无线语音传输系统

Triple wireless voice data transmission system designStudent :,Instructor :, UniversityEvery day, in our work and in our leisure time, we come in contact with and use a variety of modern communication media, the most common being the telephone, radio, television, and the Internet. Though these media we are able to communicate (nearly) instantaneously with people on diffident continents, transact our daily business, and receive information about various developments and events of note that occur all around the world. Electronic mail and facsimile transmission have made it possible to rapidly communicate written message across great distances.Wireless communications. The development of wireless communications stems from the works of Oersted, Faraday, Gauss, Maxwell, and Hertz. In1820, Oersted demonstrated that an electric current produces a magnetic field. On August 29,1831,Michael Faraday showed that an induced current is produced by moving a magnet in the vicinity of a conductor. Thus, he demonstrated that a changing magnetic field produces an electric field. With this early work as background, James C. Maxwell in 1864 predicted the existence of electromagnetic radiation and formulated the basic theory that has been in use for over a century. Maxwell’s theory was verified experimentally by Hertz in 1887.In 1894, a sensitive device that could device that could detect radio signals, called the coherer, was used by its inventor Oliver Lodge to demonstrate wireless communication over a distance of 150 yards at Oxford, England. Guglielmo Marconi is credited with the development of wireless telegraphy. Marconi demonstrated the transmission of radio signals at a distance of approximately 2 kilometers in 1895. Two years later, in 1897 , he patented a radio telegraph system and established the Wireless Telegraph and Signal Company. On December 12, 1901, Marconi received a radio signal at Signal Hill in Newfoundland, which was transmitted from Cornwall, England, a distance of about 1700 miles.The invention of the vacuum tube was especially instrumental in the development of radio communication system .The vacuum diode was invented by Fleming in 1904 and the vacuum triode amplifier was invented by De Forest in 1906, as previously indicated. The invention of the triode made radio broadcast possible in the early part of the twentieth century. Amplitude modulation (AM) broadcast was initiated in 1920 when radio station KDKA, Pittsburgh, went on the air. From that date, AM radio broadcasting grew rapidly across the country and around the world. The super heterodyne AM radio receiver, as we know it today, was invented by Edwin Armstrong during World War I. Another significant development in radio communications was the invention of Frequency modulation (FM), also by Armstrong.In 1933, Armstrong built and demonstrated the first FM communication system. However, the use of FM was slow to develop compared with AM broadcast. It was not until the end of World War II that FM broadcast gained in popularity and developed commercially.The first television system was built in the United States by V. K. Zworykin and demonstrated in 1929. Commercial television broadcasting began in London in 1936 by the British Broadcasting Corporation(BBC) . Five years later the Federal Communications Commission(FCC) authorized television broadcasting in the United States.ELEMENTS OF AN ELECTRICAL COMMUNICA SYSTEM Electrical communication systems are designed to send messages or information from a source that generates the message to one more destinations. In general, a communication system can be represented by the functional block diagram shown . The information generated by the source may be of the form of voice (speech source), a picture (image source), or plain text in some particular language, such as English , Japanese, German , French, etc. An essential feature of any source that generates information is that its output is described in probabilistic terms; i.e., the output of a source is not deterministic. Otherwise, there would be no need to transmit the message.A transducer is usually required to convert the output of a source into an electrical signal that is suitable for transmission. For example, a microphone serves as the transducer that converts an acoustic speech signal. At the destination, a similar transducer is required to convert the electrical signals that are received into a form that is suitable for the user; e.g., acoustic signals, images, etc.The heart of the communication system consists of three basic parts, namely, the transmitter, the channel, and the receiver. The functions performed by these three elements are described next.The Transmitter. The Transmitter converts the electrical signal into a form that is suitable for transmission though the physical channel or transmission medium. For example, in radio and TV broadcast, the Federal Communications Commission (FCC) specifies the frequency range for each transmitting station. Hence, the transmitter must translate the information signal to be transmitted into the appropriate The Transmitter range that matches the frequency allocation assigned to the transmitter. Thus, signal transmitted by multiple radio station do not interfere with one another. Similar functions are performed in telephone communication systems where the electrical speech signals from many users are transmitted over the same wire.In general, the transmitter performs the matching of the message signal to the channel by a process called modulation. Usually, modulation involves the use of the information signal to systematically vary either the amplitude, frequency, or phase of a sinusoidal carrier. For example, in AM radio broadcast, the information signal that is transmitted is contained in the amplitude variations of the sinusoidal carrier, which is the center frequency in the amplitude modulation. In FM radio broadcast., the information signal that is transmitted is contained in the frequency variations of thesinusoidal carrier. This is an example of frequency modulation. Phase modulation (PM) is yet a third method for impressing the information signal on a sinusoidal carrier.In general, carrier modulation such as AM, FM, and PM is performed at the transmitter, as indicated above, to convert the information signal to a form that matches the characteristics of the channel. Thus, though the process of modulation, the choice of the type of modulated in frequency to match the allocation of the channel. The choice of the type of modulation is based on several factors, such as the amount of bandwidth over the channel, the type of noise and the interference that the signal encounters in transmission. In any case, the modulation process makes it possible to accommodate the transmission of multiple messages from many users over the same physical channel.In addition to modulation, other functions that are usually performed at the transmitter are filtering of the information-bearing signal , amplification of the modulated signal, and in case of wireless transmission, radiation of the signal by means of a transmitting antenna.The channel. The communications channel is the physical medium that is used to send the signal from the transmitter to the receiver. In wireless transmission, the channel is usually the atmosphere (free space). On the other hand, telephone channels usually employ a variety of physical media, including wirelines, optical fiber cables, and wireless (microwave radio). Whatever the physical medium for signal transmission, the essential feature is that the