The Evolution of Digital Audio: From CDs to Streaming Platforms

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The Evolution of Digital Audio: From CDs to Streaming Platforms

Digital Audio

Digital audio has come a long way since its humble beginnings. In the early days, digital audio was stored on cassette tapes and floppy disks, which were both bulky and inconvenient. However, the development of compact discs (CDs) in the 1980s revolutionized the way we listen to music. CDs offered superior sound quality to cassette tapes and were much more durable.

The Rise of CDs

The CD quickly became the dominant format for music distribution, and by the early 1990s, it had all but replaced vinyl records. CDs were not only more convenient than cassette tapes, but they also offered better sound quality. This was due to the fact that CDs use a digital format, which means that the sound is stored as a series of numbers. This is in contrast to analog formats, such as vinyl records, which store sound as a continuous wave.

The digital format of CDs also made it possible to create special features, such as bonus tracks and enhanced albums. These features helped to make CDs more appealing to consumers, and they also helped to drive sales.

The Rise of Streaming

In the early 2000s, a new technology began to challenge the dominance of CDs: streaming. Streaming allows users to listen to music online, without having to download or purchase any files. This made music more accessible than ever before, and it also helped to drive down the cost of music.

The rise of streaming has had a major impact on the music industry. CD sales have plummeted, and many record labels have been forced to adapt to the new reality. However, streaming has also created new opportunities for artists, as it has made it easier for them to reach a wider audience.

The Future of Digital Audio

It is still too early to say what the future of digital audio will hold. However, it is clear that streaming is here to stay. As streaming technology continues to improve, it is likely that it will become even more popular in the years to come.

In addition to streaming, there are also a number of other digital audio formats that are gaining popularity. These include lossless formats, such as FLAC and ALAC, which offer better sound quality than CDs. There are also a number of new technologies that are being developed, such as 3D audio, which could revolutionize the way we experience music.

Final words about the evolution of digital audio

The evolution of digital audio has been a fascinating journey. From the humble beginnings of cassette tapes to the cutting-edge technology of today, digital audio has changed the way we listen to music forever. It will be interesting to see what the future holds for this ever-evolving technology.

I hope this article has given you a better understanding of the evolution of digital audio.

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The Advantages of Digital Audio

Digital Audio

Introduction

Digital audio is a type of audio recording that uses digital signals to represent sound. This is in contrast to analog audio, which uses continuous waveforms to represent sound.

The Benefits of Digital Audio

Higher Fidelity

Digital audio can be recorded and reproduced with a higher degree of fidelity than analog audio. This means that digital audio can sound more realistic and accurate.

For example, a CD-quality audio file has a sample rate of 44,100 samples per second. This means that the sound is sampled 44,100 times every second. The higher the sample rate, the more accurate the representation of the sound wave.

Efficiency

Digital audio files are more efficient than analog audio files. This means that they take up less space and can be stored and transmitted more easily.

For example, a CD-quality audio file takes up about 650MB of space. This is a relatively small amount of space, especially considering the high quality of the audio.

Durability

Digital audio files are more durable than analog audio recordings. They are less susceptible to damage from scratches, dust, and other factors.

This is because digital audio files are stored as a series of numbers. These numbers are not affected by physical damage to the media on which they are stored.

Flexibility

Digital audio files can be easily edited and manipulated. This makes them ideal for a variety of applications, such as music production, sound design, and video editing.

For example, digital audio files can be easily trimmed, edited, and mixed. This makes it possible to create new and innovative sounds.

The Future of Digital Audio

The future of digital audio is bright. Digital audio is becoming increasingly popular, and it is being used in a wider range of applications.

As digital audio technology continues to develop, we can expect to see even higher quality audio with even greater flexibility. Digital audio is the future of audio, and it is sure to play an important role in our lives for many years to come.

Final Words about the Advantages of Digital Audio

Digital audio offers a number of advantages over analog audio. These advantages include higher fidelity, efficiency, durability, and flexibility. As digital audio technology continues to develop, we can expect to see even greater advantages in the future.

If you are looking for the best possible audio quality, then digital audio is the way to go. Digital audio files are also more efficient and durable than analog audio recordings. And, digital audio files can be easily edited and manipulated, making them ideal for a variety of applications.

