 may be transmitted in a slot regularly allocated in the case of an AVB packet, where all nodes (eg, the distributor 130 of the AVB domain) are transmitted. ), The digital mixer, the power digital amplifier 160, etc.) share a virtual clock so that the AVB packet has a presentation time of when the media packet should be executed. I can do it.

The sound network transmitter 120 having the above-described configuration may further include a network control / management unit, a time synchronization unit, and a synchronization message unit (not shown in the drawing for convenience of description).

The network control / management unit is a control / management protocol part such as IEEE 1722. 1, which is responsible for the control and management of the UTP network composed of the IEEE 1722 protocol according to the network control / management control of the processor 121. At this time, the processor unit 121 performs network control / management control in the network control / management unit.

The time synchronization unit adjusts the time synchronization between the devices connected to the UTP network (eg, the distributor 130, the digital mixer, the power digital amplifier 160, etc.) according to the time synchronization control of the processor 121, It prevents the loss of UTP signal transmitted by time synchronization and guarantees transmission quality. At this time, the processor unit 121 performs time synchronization control in the time synchronization unit.

The synchronization message unit is a transmission / reception protocol portion such as IEEE 802.1AS, and the like (eg, the distributor 130, the digital mixer, and the power digital amplifier 160) connected to the UTP network according to the transmission / reception control of the processor 121. Etc.) It is responsible for the time synchronization procedure of the time synchronization unit by transmitting and receiving synchronization messages for precise time synchronization. At this time, the processor unit 121 performs transmission and reception control to the synchronization message unit.

3 is a diagram illustrating the power digital amplifier 160 in FIG. 1.

Referring to FIG. 3, the power digital amplifier 160 includes a left input terminal (Audio in) 201, a right input terminal 202, a left input volume unit (Audio in Volume) 203, and a right input volume unit 204. , Left line output stage 205, right line output stage 206, LAN (Local Area Network) jack (207), Ethernet module 208, control unit 209, left volume controller 210, right volume controller 211, left high pass controller 212, right high pass controller 213, left amplifier 214, right amplifier 215, left low pass filter 216, right low pass filter 217, left speaker 218, a right speaker 219, a MPC 220, a power input terminal 221, a driver 222, a main power supply 223, and a display 224.

The left input terminal 201 receives the left audio input signal and delivers the left audio input signal to the left input volume unit 203.

The right input terminal 202 receives the right audio input signal and delivers it to the right input volume unit 204.

The left input volume unit 203 transfers the left audio input signal transmitted from the left input terminal 201 to the left line output terminal 205 and the left volume controller 210.

The right input volume unit 204 transfers the right audio input signal transmitted from the right input terminal 202 to the right line output terminal 206 and the right volume controller 211.

The left line output terminal 205 receives a left audio input signal from the left input volume unit 203 and sends out a line output to the outside.

The right line output terminal 206 receives the right audio input signal from the right input volume unit 204 and sends out a line output to the outside.

The LAN jack 207 is a digital audio signal of the sound network transmission system 100 (that is, a UTP signal received through the UTP cable from the distributor 130 or a digital mixing signal received through the UTP cable from the digital mixer 150. ) Is received and delivered to the Ethernet module 208.

The Ethernet module 208 is, for example, a Cobranet Module, which converts an analog audio signal into a digital audio signal transmitted through the LAN jack 207, and converts the converted analog audio signal into a left volume controller. And to the right volume controller 211.

The control unit 209 is a microcontroller unit (MCU), which controls volume for the left volume controller 210 and the right volume controller 211, mute protection control for the MPC 220, and power supply for the main power supply unit 223. Control, status display control of the display unit 224 is performed.