transmitted signal is corrupted in a random manner by a variety of possible mechanisms. The most common from of signal degradation comes in the form of additive noise ,which is generated at the front end of the receiver, where signal amplification is performed. This noise is often called thermal noise. In wire less transmission, additional additive disturbances are man-made noise, and atmospheric noise picked up by a receiving antenna. Automovile ignition noise is an example of man-made noise, and electrical lightning discharges from thunderstorms is an example of atmospheric noise. Interference from other users of the channel is another form of additive noise that often arises in both wireless and wire line communication systems .In some radio communication channels, such as the ionospheric channel that is used for long range ,short-wave radio transmission, another form of signal degradation is multipath propagation. Such signal distortion is characterized as a nonadditive signal disturbance which manifests itself as time variations in the signal amplitude, usually called fading .Both additive and nonadditive signal distortions are usually characterized as random phenomena and described in statistical terms. The effect of these signal distortions must be taken into account on the design of the communication system.In the design of a communication system, the system, the system designer works with mathematical models that statistically characterize he signal distortion encountered on physical channels. Often, the statistical description that is used in mathematical model is a result of actual empirical measurements obtained from experiments involving signal transmission over such channels .In such cases , there isa physical justification for the mathematical model used in the design of communication systems. On the other hand, in some communication system designs ,the statistical characteristics of the channel may vary significantly with time. In such cases, the system design may designer may design a communication system that is robust to the variety of signal distortions. This can be accomplished by having the system adapt some of its parameters to the channel distortion encountered.The receiver. The function of the receiver is to recover the message signal contained in the received signal. If the message signal is transmitted by carrier modulation, the receiver performs carrier demodulation in order to extract the message from the sinusoidal carrier. Since the signal demodulation is performed in the presence of additive noise and possibly other signal distortion, the demodulated message signal is generally degraded to some extent by the presence of these distortions in the received signal. As we shall see, the fidelity of the additive noise, the type and strength of any other additive interference, and the type of any nonadditive interference.Besides performing the primary function of signal demodulation, the receiver also performs a number of peripheral functions, including signal filtering and noise suppression.Digital Communication SystemAn electrical communication system in rather broad terms based on the implicit assumption that message signal is a continuous timevarying waveform. We refer to such continuous-time signal waveforms as analog sources. Analog signal can be transmitted directly via modulation over the communication channel and demodulated accordingly at the receiver. We call such a i communication system an analog communication system.Alternatively, an analog source output may be converted into a digital form and the message can be transmitted via digital modulation as a digital signal at the receiver. There are some potential advantage to transmitting an analog signal by means of digital modulation. The most important reason is that signal fidelity is better controlled though digital transmission than analog transmission. In particular, digital transmission allows us to regenerate the digital signal in long-distance transmission, thus eliminating effects of noise at each regeneration point. In contrast, the noise added in analog transmission is amplified along with the signal when amplifiers are used periodically to boost the signal level in long-distance transmission. Another reason for choosing digital transmission over analog is that the analog message signal may be highly redundant. With digital processing, redundancy may be removed prior to modulation, thus conserving channel bandwidth. Yet a third reason may be that digital communication systems are often cheaper to implement.In some applications, the information to be transmitted is inherently digital; e.g., in the form of English text, computer data, etc. In such cases, the information source that generates the data is called a discrete (digital)source.In a digital communication systems , the some applications, the functional operations performed at the transmitter and receiver must be expanded to includemessage signal discrimination at the transmitter and message signal synthesis or interpolation at the receiver. Additional functions include redundancy removal, and channel coding and decoding.The source output may be either an analog signal, such as audio or video signal, or a digital signal , such as the output of a computer which is discrete in time and has a finite number of output characters. In a digital communication system, the message produced by the source are usually converted into a sequence of binary digits as possible. In other words, we seek inefficient representation of the source output of either an analog or a digital source into a sequence of binary digits is called source encoding or date compression.The sequence of binary digits from the coerce encoder, which we call the information sequence is passed to the channel encoder. The purpose of the channel encoder is to introduce, in a controlled manner, some redundancy in binary information sequence which can be used at the receiver to overcome the effects of noise and interference encountered in the transmission of the signal though the channel. Thus the added redundancy serves to increase the reliability of the received data and improves the fidelity in decoding the deceived signal. In fact, redundancy serves in the information sequence aids the receiver in decoding the desired information sequence .The binary sequence at the output of the channel encoder is passed to the digital modulator, which servers as the interface to the communications channel. Since nearly all of the communication channels encountered in practice are capable of transmitting electrical signals (waveforms), the primary purpose of the digital modulator is to map the binary information sequence into signal waveforms.At the receiving end of a digital communication system, the digital demodulator processes the channel-corrupted transmitted waveform and reduces reduce each waveform to a signal number that represents an estimate of the transmitted data symbol (binary or Mary) . When there is no redundancy in the transmitted information, the demodulator must decide which of the M waveform was transmitted in any given time interval. A measure of how well the demodulator and encoder perform is the frequency with which errors occur in the decoded sequence.As a final step, when an analog output is desired, the source decoder accepts the output sequence from the channel and , from knowledge of the source-encoding method used, attempts to reconstruct the original signal from the source.双工无线语音数据传输系统的设计学生：学院指导老师：汉大学在日常的工作和生活中，人们每天都要接触和使用大量的现代通信系统和通信媒介，其中最常见的是电话，无线电广播，电视和因特网。