So, if you are looking for the best possible audio experience, then digital audio is the way to go.

The World of Digital Audio: Codecs, Formats, and Bitrates

Digital audio

Digital audio is a broad term that encompasses a wide variety of audio formats, codecs, and bitrates. In this article, we will take a closer look at these three key concepts and how they impact the quality of digital audio.

Codecs

A codec is a device or program that compresses and decompresses digital data. In the context of digital audio, a codec is used to reduce the size of an audio file without sacrificing too much quality. There are many different codecs available, each with its own strengths and weaknesses. Some of the most popular codecs for digital audio include:

MP3: MP3 is a lossy codec, which means that some of the original audio data is removed during the compression process. This results in a smaller file size, but it also means that the quality of the audio may be slightly reduced.
AAC: AAC is another lossy codec that is similar to MP3. However, AAC is generally considered to be a higher quality codec than MP3.
FLAC: FLAC is a lossless codec, which means that no audio data is removed during the compression process. This results in a larger file size, but it also means that the quality of the audio is preserved.

Formats

A format is a specific way of storing digital audio data. There are many different audio formats available, each with its own advantages and disadvantages. Some of the most popular audio formats include:

WAV: WAV is a lossless format that is commonly used for storing uncompressed audio data. WAV files are typically very large, but they offer the highest possible audio quality.
MP3: MP3 is a lossy format that is commonly used for storing compressed audio data. MP3 files are much smaller than WAV files, but they may not offer the same level of audio quality.
AAC: AAC is another lossy format that is commonly used for storing compressed audio data. AAC files are typically smaller than MP3 files, and they may offer better audio quality.
FLAC: FLAC is a lossless format that is commonly used for storing compressed audio data. FLAC files are typically smaller than WAV files, but they offer the same level of audio quality.

Bitrates

A bitrate is a measure of the amount of data that is used to represent a digital audio signal. The higher the bitrate, the more data is used, and the higher the quality of the audio. However, higher bitrates also result in larger file sizes.

The optimal bitrate for a digital audio file depends on a number of factors, including the type of audio, the intended use of the file, and the capabilities of the playback device. For example, a high-quality audio file that is intended to be played on a high-end audio system may require a bitrate of 320 kbps or higher. However, an audio file that is intended to be played on a mobile device may only require a bitrate of 128 kbps or lower.

Conclusion

Digital audio is a complex topic, but it is important to understand the basics if you want to get the most out of your digital audio files. By understanding codecs, formats, and bitrates, you can choose the right audio files for your needs and ensure that you are always getting the best possible audio quality.

Here are some additional tips for choosing and using digital audio files:

Choose the right codec for your needs. If you need the highest possible audio quality, choose a lossless codec such as FLAC. If you are looking for a smaller file size, choose a lossy codec such as MP3 or AAC.
Choose the right format for your needs. If you need to store uncompressed audio data, choose a lossless format such as WAV. If you are looking for a smaller file size, choose a lossy format such as MP3 or AAC.
Choose the right bitrate for your needs. The higher the bitrate, the higher the quality of the audio. However, higher bitrates also result in larger file sizes.
Use a high-quality audio player. A good audio player will be able to reproduce the full range of frequencies and dynamics in your digital audio files.
Listen to your audio files in a quiet environment. This will help you to appreciate the full quality of the audio.

Digital Audio Signal Processing Basics

Digital Audio Signal

Audio signal processing is the process of manipulating digital audio signals. This can be done for a variety of purposes, such as noise reduction, equalization, and compression.

Here are some of the most common digital audio signal processing techniques:

Noise reduction: This technique is used to remove unwanted noise from an audio signal. This can be done using a variety of methods, such as averaging, filtering, and time-domain adaptive filtering.
Equalization: This technique is used to adjust the frequency response of an audio signal. This can be done to improve the sound quality of an audio signal, or to match the frequency response of a speaker system.
Compression: This technique is used to reduce the dynamic range of an audio signal. This can be done to make an audio signal louder, or to save space when storing an audio file.
Digital audio signal processing is a complex and ever-evolving field. However, the basic principles are relatively simple to understand.