In one embodiment, the control unit 209, each component (for example, left input volume unit 203, right input volume unit 204, Ethernet module 208, left volume controller 210, right volume) Controller 211, Left High Pass Controller 212, Right High Pass Controller 213, Left Amplifier 214, Right Amplifier 215, Left Low Pass Filter 216, Right Low Pass Filter 217, Left Side The operation state of the speaker 218, the right speaker 219, the MPC 220, the driver 222, the main power supply unit 223, and the like, and transmits information on the determined operation state to the display unit 224. Can give

According to an embodiment, the controller 209 may perform a system monitoring function by using a computer screen. The controller 209 detects an environmental change factor according to a temperature change in the amplifiers 214 and 215 and switches the switch to alternately operate in an abnormal situation. You can check whether there is a protection circuit fault, check the output status in real time graphic, check the output level status in real time, or check the network connection status of the currently connected device.

The left volume controller 210 controls the volume of the left audio input signal transmitted from the left input volume unit 203 and the analog audio signal transmitted from the Ethernet module 208 according to the volume control of the controller 209. It passes to the high pass controller (212).

The right volume controller 211 controls the volume of the right audio input signal transmitted from the right input volume unit 204 and the analog audio signal transmitted from the Ethernet module 208 according to the volume control of the controller 209. It passes to the high pass controller (213).

The left high pass controller 212 is, for example, a high pass filter of 30/70 Hz, and receives a volume controlled audio signal (ie, a volume control audio signal) from the left volume controller 210 and controls the received volume. The signal is transmitted to the left amplifier 214 through the high pass of the audio signal (ie, the truncation of the low band) and the frequency adjustment function of the high band.

The right high pass controller 213 is, for example, a high pass filter of 30/70 Hz. The right high pass controller 213 receives a volume control audio signal from the right volume controller 211 and performs a high pass for the received volume control audio signal. The low frequency band is cut off) and the high frequency band is adjusted to the right amplifier 215.

In one embodiment, the high pass controllers 212 and 213 make full use of the characteristics of the speakers 218 and 219, and 30 Hz or 70 Hz per channel to protect the speakers 218 and 219 from low-frequency. A high pass filter can be built in.

The left amplifier 214 is, for example, a digital amplifier of Class-D L-ch, and amplifies an audio signal transmitted from the left high pass controller 212 according to the mute protection control of the MPC 220, and amplifies the corresponding audio signal. The audio signal is transmitted to the left low pass filter 216.

The right amplifier 215 is, for example, a digital amplifier of Class-D L-ch, and amplifies an audio signal transmitted from the right high pass controller 213 according to the mute protection control of the MPC 220, and amplifies the audio signal. The audio signal is transmitted to the right low pass filter 217.

In one embodiment, the left amplifier 214 and the right amplifier 215 uses a Switching Mode Power Supply (SMPS) / D Class Digital Amplifier circuit, which employs a high-efficiency SMPS. Thus, 2Ω output and noise of the audio signal amplified by the high pass controllers 212 and 213 can be minimized.

The left low pass filter 216 receives the amplified audio signal from the left amplifier 214 and delivers the amplified audio signal to the left speaker 218 through a low pass (i.e., high-band cutoff) function for the received amplified audio signal. .

The right low pass filter 217 receives the amplified audio signal from the right amplifier 215 and delivers the amplified audio signal to the right speaker 219 through a low pass (i.e., high-frequency cut off) function of the received amplified audio signal. .

The left speaker 218 receives an audio signal from the left low pass filter 216 and emits the audio signal.

The right speaker 219 receives an audio signal from the right low pass filter 217 and emits the audio signal.

The MPC 220 performs mute protection control on the left amplifier 214 and the right amplifier 215 according to the mute protection control of the controller 209.

The power input terminal 221 receives an external commercial power source (ie, AC power source) and delivers it to the driver 222.

The driver 222 is a power factor correction (PFC) driver having an LC-type circuit composed of a transformer-type silicon ion inductor and a capacitor, and generates electromagnetic waves (or waves) for commercial power input through the power input terminal 221. Removes noise) and transfers the noise to the main power unit 223.