基于fm调频的双路语音同传无线收发系统设计摘要：一、引言二、FM 调频双路语音同传无线收发系统的设计要求三、系统设计四、系统实现五、实验结果与分析六、结论正文：一、引言在现代通信技术中，语音同传技术被广泛应用于各种场合，如会议、电话等。

然而，传统的有线语音同传系统存在着诸多不便，如受传输距离限制、布线复杂等。

因此，基于FM 调频的双路语音同传无线收发系统的设计具有实用价值和研究意义。

二、FM 调频双路语音同传无线收发系统的设计要求本系统旨在实现双路语音同传，主要设计要求如下：1.系统载波频率为FM，信号频段为2、3、48.5MHz；2.相对误差的绝对值不大于1，峰值频偏不大于25kHz；3.能够通过无线收发系统传输任意一路语音信号A 或B。

三、系统设计系统主要由两部分组成：调制与解调部分、双路语音同传处理部分。

1.调制与解调部分：采用FM 调频技术，对语音信号进行调制和解调。

其中，语音输入A 和B 经过调制后，通过无线信道传输；接收端收到信号后，进行解调，得到原始语音信号。

2.双路语音同传处理部分：接收端解调后得到两路语音信号，需要进行合并处理。

采用合路器将两路信号合并为一路信号，同时确保信号质量不受影响。

四、系统实现根据上述设计，我们可以实现一个FM 调频双路语音同传无线收发系统。

具体实现过程如下：1.设计并制作FM 无线收发系统，包括信号发射和接收部分；2.对语音信号A 和B 进行调制，并发射到无线信道；3.接收端接收到信号后，进行解调，得到两路语音信号；4.通过合路器将两路信号合并为一路信号，并输出。

