What to include determines what, such as what the source decides, and so on

Does Character Really Determine Destiny? It seems to be an exaggerated assertion, and I don't know when I've heard this sentence too much, but now I feel more and more that this sentence is still very reasonable. Maybe this is a very idealistic statement, because there are many factors that affect a person's fate, such as social background, family background, educational background, social opportunities, etc., but a person's personality also accounts for a large proportion.

I don't know how a person's character is formed, is it related to innate factors? Or is it related to genetic factors? What is the education of the parents concerned?

Maybe it has something to do with all of this? But I feel that character determines destiny is not a simple empty phrase. First of all, put yourself in perspective.

Find your strengths. Then, let your strengths play to your strengths. This is the most basic condition for gaining self-confidence.

To gain self-confidence, you must first gain a sense of satisfaction and make yourself feel that you are very good. This is the most basic. Therefore, you need to make good use of your strengths and try to play to your strengths.

Do more, only in this way can you taste the satisfaction of success as much as possible, then you can build self-confidence. If you think you can't do anything, and you don't do anything, you don't dare to do anything. The less confident you become, it's a vicious circle.

As long as you get the satisfaction of success, you can further gain self-confidence. Of course, maybe take your time. You can start with small things and gradually increase them.

Self-confidence, in fact, is just a state of mind. All you need is to discover it yourself, and you don't need too many complicated processes. As long as you have faith in yourself, then you will definitely be full of strength.

Don't be overly considerate of others, pay too much attention to what others think of you. Deal with any setbacks with a nonchalant and normal mindset. Self-confidence, in fact, is very simple, just believe in yourself.

When you have self-confidence, you will be able to do everything. The key lies in yourself, as long as you have confidence in yourself, you can solve anything. In addition, the biggest factor of self-confidence is probably the influence of the outside world on you.

To know that what others say about us is always what they think, and we don't have to live in someone else's world. Just do your own thing. Why don't you care so much about him?

It is necessary to have the momentum that the world exists only for itself. Have the courage to go your own way and let others do what they say. No one can change themselves, no one can control themselves.

When you succeed, it's your own business, but if you are influenced by others and retreat, it's your own business, so why bother to control yourself for irrelevant people. The last sentence: Believe in yourself, and you will be full of self-confidence.

It's all about the mindset.

A wave or wave is a physical phenomenon in which perturbations or physical information propagate in space. The form of perturbation is arbitrary. The speed of propagation of a wave is always limited. Except for electromagnetic and gravitational waves, which are able to propagate in a vacuum, most waves, such as mechanical waves, can only propagate in a medium.

Fluctuations are an important form of material movement and are widely present in nature. There are many forms of disturbances or vibrations of the transmitted physical quantities, the transmission of mechanical vibrations constitutes mechanical waves, the transmission of electromagnetic field vibrations constitutes electromagnetic waves (including light waves), the transmission of temperature changes constitutes temperature waves (see liquid helium), the transmission of crystal lattice vibrations constitutes lattice waves (see lattice dynamics), the disturbance of spin magnetic moments forms spin waves when propagating in ferromagnets (see solid state physics), and in fact, any macroscopic or microscopic physical quantity can form waves when it is transmitted in space. The most common mechanical wave is the propagation process in space by the mechanical motion of the particles that make up the medium (causing changes in physical quantities such as displacement, density, pressure, etc.), such as waves in strings, water surface waves, sound waves in air or solids, etc.

The premise of these waves is that there is an elastic force or quasi-elastic force interaction between the adjacent particles of the medium, and it is with the help of this interaction force that the vibration of a certain point is transmitted to the adjacent particles, so these waves are also called elastic waves. The physical quantity of vibration can be a scalar quantity, and the corresponding wave is called a scalar wave (such as a sound wave in the air), or it can be a vector quantity, and the corresponding wave is called a vector wave (such as an electromagnetic wave).The direction of vibration that coincides with the direction of wave propagation is called a longitudinal wave, and the perpendicular direction is called a transverse wave.

The frequency of light is determined by the energy emitted by the electron transitione=hv, v=e is the -34th power of Planck's constant, and v is the frequency of light.

The frequency reacted to the same.

The vibration of the BAI position, the DU wavelength is the vibration of the entire space at the same time, and the DAO wave velocity is the propagation velocity.

It is generally accepted that the frequency is determined by the vibration of the source of the wave.

There are three more basic frequencies: the vibrational frequency at the source of the wave, the frequency in the medium, and the frequency of the observer.

If these three things are relatively stationary, the three frequencies are equal.

The wave velocity and wavelength depend on the static propagation environment, v = v0 n, wavelength = v f

Frequency: Vibration source.