The main power supply unit 223 supplies power transmitted through the driver 222 according to the power supply control of the control unit 209 (for example, the left input volume unit 203 and the right input volume unit 204). Ethernet module 208, controller 209, left volume controller 210, right volume controller 211, left high pass controller 212, right high pass controller 213, left amplifier 214, right amplifier 215, left low pass filter 216, right low pass filter 217, left speaker 218, right speaker 219, MPC 220, power input terminal 221, driver 222, main power supply (223, etc.) is converted into a power supply required for supply.

According to an embodiment, the power supply may be designed using an SMPS design method that maximizes the efficiency of the amplifiers 214 and 215.

The display unit 224 displays the operation state information transmitted from the control unit 209 on the screen according to the state display control of the control unit 209.

The display unit 224 displays power, clips, signals, protections, and modes on the front panel so that the operation state of the device can be checked according to the status display control of the controller 209. LEDs for (Mode) (e.g., modes such as Parallel, Stereo, Bridged, etc.) can be attached.

The power digital amplifier 160 having the above-described configuration is designed to have a compact compact size (for example, 2-rack height), capable of high power up to 2000 W, and has a light weight and a small space. It can be easily mounted and used at.

The power digital amplifier 160 having the above-described configuration can provide powerful sound quality and delicate sound, wherein a high damping factor through the volume controllers 210 and 211 and the high pass controllers 212 and 213 is obtained. Low 0.01% Total Harmonic Distortion (THD) through the Damping Factor) and the low pass filters 216 and 217 enable powerful sound quality and fine reproduction.

The power digital amplifier 160 having the above-described configuration may include, as a protection circuit, a complete protection circuit (not shown in the drawings for convenience of description) for overcurrent, overheating, output short, and DC detection. have.

In order to maintain excellent performance of the amplifiers 214 and 215, the power digital amplifier 160 having the above-described configuration includes a channel-specific clip limiter circuit for preventing distortion due to over-input. For convenience, the drawing may not be included).

The power digital amplifier 160 having the configuration as described above can receive and process analog signals through the left input terminal 201 and the right input terminal 202 and digital signals through the LAN jack 207 at the same time. Value can be very high.

The power digital amplifier 160 having the configuration as described above may be formed by a dual system operation, and when an analog system is operated, an analog signal may be received using a stereo channel and a bridge mono to amplify a sound source, and the same amplifier It can be used to share the analog signal of (214, 215) and other devices, and use the link terminal to transmit signals to other devices, and also increase the compatibility with digital device operation and sound network transmitter 120. The signal (CAT-5E) can be directly input to UTP cable and converted to analog signal to perform digital amplifier signal amplification and analog signal external transmission.

FIG. 4 is a diagram illustrating a front portion of the power digital amplifier shown in FIG. 1.

Referring to FIG. 4, the power digital amplifier 160 includes a plurality of bounding holes 231, a power switch 232, a plurality of status display LEDs 233, a cooling suction opening 234, a channel regulator 235, and a plurality of powering amplifiers. Signal signal 236, a plurality of channel attenuator (Channel Attenuator) (237) is further included.

The bounding hole 231 is formed in a hole-shaped space at each corner of the power digital amplifier 160 to mount the power digital amplifier 160 in a rack.

The power switch 232 turns the power of the power digital amplifier 160 on / off.

The status display LED 233 displays the current state of the power digital amplifier 160 (eg, a power-on state, a standby state, etc.) according to the state display control of the controller 209.

The cooling suction opening 234 receives external cool air (cold air) to cool the heat generated by the power digital amplifier 160.

The channel adjuster 235 is a digital audio signal of the sound network transmission system 100 (that is, a UTP signal received through the UTP cable from the distributor 130 or a digital mixing signal received through the UTP cable from the digital mixer 150. ) Adjust the channel to receive.

When the voltage of the line output terminal 205, 206 reaches a preset voltage value (for example, about 4 volts) according to the state display control of the control part 209, the signal LED 236 will be close. The lowest LEDs are turned on, and the clip LEDs flash when the amplifiers 214 and 215 become clipped. In this case, when the clip LEDs are continuously blinking, the control unit 209 controls the amplifiers 214 and 215 to enter the protection mode until the input signal is stabilized. In this case, the control mode prevents sound.