Here are some of the most important concepts in digital audio signal processing:

Sampling: This is the process of converting an analog audio signal into a digital signal. This is done by taking a series of measurements of the analog signal at regular intervals.
Quantization: This is the process of rounding the digital values to a finite number of bits. This is done to reduce the amount of data that needs to be stored or transmitted.
Filtering: This is the process of removing unwanted components from an audio signal. This can be done using a variety of methods, such as FIR filters, IIR filters, and wavelet transforms.
Enhancement: This is the process of improving the quality of an audio signal. This can be done using a variety of methods, such as noise reduction, equalization, and compression.
Digital audio signal processing is a powerful tool that can be used to improve the sound quality of audio recordings. It can also be used to create new and exciting sounds.

If you are interested in learning more about digital audio signal processing, there are many resources available online and in libraries.

Frequently Asked Questions

Here are some of the most frequently asked questions about digital audio signal processing:

What is the difference between analog and digital audio?

Analog audio is a continuous signal, while digital audio is a discrete signal. This means that analog audio values can take on any value within a given range, while digital audio values can only take on a finite number of values.

Why is digital audio better than analog audio?

Digital audio is not necessarily better than analog audio. However, digital audio has some advantages over analog audio, such as:

It is less susceptible to noise.
It can be easily stored and transmitted.
It can be easily manipulated using digital audio signal processing techniques.
What are the different types of digital audio formats?

There are many different types of digital audio formats. Some of the most common formats include:

WAV: This is a lossless format that is commonly used for storing uncompressed audio.
MP3: This is a lossy format that is commonly used for storing compressed audio.
AAC: This is another lossy format that is commonly used for storing compressed audio.
FLAC: This is a lossless format that is commonly used for storing high-quality audio.
What are the different types of digital audio signal processing techniques?

There are many different types of digital audio signal processing techniques. Some of the most common techniques include:

Noise reduction: This technique is used to remove unwanted noise from an audio signal.
Equalization: This technique is used to adjust the frequency response of an audio signal.
Compression: This technique is used to reduce the dynamic range of an audio signal.
Enhancement: This is the process of improving the quality of an audio signal.

Conclusion

Digital audio signal processing is a powerful tool that can be used to improve the sound quality of audio recordings. It can also be used to create new and exciting sounds.

If you are interested in learning more about digital audio signal processing, there are many resources available online and in libraries.

Digital Audio: Representing Sound as Data

Digital Audio

Have you ever wondered how digital audio works? How can a computer store and play back sound, which is a continuous wave? The answer lies in digital audio, which is a way of representing sound as data.

In digital audio, sound is sampled at regular intervals. This means that the computer takes a snapshot of the sound wave at a certain point in time, and then stores that snapshot as data. The more frequently the sound is sampled, the more accurate the digital representation of the sound will be.

Once the sound has been sampled, it can be stored on a computer or other digital device. When the sound is played back, the computer reads the data and uses it to recreate the original sound wave.

Digital audio has many advantages over analog audio, which is the traditional way of storing and playing back sound. Digital audio is more accurate, it can be stored in smaller files, and it is less susceptible to noise and distortion.

Digital audio is also more versatile than analog audio. It can be easily edited, mixed, and mastered. It can also be stored and played back on a variety of devices, including computers, smartphones, and MP3 players.

How Digital Audio Works

Here is a more detailed explanation of how digital audio works:

The sound wave is first converted into an electrical signal. This is done by a microphone.
The electrical signal is then sampled at regular intervals. This is done by an analog-to-digital converter (ADC).
The samples are then stored as data. This can be done on a computer, a hard drive, or a CD.
When the sound is played back, the data is read from the storage device and converted back into an electrical signal. This is done by a digital-to-analog converter (DAC).
The electrical signal is then amplified and sent to a speaker.
The speaker converts the electrical signal back into sound waves, which are then audible to the listener.

The Benefits of Digital Audio

There are many benefits to using digital audio. Some of the most important benefits include:

Accuracy: Digital audio is more accurate than analog audio. This is because the sound is sampled at regular intervals, which ensures that the data is a true representation of the original sound wave.
Size: Digital audio files are much smaller than analog audio files. This is because the data is stored in a compressed format.
Versatility: Digital audio is more versatile than analog audio. It can be easily edited, mixed, and mastered. It can also be stored and played back on a variety of devices.