Wavelength: vibrating source + medium.

Wave velocity: medium.

Frequency and wave velocity. Because wavelength = speed of wave frequency.

The frequency is determined by the source of the wave, that is, when the wave occurs.

The speed of the wave is determined by the medium, that is, when the wave travels.

The above applies to both mechanical waves (e.g., sound waves) and electromagnetic waves (e.g., light waves).

According to the theory of matter waves.

Wavelength = momentum of Planck's constant.

So it should be determined by momentum.

For mechanical waves, it is determined by the frequency and medium of the applied force;

For electromagnetic waves, it is determined by energy.

zhes, a property peculiar to matter, can only be said to be determined by nature.

It is determined by both the substance and the medium.

The wavelength is equal to the speed of the wave multiplied by the period.

Therefore, it is up to these two.

There is a material nature that dictates.

The explanation is as follows.

The timbre is determined by the material and structure of the emitter.

1. The timbre depends on the sound emitter itself, and the vibration of different sound emitters is different, and the timbre of the sound is different.

2. Timbre is the basis for us to distinguish various sounds, not affected by pitch and loudness, even if different musical instruments produce the same tone and loudness, we can also distinguish them, which is due to the difference in timbre.

If the timbre of a person's voice is determined by his own vocal cords, it is the vocal body.

If it is the timbre of electronic products, such as mobile phones, TVs, amplifiers, etc., the timbre of their sound is determined by the nature and material of the articulating body. Such as speakers, sound cards, etc.

The quality of the sound is also related to the debugging of the equipment. If the debugging is not in place, the sound quality will directly affect the timbre, and there will be no good results.

The timbre is mainly determined by the frequency spectrum of the sound, that is, it is composed of the combination of the base tone and the harmonic tones.

Different musical instruments, different people, and all the objects that can make sounds are formed by the accompaniment of a fundamental tone and different frequency overtones, which in turn determine the generation of different timbres, so that we can distinguish them from each other by the location of the source of the sound.

The timbre is absolutely determined by the articulation body, as well as the material of the pronunciation.

In fact, in this world, everyone's timbre is different. So when you hear a friend's voice, it's easy to tell whose voice it is.

This is because the frequencies of different sounds are not the same. It's like a guitar and a piano, they have different materials and different sounds.

The type and number of overtones determine the difference in timbre.

Ordinary sounds are composed of a series of different frequencies and different amplitudes emitted by the articulators. Of these vibrations, we call the tone from the vibration with the lowest frequency as the fundamental tone, and the tone from the vibration at the remaining frequencies as the overtone. And the overtones determine the timbre.

The timbre is determined by the nature of the articulating body, and each object will produce a frequency when it vibrates, and the vibration frequency of the object is not single, and the combined composite wave and the behavior composite wave are different, so the timbre is also different.

Different structures and materials of different emitters will also cause different timbres, so the timbre played by different instruments is different, and the timbre of the same instrument made of different materials is also different.

In general readings, it is said that timbre is determined by the nature of the articulatory body. But it is not stated what is going on with the nature of the articulatory body.

In fact, it is determined by the law of vibration of the vibrating body: the waveform of the vibration is usually not a single sine wave, but a composite wave composed of a series of waves. It is this complex wave that determines the timbre emitted by the vibrator.

Different articulation bodies have different natural vibration laws – mainly frequencies and waveforms, which naturally produce different timbres.

Timbre is also called a sound product, that is, the characteristics of various sounds. Timbre is mainly determined by the frequency spectrum of the sound, which can be simply understood as frequency and waveform. In addition, it is also related to sound pressure and the temporal characteristics of sound. And the timbre is determined only by the emitter itself.

In addition, only compound colors have a timbre, and solid colors have no timbre.

Sounds are made by vibrations.

For example, the timbre of the piano violin and the guitar is different, because they have different sound methods and different frequencies, such as some rely on the vibration of the strings, and some rely on the vibration of the air column.

There are many determining factors for timbre.

For example, the material and structure that occurs, the frequency of vibration, and the environment in which it is located are all related.

When I was in junior high school in physics, my teacher gave us experiments.

The sound of the tuning fork is different for different materials, and the sound is different for different forces of striking the tuning fork.

Hitting a tuning fork in water is still different from tapping in air.

Timbre is determined by the nature of the articulating body, specifically by the vibrating laws of the vibrating body, and different articulating bodies have different natural vibration laws - mainly frequency and waveform, which naturally produce different timbres.

The material, structure, and vibration of the articulation body all affect the timbre of the articulation body. Hope it helps