The channel attenuator 237 is an input signal (i.e., a digital audio signal of the sound network transmission system 100 (e.g., a UTP signal received from the distributor 130 via a UTP cable or a UTP from the digital mixer 150). Digital mixing signal received through the cable).

FIG. 5 is a diagram illustrating a rear portion of the power digital amplifier shown in FIG. 1, and FIG. 6 is a diagram illustrating the clip limiter switch shown in FIG. 5. FIG. 7 is a diagram illustrating a speaker output terminal of FIG. 5. FIG. 8 is a diagram illustrating an XLR / TRS combo balanced input terminal in FIG. 5. FIG. 9 is a diagram illustrating a parallel mode and a stereo mode by the mode selection switch in FIG. 5. FIG. 10 is a diagram illustrating a bridged mono mode by the mode selection switch in FIG. 5.

5 to 10, the power digital amplifier 160 includes a first setting switch 241, a second setting switch 242, a clip limiter switch 243, a plurality of cooling vents 244, and two The apparatus further includes a speaker output terminal 245, a XLR / TRS combo balanced input terminal 246, a link connection terminal 247, and an Ethernet connector terminal 248.

The first setting switch 241 sets three modes (for example, 30 Hz, 70 Hz, off mode, etc.) for the high pass controllers 212 and 213 for each channel.

In one embodiment, the first setting switch 241 is a selection switch of a 30 Hz or 70 Hz high pass filter, and according to the type and characteristics of the speakers 218 and 219, the HPF of the amplifiers 214 and 215 corresponding thereto. By selecting one of the 30Hz or 70Hz high pass filter), the response characteristics of the power digital amplifier 160 can be improved and the speakers 218 and 219 can be protected by attenuating or removing low frequency noise. At this time, the 70Hz HPF selection is used for the compact full range speaker, the 30Hz HPF selection is used for the sub-woofers or the large full range systems, and the off-select studio monitor. Used for Full Range for Studio Monitor.

The second setting switch 242 sets the operation modes (for example, parallel, stereo, bridged, and the like) of the amplifiers 214 and 215. At this time, when the amplifiers 214 and 215 are turned on, the control unit 209 may prevent the operation mode of the second setting switch 242 from being adjusted.

The clip limiter switch 243 sets clip limiters (for example, off, slow, fast, etc.) of the amplifiers 214 and 215.

In one embodiment, the clip limiter switch 243 is a switch for driving a built-in clip limiter circuit by securing a dynamic range so that there is no distortion of the amplifier output sound, and the signal input in any case is clear without distortion. Can produce a clear high output sound. At this time, (a) of Figure 6 shows the on of the clip limiter switch 243 with the switch sliding to the right, Figure 6 (b) shows the state of the clip limiter switch 243 with the switch sliding to the left. Indicates off.

The cooling vent 244 discharges the air sucked through the cooling suction opening 234 to the outside via the amplifiers 214 and 215 as the ventilation openings.

The speaker output terminal 245 connects the amplifiers 214 and 215 with the user's speakers 218 and 219 quickly and conveniently.

In one embodiment, the speaker output terminal 245 may include two types of output terminals, a binding post and a speaker.

In one embodiment, the speaker output terminal 245, as shown in Figure 7, shows the configuration and connection pin specifications of each mode, (a) is a stereo mode and (b) is a bridged mode It is shown. At this time, when the binding post is used as an output terminal, the polarities of the speakers 218 and 219 are connected so as not to be changed. When using the bridged mono mode, the red terminal of the channel 1 must be connected to the speaker 218 as shown in the upper part of the binding post. Connect the red terminal of channel 2 to the (+) terminal of 219) to the (-) terminal of the speakers 218 and 219, and do not use the black terminal.