五、实验结果与分析经过实验测试，该系统在满足设计要求的条件下，能够实现双路语音同传。

实验结果表明，系统传输质量稳定，语音信号清晰。

六、结论本文介绍了一种基于FM 调频的双路语音同传无线收发系统设计。

无线通信系统1. 引言无线通信系统是一种通过无线电波传输信息的通信系统。

它使用无线电频谱中的特定频段来传输语音、数据和图像等信息，实现人与人、设备与设备之间的无线通信。

无线通信系统在现代社会中广泛应用，包括移动通信、卫星通信、无线局域网等。

2. 无线通信系统的组成无线通信系统由以下几个组成部分组成：2.1 无线发射机无线发射机是无线通信系统中的核心设备之一。

它负责将待传输的信息转换为无线电信号，并通过天线向空间传播。

无线发射机的设计和技术水平对整个无线通信系统的性能有重要影响。

2.2 无线接收机无线接收机是无线通信系统中的另一个重要设备。

它负责接收从发射机发出的无线电信号，并将其转换回原始的信息。

无线接收机的性能直接影响到接收到的信号的质量和可靠性。

2.3 天线天线是无线通信系统中的关键部件之一。

它负责将发射机或接收机产生的无线电信号转换为电磁波，并向空间传播。

不同类型的无线通信系统使用不同种类的天线，如定向天线、全向天线等。

2.4 信道信道是无线通信系统中信息传输的媒介。

在无线通信系统中，信道通常是无线电信号在空间中传播的路径。

不同的无线通信系统使用不同的信道技术，如频分复用、时分复用等。

2.5 控制器控制器是无线通信系统中的一个重要组成部分。

它负责管理并控制整个无线通信系统的运行。

控制器可以监测和管理无线通信系统中的各种设备，如发射机、接收机、天线等。

3. 无线通信系统的应用3.1 移动通信移动通信是无线通信系统的重要应用之一。

它通过将无线电信号发送到移动设备，实现人与人之间的语音和数据传输。

现代移动通信系统包括蜂窝网络、卫星通信等。

3.2 无线局域网无线局域网是无线通信系统的另一个重要应用。

它使用无线电信号在有限区域内实现设备之间的通信。

无线局域网通常用于家庭、办公室等场所提供无线上网服务。

3.3 卫星通信卫星通信是一种通过卫星进行通信的无线通信系统。

它将信号发送到卫星上，再由卫星转发到目标地区。

红外无线语音系统的设计与实现王智伟（河北省省直房地产服务中心）摘要：本设计制作的这个系统是红外无线语音传输系统。

在系统设计时，使用的是一对850nm 波长的红外光发射、接收管。

利用它能够将声音进行传递。

在用手机的插头作为输入信号在通过电路的调试来实现语音信号传输，从而实现了定向，然后我在进行红外光收发系统的设计。

通过测试和查阅资料可以知道，5m 的传输距离是红外通信保证无明显失真情况下的极限距离。

通过放大和滤波电路，此时电路主要由LM-386所搭建。

同时我们还加了一个转制装置来实现90°的转变，最后输出端的喇叭中可以听到输入的语音。

关键词：红外；语音传输；无线通信Design and implementation of infrared wireless voice systemWang Zhiwei(Hebei provincial real estate service center)Abstract ：Science and technology continues to progress,and all kinds of communication technolgy are also in constant improvement progress.In the system design,I use a wave length of 850nm infrared transmitting and receiving e it to make sound ing a plug of the mobile phone as the input singal through the circuit debugging to realize voice signal transmission, so as to realize through tne orientation,and then I design the infrared transceiver system.Through the test and inspection date we can know that the transmission distance is 5m infrared communication to ensure no significant distortion limit distance under the condition of the amplifier and filter circuit.This circuit is mainly composed of LM-386 structures.At the same time, we alse add a conversion device to realize the transformation of 90 degree,the voice of the input can be heard in the horn of the output finally.Keywords ：Infrared ；Speech transmission ；Wireless communication 0 引言红外通信优点是高速率、低成本、低功耗，能实现近距离无线传输，所以首选设计为手持遥控器。