The Future of Digital Audio

Digital audio is the future of sound recording and playback. It is more accurate, smaller, and more versatile than analog audio. As technology continues to evolve, digital audio will become even more popular.

Conclusion

Digital audio is a powerful technology that has revolutionized the way we listen to music. It is more accurate, smaller, and more versatile than analog audio. As technology continues to evolve, digital audio will become even more popular.

Technical Aspects of Digital Audio

Digital Audio

Digital Audio Technology

As a music producer, I have always been fascinated by the technical aspects of digital audio. The technology behind digital audio has come a long way since its inception, and it continues to evolve at a rapid pace. One of the most significant advancements in digital audio technology is the use of digital signal processing (DSP) algorithms. These algorithms allow for the manipulation of audio signals in real-time, enabling producers to create complex soundscapes and effects.
In his book, “The Art of Digital Audio,” John Watkinson writes, “DSP algorithms are the key to the power of digital audio. They allow us to do things that were previously impossible with analog audio.” I couldn’t agree more. DSP algorithms have revolutionized the way we produce and consume music, and they continue to push the boundaries of what is possible.

Digital Audio Formats

When it comes to digital audio, there are a variety of formats to choose from. Each format has its own unique characteristics, and choosing the right one can make a significant difference in the quality of your audio. Some of the most popular digital audio formats include MP3, WAV, and FLAC.
Personally, I prefer to work with WAV files. They offer the highest quality audio and are compatible with most digital audio workstations (DAWs). However, they do take up a lot of storage space, so it’s essential to have a reliable backup system in place.

Digital Audio Editing

Digital audio editing is an essential part of the music production process. It allows producers to manipulate audio files in a variety of ways, from simple cuts and fades to complex time-stretching and pitch-shifting. One of the most popular digital audio editing tools is Pro Tools, which is widely used in the music industry.
In my experience, the key to successful digital audio editing is to have a clear vision of what you want to achieve. It’s easy to get lost in the endless possibilities of digital audio editing, so it’s essential to stay focused on your goals. As the famous producer Quincy Jones once said, “The most important thing is to have a vision for your music – one that is unique and true to who you are as an artist.”

Digital Audio Processing

Digital Audio Compression

Digital audio compression is a process that reduces the size of audio files without significantly affecting their quality. Compression is essential for streaming services like Spotify and Apple Music, which need to deliver high-quality audio over the internet. However, compression can also have a negative impact on the quality of the audio, particularly if it’s overdone.
In my opinion, it’s essential to strike a balance between file size and audio quality when compressing digital audio. As the saying goes, “less is more.” It’s better to have a smaller file size with slightly lower audio quality than a massive file size with no noticeable improvement in quality.

Digital Audio Quality

Digital audio quality is a topic that is often debated among music producers and audiophiles. Some argue that digital audio can never match the warmth and depth of analog audio, while others believe that digital audio has surpassed analog in terms of quality.
In my experience, digital audio quality has come a long way in recent years. With high-resolution audio formats like FLAC and MQA, it’s now possible to achieve audio quality that rivals or even surpasses analog. However, it’s essential to have a high-quality playback system to fully appreciate the nuances of digital audio.

Digital Audio Production

Digital audio production is the process of creating music using digital tools and technology. It’s a complex and challenging process that requires a combination of technical skill and artistic vision. One of the most critical aspects of digital audio production is the ability to collaborate effectively with other musicians and producers.
In my experience, the key to successful digital audio production is to stay organized and focused. It’s easy to get lost in the endless possibilities of digital audio, so it’s essential to have a clear plan and timeline for your project. As the famous producer Rick Rubin once said, “The most important thing is to capture the essence of the song and the artist’s performance.”
Final Words:
In conclusion, the technical aspects of digital audio are complex and ever-evolving. From digital audio technology to digital audio production, there are many factors to consider when working with digital audio. However, with the right tools and techniques, it’s possible to achieve high-quality audio that rivals or even surpasses analog. As a music producer, I’m excited to see where the future of digital audio will take us.
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What is Digital Audio and How Does it Work?