The XLR / TRS combo balanced input terminal 246 connects an XLR male (or male) TRS connector.

In one embodiment, the XLR / TRS combo balanced input terminal 246 is a terminal for connecting the output of the digital mixer 150, which is a preamplifier or an audio mixer, to the power digital amplifier 160. There are two types of input terminals, an XLR jack as shown and a combination jack as shown in Fig. 8B. In this case, when the amplifiers 214 and 215 are used in the bridged mono mode, only the input terminal of the channel 1 is used.

The link connection terminal 247 transmits the same signal as the input signal to another amplifier.

The Ethernet connector terminal 248 is a UTP cable (for example, CAT-5E, etc.) Ethernet terminal. The Ethernet connector terminal 248 is externally attached and detached as necessary, and the distributor (130) (or hub) or the digital mixer 150 (digital audio). You can easily adjust the volume when connecting.

As shown in FIG. 5, the power digital amplifier 160 having the above-described configuration further includes an AC power supply code 251, a circuit breaker 252, and a mode selection switch 253.

The AC power supply cord 251 supplies the AC power of the power digital amplifier 160. At this time, after confirming the power source to be used and connected to the outlet, in the case of 220V only, use a power source of 220V.

The circuit breaker 252 protects the power digital amplifier 160 by shutting off power when an abnormality occurs in the power digital amplifier 160 due to an overload or malfunction. The circuit breaker 252 is turned off with a protruding portion to protect the amplifiers 214 and 215 if an abnormal situation occurs during use, and is pressed again when the protruding portion is pressed after the abnormal situation is finished. It is connected to supply power to the amplifier (214, 215).

The mode selection switch 253 selects a mode (for example, one of parallel, stereo, bridged, etc.) so that it can be suitably used when the power digital amplifier 160 is used. Here, in the parallel mode, as shown in Fig. 9A, the two amplifiers 214 and 215 are operated with only one input signal. When the input is input to the channel 1 and the parallel mode is selected, the signal input to the channel 1 is outputted to the first amplifier 214 and the second amplifier 215. In addition, in parallel mode, only the input of the channel 1 must be used, that is, only the input signal of the channel input 1 is output to the first amplifier 214 and the second amplifier 215 so that an input jack is not inserted into the channel input 2. do.

For example, in the stereo mode, as shown in FIG. 9B, input signals of respective channels are independently output. In this case, the channel 1 input signal is output to the first amplifier 214, and the channel 2 input signal is output to the second amplifier 215, respectively.

For example, in the bridged mono mode, as shown in Fig. 10, two amplifiers 214 and 215 are used together to be used when using a larger output. At this time, the signal of the channel 1 can be used as the output twice as large as the signal is input to the input channel 1 by connecting the (+) output terminal of the amplifier output channel 1 and the (+) terminal of the channel 2. At this time, in the bridged mono mode, only the input of the channel 1 is used, and only the input signal of the channel input 1 is output twice, so that the input jack is not inserted into the channel input 2. In addition, the connection of the speakers 218, 219 also allows the signal input to the channel 1 to be output to the + terminal (red) of the amplifier outputs 1 and 2. In the bridged mono mode, the volume control volume of the input channel 2 is set to the maximum position, the volume is controlled by the volume control volume of the channel 1, and a speaker having a predetermined resistance value (for example, 4Ω or more) (218, 219). ).

11 is a flowchart illustrating a sound network transmission method according to an embodiment of the present invention.

Referring to FIG. 11, first, in each of the first sound source generators 110-1 to 110-N such as a microphone, a voice or sound (that is, a sound source) is received and converted into an electrical first analog audio signal (S101). The first analog audio signal converted in step S101 is transmitted to the sound network transmitter 120. Accordingly, the sound network transmitter 120 processes the first analog audio signal transmitted from each of the first sound source generators 110-1 to 110 -N as a UTP signal and in real time through the UTP cable, the hub, the main wiring board, and the middle. The data is transmitted to the distributor 130 such as a wiring board (S102).