现代无线通信系统的例子现代无线通信系统是指利用无线电波进行信息传输的系统，广泛应用于手机、无线局域网、卫星通信等领域。

以下是10个现代无线通信系统的例子：1. 手机通信系统：手机通信系统是最常见的无线通信系统，它使用无线电波进行语音和数据传输。

手机通过基站与网络连接，实现与其他手机或固定电话的通信。

2. Wi-Fi无线局域网：Wi-Fi是一种局域网技术，使用无线电波使设备之间互相连接，实现无线上网和数据传输。

Wi-Fi广泛应用于家庭、办公室、公共场所等地方。

3. 蓝牙通信系统：蓝牙是一种短距离无线通信技术，可以实现设备之间的数据传输和通信。

蓝牙通常用于连接手机、耳机、音箱等设备。

4. GPS导航系统：GPS（全球定位系统）是一种卫星导航系统，通过接收卫星信号来确定地理位置和导航。

GPS广泛应用于汽车导航、户外定位等领域。

5. 无线电广播系统：无线电广播系统利用无线电波将音频信号传输到广播接收器，实现广播节目的传播。

无线电广播系统包括AM广播和FM广播。

6. 无线电频率识别系统（RFID）：RFID是一种无线通信技术，通过无线电波实现对物体的识别和跟踪。

RFID广泛应用于物流、库存管理、门禁系统等领域。

7. 卫星通信系统：卫星通信系统利用人造卫星进行数据传输和通信。

卫星通信系统可以实现全球范围内的通信，广泛应用于电话、电视、互联网等领域。

8. 短距离无线通信系统：短距离无线通信系统包括NFC（近场通信）、ZigBee等技术，用于实现设备之间的短距离无线通信和数据传输。

9. 无线传感器网络：无线传感器网络是由大量分布在空间中的传感器节点组成的网络，用于采集环境数据并进行传输和处理。

无线传感器网络广泛应用于环境监测、智能农业等领域。

10. 远程遥控系统：远程遥控系统利用无线通信技术实现对设备的远程控制。

远程遥控系统广泛应用于家庭、工业、军事等领域，实现对设备的远程操作和控制。

以上是10个现代无线通信系统的例子，它们在不同领域中发挥着重要的作用，改变了人们的生活和工作方式。

语音信号模拟传输系统实验设计与实现引言：语音信号模拟传输系统是一种将语音信号转化为电信号进行传输的系统。

它在通信、音频处理等领域有着广泛的应用。

本文将介绍语音信号模拟传输系统的实验设计与实现，包括系统的组成、实验步骤和实验结果分析。

一、系统组成语音信号模拟传输系统主要由以下几部分组成：语音采集模块、模拟信号调制模块、信号传输模块、模拟信号解调模块和语音重放模块。

1. 语音采集模块语音采集模块用于采集人声，并将其转化为模拟电信号。

常用的采集设备包括麦克风和声卡。

通过声卡，麦克风采集到的声音信号可以被转化为电信号，从而进行后续处理。

2. 模拟信号调制模块模拟信号调制模块将语音信号转化为模拟调制信号。

常用的调制方法有频率调制（FM）和幅度调制（AM）。

通过调制技术，语音信号可以被转化为适合传输的模拟信号。

3. 信号传输模块信号传输模块负责将模拟信号传输到接收端。

常用的传输介质有电缆、光纤和无线电波等。

传输过程中需要注意信号的衰减和噪声的干扰。

4. 模拟信号解调模块模拟信号解调模块将传输过来的模拟信号解调为原始语音信号。

解调方法与调制方法相对应，常用的解调方法有频率解调和幅度解调。

5. 语音重放模块语音重放模块用于将解调后的语音信号重新播放出来。

通过扬声器或耳机等设备，人们可以听到传输过来的语音信号。

二、实验步骤1. 进行语音采集在实验前，需要准备好麦克风和声卡，并连接到计算机上。

然后，使用录音软件进行语音采集，将采集到的声音保存为.wav格式文件。

2. 进行模拟信号调制将采集到的.wav文件导入到模拟信号调制软件中。

选择合适的调制方法，将语音信号转化为模拟调制信号。

3. 进行信号传输将模拟调制信号通过适当的传输介质传输到接收端。

根据实际情况选择合适的传输介质，并注意信号衰减和噪声干扰的问题。

4. 进行模拟信号解调在接收端，使用模拟信号解调软件对传输过来的模拟信号进行解调。

选择与调制方法相对应的解调方法，将模拟信号还原为原始语音信号。

基于FM调频的双路语音同传无线收发系统设计1. 背景介绍双路语音同传无线收发系统是一种用于同传翻译、会议交流等场景的通信系统。

该系统通过无线信号传输双方的语音信息，实现实时的语音传输和接收。

本文将介绍基于FM调频的双路语音同传无线收发系统的设计原理和实现方法。

2. 系统设计原理2.1 FM调频技术FM调频技术是一种常用的调制技术，它通过改变载波频率的方式将音频信号转换成无线信号。

在FM调频中，音频信号的振幅保持不变，而频率会随着音频信号的变化而改变。