Digital Audio

Digital audio is a technology that allows us to record, store, and reproduce sound in a digital format. Unlike analog audio, which is recorded and stored as a continuous wave, digital audio is converted into a series of numbers that represent the amplitude of the sound wave at different points in time. These numbers are then stored as digital data, which can be played back using a digital-to-analog converter (DAC).

Digital Audio Technology

One of the key technologies used in digital audio is audio encoding. This is the process of converting analog audio signals into digital data that can be stored and manipulated. There are several different audio encoding formats, including MP3, AAC, and FLAC. Each format has its own advantages and disadvantages, depending on factors such as sound quality, file size, and compatibility with different devices.

Another important technology used in digital audio is audio compression. This is the process of reducing the size of digital audio files by removing redundant or unnecessary data. There are two main types of audio compression: lossy compression and lossless compression. Lossy compression, as the name suggests, involves removing data from the audio file that is deemed to be less important, resulting in a smaller file size but also a loss of some of the original sound quality. Lossless compression, on the other hand, preserves all of the original data but still reduces the file size.

As author David Mellor explains in his book “Digital Audio Explained,” “digital audio technology has made it possible to record and manipulate sound with an unprecedented level of accuracy and precision.” This has led to a range of new applications for audio, including music production, sound design, and audio post-production for film and television.

Digital Audio File Types

There are several different types of digital audio files, each with its own file extension and format. Some of the most common file types include MP3, WAV, AIFF, and FLAC. Each format has its own strengths and weaknesses, depending on factors such as sound quality, file size, and compatibility with different devices.

For example, MP3 is a popular format for music files because it is small in size and can be played on most devices. However, it uses lossy compression, which means that some of the original audio data is lost during the encoding process. WAV, on the other hand, is a lossless format that preserves all of the original audio data, but is larger in size and may not be compatible with all devices.

Advantages of Digital Audio

One of the main advantages of digital audio is that it allows for a high level of precision and control over the sound. This makes it possible to manipulate audio in ways that were not possible with analog audio, such as applying digital effects and processing, editing audio with a high degree of precision, and adjusting the levels of different tracks in a mix.

Digital audio also allows for easy sharing and distribution of audio files, since they can be stored and transferred as digital data. This has led to the development of online music stores, streaming services, and other digital audio platforms that have transformed the way we listen to and consume music.

As author Robert A. Turnbaugh explains in his book “Introduction to Digital Audio,” “digital audio has revolutionized the way we create, produce, and distribute sound.” Whether you are a professional audio engineer or a casual listener, digital audio has opened up new possibilities for how we interact with sound.

Conclusion:

In conclusion, digital audio is a fascinating and complex topic that involves many technical aspects. Understanding the basics of digital audio, such as sampling rate, bit depth, and file formats, can help you get the most out of your digital audio experience. It can also help you troubleshoot any issues you might encounter with your digital audio files.

We hope this article has been informative and helpful in providing a basic understanding of digital audio. Remember, the key to optimizing your digital audio experience is to keep learning and experimenting with different techniques and tools.

As musician and audio engineer Steve Albini once said, “The only way to learn how to make records is to be making records.” So get out there and start exploring the world of digital audio, and don’t be afraid to try new things.

Thank you for reading this article, and we hope you found it helpful. If you have any questions or comments, feel free to leave them below. And remember, if you’re looking for a reliable and effective audio normalization and conversion tool, give MP4Gain a try.

What is Digital Audio?

Digital audio is a method of storing audio data on a computer or digital device. Audio data is essentially a collection of sound waves, and to store it digitally, we need to convert these sound waves into a series of numbers that a computer can understand.

What is Digital Audio?

To do this, we use a process called “analog-to-digital conversion”. Analog audio signals are transformed into digital data by measuring the sound wave at regular intervals and assigning each measurement a numerical value. The process of measuring sound waves is called “sampling”, and the numerical values assigned to each sample are known as “bit depth”.

In essence, the audio signal is converted into a series of binary digits (1s and 0s) that can be stored on a computer. This allows us to manipulate, edit, and reproduce audio data in various ways.

How is Audio Converted to Digital Audio?