The UTP signal received through the UTP cable in step S102 described above is distributed by the distributor 130 (S103), and the UTP signal distributed in the corresponding step S103 is transmitted to the digital mixer 150 and the power digital amplifier 160. do.

On the other hand, in each of the second sound source generators 140-1 to 140-M such as a wireless microphone, a CD, a DVD, an MP3, a cassette tape, a hard disk, a memory, a line, and the like, a voice or a sound (ie, a sound source) is received or stored. The generated voice or sound (that is, sound source) is generated as an electrical second analog audio signal (S104), and the second analog audio signal generated in step S104 is transmitted to the digital mixer 150.

The digital mixer 150 digitally mixes the UTP signal distributed in the above-described step S103 and the second analog audio signal generated in the above-described step S104 (S105), and the digitally mixed signal (ie, the digital mixing in the corresponding step S105). Signal) is transmitted to the power digital amplifier 160 having an AD / DA converter, an amplifier, etc. through a UTP cable.

The power digital amplifier 160 receives the UTP signal distributed in the above-described step S103 or the digital mixing signal digitally mixed in the above-described step S105 through the UTP cable and amplifies the digital analog (S106), and the digital analog in the corresponding step S106. The amplified signal (that is, the digital analog amplified signal) is transmitted to the sound source players 170-1 to 170-4 such as speakers.

The sound source player 170-1 to 170-4 receives the digital analog amplified signal digitally amplified in step S106 described above and outputs it as voice or sound (that is, sound source) (S107).

12 is a flowchart illustrating the digital analog amplification step in FIG. 11.

Referring to FIG. 12, first, the power digital amplifier 160 receives an external commercial power source (ie, AC power source) through the power input terminal 221 and delivers it to the driver 222. Accordingly, the driver 222 removes electromagnetic waves (or noise) generated for commercial power input through the power input terminal 221 and delivers the electromagnetic waves (or noise) to the main power supply unit 223. Accordingly, the main power supply unit 223 converts the power transmitted through the driver 222 into the power required for the power digital amplifier 160 according to the power supply control of the control unit 209 (S111).

The power digital amplifier 160 receives an audio input signal through the input terminals 201 and 202 and delivers the audio input signal to the input volume units 203 and 204. Accordingly, the input volume units 203 and 204 transmit the audio input signals transmitted from the input terminals 201 and 202 to the line output terminals 205 and 206 or the volume controllers 210 and 211. At this time, the controller 209 checks whether the audio input signal is received through the input terminals 201 and 202 (S112), and then transfers the checked audio input signal to the line output terminals 205 and 206 or the volume controller 210. 211) it is determined whether to transfer (S113).

When the audio input signal is transmitted to the line output terminals 205 and 206 in step S113 described above, the line output terminals 205 and 206 receive the audio input signals from the input volume units 203 and 204 to output the line output to the outside. Export (S114).

When the audio input signal is transmitted to the volume controllers 210 and 211 in step S113 described above, the power digital amplifier 160 transmits the digital audio signal of the sound network transmission system 100 through the LAN jack 207. The UTP signal received from the distributor 130 through the UTP cable or the digital mixing signal received from the digital mixer 150 through the UTP cable) is transmitted to the Ethernet module 208 (S115). Accordingly, the Ethernet module 208 converts the analog audio signal from the digital audio signal transmitted through the LAN jack 207 (S116), and converts the analog audio signal converted in the corresponding step S116 to the volume controllers 210 and 211. Deliver it.

The volume controllers 210 and 211 control the volume of the audio input signal transmitted from the input volume units 203 and 204 and the analog audio signal transmitted from the Ethernet module 208 according to the volume control of the controller 209. It passes to the high pass controller (212, 213) (S117).

The high pass controller 212, 213 receives a volume controlled audio signal (ie, a volume control audio signal) from the volume controllers 210, 211, and a high pass (ie, low frequency band) for the received volume control audio signal. And the frequency adjustment function of the treble band to the amplifiers 214 and 215 (S118).

