Volume is a derived quantity because it is calculated by multiplying three lengths together in the SI system of units. The SI base units for length are meters, so volume is expressed in cubic meters (m^3). It is not considered a fundamental quantity like length, mass, or time, which are base units in the SI system.
A fundamental quantity is a physical quantity that cannot be defined in terms of other physical quantities, while a derived quantity is a physical quantity that is defined in terms of fundamental quantities through mathematical relationships. Examples of fundamental quantities include mass, length, and time, while examples of derived quantities include velocity, acceleration, and energy.
Electric current is considered a fundamental quantity in physics. It is measured in units of amperes (A) and is one of the seven base SI units.
Derived quantities are quantities that are calculated from two or more measurements. They include area, volume, and density. The area of a rectangular surface is calculated as its length multiplied by its width. The volume of a rectangular solid is calculated as the product of its length, width, and height.
Fundamental quantities are independent and cannot be derived from other physical quantities, such as length, mass, and time. Derived quantities are dependent on fundamental quantities and are obtained through mathematical combinations of these fundamental quantities, such as velocity being derived from length and time.
Base quantities (Scalar Quantities) :Independent quantities who have single standard units.- time /seconds-distance/metersDerived Quantities (Vector Quantities):Quantities derived by multiplying or dividing 2 base quantities.- Velocity = distance/timeunit of Velocity = m/s
yes it is,it is derived by cubing the fundamental unit of length
the differentiate between fundamental quantity and derived quantity?
Fundamental quantities are quantities that can be measured such as mass, length and temperature. Derived quantities are quantities that has to be calculated such as pressure, volume and work done.AnswerThe SI does not define 'fundamental quantity', instead it uses the term 'Base Unit'. All other units are 'Derived Units', so-called because they are each derived from combinations of Base Units.
Length is fundamental, area is derived.
It is a derived quantity.
A fundamental quantity is a physical quantity that cannot be defined in terms of other physical quantities, while a derived quantity is a physical quantity that is defined in terms of fundamental quantities through mathematical relationships. Examples of fundamental quantities include mass, length, and time, while examples of derived quantities include velocity, acceleration, and energy.
Electric current is considered a fundamental quantity in physics. It is measured in units of amperes (A) and is one of the seven base SI units.
Volume is a fundamental quality because of volume per mass. Other familiar fundamental qualities include mass, velocity, speed, m3, cubic meter, and density.AnswerThere is no such thing as a 'fundamental unit' in SI. Units are either 'base units' or 'derived units'. In SI, volume is measured in cubic metres, where the metre is the base unit of length.
Volume is a fundamental quality because of volume per mass. Other familiar fundamental qualities include mass, velocity, speed, m3, cubic meter, and density.AnswerThere is no such thing as a 'fundamental unit' in SI. Units are either 'base units' or 'derived units'. In SI, volume is measured in cubic metres, where the metre is the base unit of length.
Volume is measured in units derived from the fundamental unit of length.
Derived quantities are quantities that are calculated from two or more measurements. They include area, volume, and density. The area of a rectangular surface is calculated as its length multiplied by its width. The volume of a rectangular solid is calculated as the product of its length, width, and height.
Fundamental quantities are independent and cannot be derived from other physical quantities, such as length, mass, and time. Derived quantities are dependent on fundamental quantities and are obtained through mathematical combinations of these fundamental quantities, such as velocity being derived from length and time.