As mentioned earlier, audio is converted to digital audio using a process called “sampling”. Sampling involves taking snapshots of the audio signal at regular intervals, known as the “sampling rate”. The more samples that are taken per second, the more accurately the original sound can be reconstructed.

Imagine taking a picture of a person running. If you take one picture per second, you’ll see the person moving, but the motion won’t be smooth. If you take 10 pictures per second, the motion will be smoother, and if you take 60 pictures per second, the motion will be very smooth.

The same principle applies to digital audio. By taking many samples per second, the original sound can be accurately reconstructed. The number of samples taken per second is called the “sampling rate”, and it’s usually measured in Hertz (Hz). For example, a typical sampling rate for CD-quality audio is 44.1kHz, which means that 44,100 samples are taken per second.

Once the audio has been sampled, each sample is converted into a digital number. The number represents the amplitude of the sound wave at that particular moment. The amplitude of a sound wave is the height of the wave, and it determines how loud or quiet the sound is.

The digital numbers obtained from each sample are stored as binary data, which can be easily stored, edited, and reproduced on a computer.

What is an MP3?

An MP3 is a type of digital audio file that uses a technique called “lossy compression”. This means that some of the data in the original audio file is removed in order to reduce the file size. The removed data is typically inaudible to the human ear, so the overall quality of the audio is not significantly affected.

MP3s achieve this compression by using a technique called “perceptual coding”. This involves analyzing the audio signal and identifying the parts that are less important to the overall sound quality. These parts are then removed, leaving only the most important parts of the audio signal intact.

For example, let’s say you have a song that is 4 minutes long and takes up 40MB of storage space on your computer. If you were to convert that song into an MP3 file, the resulting file might only be 4MB in size, while still maintaining a high level of audio quality.

MP3 files are a popular choice for digital audio because they take up less space than other audio formats, making them easier to store and share. They’re also supported by most digital audio players and software, making them a versatile and widely used format.

How are Sound Waves Converted into Digital Numbers?

As we mentioned earlier, sound waves are converted into digital numbers using a process called “analog-to-digital conversion”. This process involves several steps:

Sampling: The analog audio signal is measured at regular intervals, known as the sampling rate. Each sample is a snapshot of the audio signal at that particular moment.

Quantization: Each sample is assigned a numerical value that represents the amplitude of the sound wave at that moment. This is done using a process called quantization, which assigns a specific digital value to each sample.

Encoding: The digital values obtained from quantization are then converted into binary data. This is done using a process called encoding, which converts each digital value into a series of 1s and 0s.

Compression: Depending on the file format being used, the digital audio data may be compressed in order to reduce its file size. Lossy compression, as we discussed earlier, involves removing some of the data from the original audio file to reduce its size, while maintaining a high level of audio quality. Lossless compression, on the other hand, compresses the file size without sacrificing any data or quality.

Once the audio has been converted into digital data, it can be easily manipulated, edited, and reproduced on a computer or digital device. This allows us to do things like change the volume, apply special effects, and even create entirely new compositions using existing audio samples.

In summary, digital audio is a way of storing and manipulating audio data using a series of numbers that a computer can understand. Analog-to-digital conversion is the process of converting sound waves into digital data, which involves sampling, quantization, encoding, and compression. MP3s are a popular type of digital audio file that use lossy compression to reduce file size, while maintaining a high level of audio quality.

What is digital audio?

How does digital audio work?

What is the rate? Of course, I can’t directly explain to you that “rate is bitrate”. When you play sound files with some software, you should notice a small message. For example, “128Kbps”, “1411Kbps”… Some friends also know that under normal circumstances, the larger the number in front of “Kbps”, the better the sound effect, for example, CD is “1411Kbps”. So what exactly do these numbers represent? In a nutshell, how much data is converted into sound per second. The reason CDs sound better than MP3s is that CDs have more information per second than MP3s. For example, compared to a 1411 Kbps CD file, a 128 Kbps MP3 file can convert almost 12 times less data per second than a CD. For the same song, the CD is much more delicate to listen to (of course, there is a group of people in the crowd known as “mushrooms” who can feel that the effect is the same) MP3 expresses the same content with less data and, of course, its level of detail is not as good as that of a CD.