The MPC 220 performs mute protection control on the amplifiers 214 and 215 according to the mute protection control of the controller 209 (S119).

The amplifiers 214 and 215 amplify the audio signals transmitted from the left high pass controller 212 according to the mute protection control of the MPC 220, and transfer the amplified audio signals to the low pass filters 216 and 217. Give (S120).

The low pass filters 216 and 217 receive the amplified audio signals from the amplifiers 214 and 215 and pass through a low pass (i.e., high-band cutoff) function of the received amplified audio signals. Will deliver to (S121).

The speakers 218 and 219 receive an audio signal from the low pass filters 216 and 217 and emit the audio signal to the sound source (S122).

As described above, the embodiment of the present invention is not implemented only through the above-described apparatus and / or method, but through a program for realizing a function corresponding to the configuration of the embodiment of the present invention, a recording medium on which the program is recorded, and the like. Such implementations may be readily implemented by those skilled in the art to which the present disclosure pertains based on the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

100: sound network transmission system 110-1 to 110-N: first sound source generator
120: sound network transmitter 121: processor unit
122: memory unit 123: audio input unit
124: encoding unit 125: UTP signal processing unit
126: UTP interface unit 127: streaming processing unit
128: AVB part 130: distributor
140-1 to 140-M: second sound source generator 150: digital mixer
160: power digital amplifier 170-1 ~ 170-4: sound source player
201: left input terminal 202: right input terminal
203: left input volume portion 204: right input volume portion
205: left line output stage 206: right line output stage
207: LAN jack 208: Ethernet module
209: control unit 210: left volume controller
211: Right Volume Controller 212: Left High Pass Controller
213: right high pass controller 214: left amplifier
215: right amplifier 216: left low pass filter
217: right low pass filter 218: left speaker
219: right speaker 220: MPC
221: power input terminal 222: driver
223: main power unit 224: display unit

Claims (5)

A plurality of first sound source generators for receiving a sound source and converting the sound source into an electrical first analog audio signal;
A sound network transmitter which processes the first analog audio signal converted by the first sound source generator into a UTP signal and transmits the same through a UTP cable in real time;
A distributor for distributing the UTP signal transmitted from the sound network transmitter;
A plurality of second sound source generators for receiving a sound source or generating a stored sound source as an electrical second analog audio signal;
A digital mixer for digitally mixing the UTP signal distributed by the distributor and the second analog audio signal generated by the second sound source generator;
A power digital amplifier for digitally analog amplifying the UTP signal distributed by the distributor or the digitally mixed signal from the digital mixer; And
It includes a plurality of sound source player for outputting the digital analog amplified signal from the power digital amplifier as a sound source,
The sound network transmitter,
A processor unit for performing audio input control, encoding control, UTP signal processing control, UTP interface control, and streaming processing control;
A memory unit for storing programs and data necessary for the operation of the processor unit;
An audio input unit for inputting a first analog audio signal converted by the first sound source generator according to audio input control of the processor unit;
An encoding unit for encoding the first analog audio signal input from the audio input unit and transferring the encoded audio signal according to encoding control of the processor unit;
A UTP signal processing unit for processing the encoded audio signal transmitted from the encoding unit into a UTP signal according to the UTP signal processing control of the processor unit;
A UTP interface unit for interfacing the UTP signal processed by the UTP signal processing unit to the distributor in real time through a UTP cable according to the UTP interface control of the processor unit; And
In accordance with the streaming processing control of the processor unit includes a streaming processing unit for streaming a UTP signal required for real-time transmission through a UTP cable,
The UTP signal processing unit, the UTP signal processing to be connected to the distributor through a UTP network,
The sound network transmitter,
According to the AVB control of the processor unit in the real-time transmission of the UTP signal through the UTP network control the time of the signal stream between the UTP network nodes, and includes an AVB unit for adjusting the bandwidth to manage the competition between signal traffic Sound network transmission system. delete delete delete delete

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