Linear (λ = q/l), Surface (σ = q/A), Volume (ρ = q/V)

Linear (λ = l/q), Surface (σ = A/q), Volume (ρ = V/q)

Linear (λ = q*l), Surface (σ = q*A), Volume (ρ = q*V)

Linear (λ = q/A), Surface (σ = q/V), Volume (ρ = q/l)

The charge is concentrated at a single point.

The charge is evenly spread throughout the object.

The charge density varies across the object.

The object has no net charge.

Sum all individual charges using integration.

Break the object into small charge increments.

Exploit the symmetry of the object.

Calculate the total charge of the object.

It increases the complexity of the problem.

It allows for the use of discrete charge calculations.

It helps to identify and cancel out electric field components in certain directions.

It determines the total charge of the object.

It approaches zero.

It approaches the electric field of a point charge.

It becomes infinitely large.

It remains constant regardless of length.

They add up to a large horizontal field.

They cancel each other out.

They combine to form a vertical field.

They are negligible and can be ignored.

k * (Q/L) * dx / (x^2 + b^2)

k * (Q/L) * dx * b / (x^2 + b^2)

k * (Q/L) * dx * b / (x^2 + b^2)^(3/2)

k * (Q/L) * dx * x / (x^2 + b^2)^(3/2)

Horizontally to the left.

Horizontally to the right.

Vertically upwards.

Vertically downwards.