2. Sampling rate.

Sampling rate is also a very common term. The specific form is “XXHz”, where “XX” is a specific number. Such as “44100Hz (44.1KHz)”, “32000Hz (32KHz)” and so on. As mentioned above, digital audio files are made up of many “points”, so the sample rate is actually a standard “quantity” to collect these “points”. Obviously, the sampling rate of “44100 Hz” is higher than that of “32000 Hz”, so more points are collected per time unit (1 second). The more points per unit of time, the more complete the sound information and, of course, the closer to reality. So if the guaranteed rate is the same, the file “44100Hz” is better than “32000Hz” (of course, this is not absolute).

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lossy compression

In fact, we are all familiar with lossy compressed audio sources. At present, popular lossy formats mainly include MP3, WMA, OGG, MP3pro, AAC, VQF, ASF, etc.

2.WMV format

The full name of WMA is WindowsMedia Audio, which is an audio format promoted by Microsoft. The WMA format achieves a higher compression ratio by reducing the data stream while maintaining sound quality. The compression ratio can usually reach 1:18, and the generated file size is only half of the corresponding MP3 file.

3.MP3 format

The full name of MP3 is MovingPicture Experts Group Audio Layer Ⅲ. In a nutshell, MP3 is an audio compression technology. Since the full name of this compression method is called MPEGAAudio Layer 3, people call it MP3 for short. It was born in 1993, and its “parents” are the German FaunhofeIIS and the French Thomson.

MP3 uses MPEGAudio Layer 3 technology to compress music into smaller files with a compression ratio of 1:10 or even 1:12. In other words, you can compress files to a smaller size with little loss of sound quality. And it keeps the original sound quality very well. It is precisely because of MP3’s small size and high sound quality that the MP3 format has become almost synonymous with online music. The MP3 format of music per minute is only 1 MB in size, so the size of each song is only 3-4 megabytes. Use an MP3 player to uncompress (decode) MP3 files in real time so that high-quality MP3 music can be played.

What is digital audio?

How does digital audio work?

In our daily lives, we listen to all kinds of music, and most of this music is transmitted in digital form, whether it is listened to or downloaded to a computer or played on an MP3 or CD player. Of course, you will often see various formats like MP3, WMV, APE, etc., but do you understand the meaning of these formats? Below I have compiled some of this content for you, I hope it helps you.

1. Introduction to digital music

Digital audio sources, that is, digital audio formats, first referred to CDs. After the CDs were compressed, a variety of formats suitable for playback on Walkmans were derived. These compressed formats can be divided into two categories: there is lossy and lossless compression. The compression mentioned here refers to converting the audio stream encoded in PCM or WAV format to other formats after special compression processing, so as to achieve the effect of reducing the file size. Lossy/Lossless refers to whether the sound signal retained in the new file is reduced compared to the original PCM/WAV format signal after compression.

PCM encoding is short for PulseCode Modulation, also known as Pulse Code Modulation, which is one of the digital communication encoding methods. The sampled value is rounded and quantized according to the hierarchical unit, and the sampled value is represented by a set of binary codes to represent the amplitude of the sampled pulse.

The final form of the digital audio signal is still made up of “0/1”. They can be any permutation and combination, such as “0001110101” or “11100001010”. Of course, different combinations have different effects. Seeing this, some friends should have noticed. If the sound is recorded in the form of “00101010”, then the final form is not a “dot”, that is, a simple “change” process. The sound is continuous, how can it be recorded with “dots”? Shouldn’t the sound we hear be segment by segment? The reason is not difficult to understand. Go home and turn on the fluorescent light, can you find the fluorescent light flickering? can not? In fact, fluorescent lights flicker constantly. Have you seen cartoons? They are all connected by a grid of still images. We can also simply understand the images one by one as “dots” one by one. Man against nature

There are limits to the sense of the world, both visual and auditory. The reason cartoons can produce coherent motion is that these “dots” are an illusion that people create when human vision doesn’t respond in time. With the exception of machines, people cannot distinguish these “dots”. So is the sound. If the frequency of the sound flicker is very fast, people cannot distinguish it. Also, when the sound performs a “digital conversion of analog signals” (D/A conversion), the decoder chip has already connected these “dots” coherently, so we hear a very coherent sound.

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