FreeNotes
Force: Derived from mass (kg), length (m), and time (s), using the equation F = ma (Newton’s Second Law). Pressure: Derived from mass, length, and time (P = Force/Area), so base quantities include mass (kg), length (m), and time (s). Power: Derived from mass, length, and time (P = Work/Time), so the base quantities are … Read more
Estimate your age in minutes and seconds. Assuming an average age of 20 years: 1 year = 365.25 days (accounting for leap years). 1 day = 24 hours = 1440 minutes = 86,400 seconds. Therefore, Age in minutes = 20 × 365.25 × 1440 = 10,513,200 minutes. Age in seconds = 10,513,200 × 60 = … Read more
Related Questions: Dynamics-1 Dynamics-II Pressure and Deformation in Solids Work and Energy Density and Temperature Magnetism Q.1 How does physics play an important role in our life? Q.2 Estimate your age in minutes and seconds. Q.3 What base quantities are involved in these derived physical quantities; force, pressure, power and charge. Q.4 Show that prefix … Read more
Statements: 1. Write the following numbers in scientific notation: a. 1234 m b. 0.000023 s c. 469.3 × 10⁷ m d. 0.00985 × 10⁵ s 2. Express the following measurements using prefixes: a. 27.5 × 10⁶ m b. 0.00023 × 10⁹ s 3. If a boy is 15 years, 2 months, and 10 days old, … Read more
Let’s first describe and draw the speed-time graphs for the three different types of motion: zero acceleration, uniform acceleration, and uniform deceleration. 1. Zero Acceleration (Constant Speed): In this case, the speed of the object remains constant over time. Since acceleration is zero, the graph will be a horizontal line. Graph: A straight horizontal line … Read more
Rest: The distance-time graph will be a horizontal line because the distance remains constant over time. Uniform Speed: The distance-time graph will be a straight line with a constant positive slope. Increasing Speed: The distance-time graph will be a curve that gets steeper as time progresses. Decreasing Speed: The distance-time graph will be a curve … Read more
Freely Falling Bodies: A freely falling body is an object that is falling under the influence of gravity only, without any resistance from air or other forces. This means that the only force acting on the body is the gravitational force, which pulls the object downward toward the Earth’s surface. In real-world conditions, air resistance … Read more
Speed: Speed is a scalar quantity that refers to the rate at which an object covers distance. It is calculated as the total distance traveled divided by the time taken. Speed does not have a direction. Example: A car traveling at 60 km/h. Velocity: Velocity is a vector quantity that refers to the rate at … Read more
Position: Position is a vector quantity that defines the location of an object in a given reference frame. It specifies the object’s location relative to a reference point (origin). Position is described by coordinates in space (e.g., (x, y) in 2D or (x, y, z) in 3D). Distance: Distance is a scalar quantity that represents … Read more
Scalars are physical quantities that are described by only their magnitude. They do not have a direction. Examples include: Speed: The rate at which an object covers distance (e.g., 60 km/h). Temperature: A measure of the heat or cold of a substance (e.g., 30°C). Mass: The amount of matter in an object (e.g., 5 kg). … Read more