JoVE Logo

로그인

Scientists frequently use models to help them comprehend a specific collection of phenomena. In physics, a model is a condensed version of a physical system that is too complex to study thoroughly. One such example is the light wave model; unlike water waves, light waves are typically invisible to us. Nonetheless, it is helpful to think of light as being composed of waves, since investigations show that light behaves like water waves. Since it is impossible to visually see what is genuinely happening, a model serves as a rough mental or visual representation of the phenomenon. A model typically resembles the phenomenon being investigated structurally and is relatively simple. A helpful model preserves an issue's critical components while simplifying it just enough to make it workable.

Meanwhile, a theory is more comprehensive, in-depth, and capable of making precise predictions that can be tested statistically. The phenomenon being studied is referred to as a theory for a broader perspective.

Physicists study natural occurrences and look for connections linking them. When these patterns are well-established and frequently applied, they are referred to as physical laws or principles. Certain succinct but general comments made by scientists about how nature functions have been classified as laws. The statement of a law frequently takes the form of an equation or relationship between two quantities. For example, the law of conservation of charges states that the net electric charge of an isolated system always remains conserved. Most of the time, experiments support the statements referred to as laws across a broad spectrum of observable occurrences. A statement is called a "law" when its applicability has been established across a broad spectrum of situations, and any restrictions and the range of the applicability are well understood.

It is crucial to distinguish between a model or a theory and the actual system or occurrences. Scientific laws are descriptive and intended to describe how nature behaves, not how it ought to behave. Laws, like theories, cannot be tested in every scenario.

Tags

ModelsTheoriesLawsScientific ModelsLight Wave ModelPhysical SystemsPredictionsPhysical LawsConservation Of ChargeScientific PrinciplesObservable OccurrencesNatural Phenomena

장에서 1:

article

Now Playing

1.3 : Models, Theories, and Laws

Units, Dimensions, and Measurements

5.0K Views

article

1.1 : 물리학의 범위

Units, Dimensions, and Measurements

25.5K Views

article

1.2 : 크기 순서

Units, Dimensions, and Measurements

16.4K Views

article

1.4 : 측정 단위 및 표준

Units, Dimensions, and Measurements

30.6K Views

article

1.5 : 물리량의 추정

Units, Dimensions, and Measurements

4.0K Views

article

1.6 : 기본 수량 및 파생 수량

Units, Dimensions, and Measurements

19.6K Views

article

1.7 : 단위의 변환

Units, Dimensions, and Measurements

21.4K Views

article

1.8 : 정확성 및 정밀도

Units, Dimensions, and Measurements

8.5K Views

article

1.9 : 무작위적이고 체계적인 오류

Units, Dimensions, and Measurements

10.7K Views

article

1.10 : 유의미한 숫자에 대한 규칙

Units, Dimensions, and Measurements

12.3K Views

article

1.11 : 계산에서 중요한 수치

Units, Dimensions, and Measurements

10.2K Views

article

1.12 : 차원 해석

Units, Dimensions, and Measurements

14.6K Views

article

1.13 : 문제 해결: 차원 해석

Units, Dimensions, and Measurements

3.1K Views

article

1.14 : 물리학의 문제 해결

Units, Dimensions, and Measurements

5.6K Views

JoVE Logo

개인 정보 보호

이용 약관

정책

연구

교육

JoVE 소개

Copyright © 2025 MyJoVE Corporation. 판권 소유