这种调制方式能够有效地抵抗噪声干扰，提高音频信号的传输质量。

2.2 双路语音同传系统设计基于FM调频的双路语音同传无线收发系统由两部分组成：发射端和接收端。

发射端负责将语音信号转换成FM调频信号并进行传输，接收端负责接收并解调FM信号，将其转换成原始的语音信号。

发射端的主要组成部分包括：•语音输入模块：用于接收外部的语音信号。

•语音编码模块：将语音信号进行数字化编码，以便进行传输。

•FM调制模块：将数字化的语音信号转换成FM调频信号。

•发射天线：用于将FM调频信号进行无线传输。

接收端的主要组成部分包括：•接收天线：用于接收发射端发送的FM调频信号。

•FM解调模块：将FM调频信号解调成数字化的语音信号。

•语音解码模块：将数字化的语音信号进行解码，恢复成原始的语音信号。

•语音输出模块：用于输出解码后的语音信号。

3. 系统实现方法3.1 发射端实现方法发射端的实现方法如下：1.使用麦克风作为语音输入模块，将外部的语音信号转换成电信号。

2.将电信号经过模数转换器进行模数转换，将其转换成数字化的语音信号。

3.使用编码算法对数字化的语音信号进行编码，将其转换成编码后的语音信号。

4.使用FM调制器将编码后的语音信号进行FM调制，将其转换成FM调频信号。

5.将FM调频信号经过功率放大器放大后，通过发射天线进行无线传输。

3.2 接收端实现方法接收端的实现方法如下：1.使用接收天线接收发射端发送的FM调频信号。

基于IEEE802．15．4／ZigBee的语音通信系统李莉;王京梅;孙俊;龚伟家【期刊名称】《电子科技》【年(卷),期】2011(024)012【摘要】提出一种基于IEEE802.15.4的无线传输方案,该方案基于Chipcon公司开发的一款符合ZigBee标准的低功耗射频芯片CC2420,设计了以MSP430为处理器、CC2420芯片为无线通信芯片的无线语音通信系统。

使用的外围器件少,实现了短距离无线语音传输和方波输出的双向数据传输,并通过正弦波实验进行代码调试,具有成本低、音质好的优点%A wireless communications technology program based on IEEE802.15.4 is proposed.A low-power chip CC2420 which conforms with ZigBee specification developed by Chipcon Enterprise is used in this program.This paper briefly introduces the architecture of wireless voice communication and a design of wireless system which uses MSP430 microcontroller and CC2420 RF transceiver.A good short-range wireless transmission and PWM output are achieved by using small external components;the effectiveness of wireless transmission is tested by sine wave.The results show that this program has the advantages of low cost and better sound quality【总页数】4页(P56-59)【作者】李莉;王京梅;孙俊;龚伟家【作者单位】电子科技大学微电子与固体电子学院,四川成都610054;电子科技大学微电子与固体电子学院,四川成都610054;电子科技大学微电子与固体电子学院,四川成都610054;电子科技大学微电子与固体电子学院,四川成都610054【正文语种】中文【中图分类】TN92;TN912.3【相关文献】1.基于IEEE802.15.4的ZigBee无线传感器网络节点的设计与实现 [J], 吕俊霞;徐珂2.基于ZigBee技术的井下语音通信系统设计 [J], 曾永华3.基于IEEE802.15.4的ZigBee无线网络数据传输安全的研究与探讨 [J], 徐小涛;高泳洪;章炜;李家皋4.基于IEEE802.15.4的煤矿井下无线语音通信系统设计与实现 [J], 王大虎;张且且;孙一帆;史艳楠;陈文博5.基于ZigBee技术的煤矿井下无线语音通信系统研究 [J], 王大虎;张且且;孙一帆;史艳楠;陈文博因版权原因，仅展示原文概要，查看原文内容请购买。