Table 4.1: List of 2D kinematic equations for constant acceleration, with definitions of the variables used. Note that the equations for x and y look very similar, with only the subscripts changed. x-components Variable Ar Uzi az At a constant V₂f = V₂i + ª₂▲t ▲r = v¸¡▲t + ‡à¸▲t² Meaning y-components ay-constant Vyf = Vyi + ªyſt Ay = v¸¡▲t + ‡â„▲tª Meaning Variable Horizontal displacement Ay Vertical displacement Vyi The x-component of the initial velocity The x-component of the final velocity The x-component of the acceleration Vyf The y-component of the initial velocity The y-component of the final velocity The y-component of the acceleration ay The time interval between initial and final events (also written final tinitial or just t). az ay --9-9.8. (4.3) Q1: Simplify the general 2D kinematic equations for the case of an object in freefall where Vyi = 0, and a₂ = 0. You will have four equations total, two for the horizontal and two for the vertical direction.

PLEASE ANSWER ASAP TWO EQUATIONS FOR VERTICAL AND TWO EQUATIONS FOR HORIZONTAL

FOR Q2 DELTA Y = 71CM

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**Q2:** Use your simplified kinematics equations to write an expression for \( \Delta t \) in terms of known quantities. (Hint: You should already know \( \Delta y \) (measured), and \( g \) (a known constant)).

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**Table 4.1: List of 2D kinematic equations for constant acceleration, with definitions of the variables used.** *Note that the equations for x and y look very similar, with only the subscripts changed.* ### x-components - **\( a_x = \text{constant} \)** - \( v_{xf} = v_{xi} + a_x \Delta t \) - \( \Delta x = v_{xi} \Delta t + \frac{1}{2} a_x \Delta t^2 \) | Variable | Meaning | |----------|---------------------------------| | \( \Delta x \) | Horizontal displacement | | \( v_{xi} \) | The x-component of the initial velocity | | \( v_{xf} \) | The x-component of the final velocity | | \( a_x \) | The x-component of the acceleration | | \( \Delta t \) | The time interval between initial and final events (also written \( t_{\text{final}} - t_{\text{initial}} \) or just \( t \).) | ### y-components - **\( a_y = \text{constant} \)** - \( v_{yf} = v_{yi} + a_y \Delta t \) - \( \Delta y = v_{yi} \Delta t + \frac{1}{2} a_y \Delta t^2 \) | Variable | Meaning | |----------|---------------------------------| | \( \Delta y \) | Vertical displacement | | \( v_{yi} \) | The y-component of the initial velocity | | \( v_{yf} \) | The y-component of the final velocity | | \( a_y \) | The y-component of the acceleration | **Equation (4.3):** \( a_x = 0 \, \frac{m}{s^2}, \quad a_y = -g \approx -9.8 \, \frac{m}{s^2}. \) **Q1:** Simplify the general 2D kinematic equations for the case of an object in freefall where \( v_{yi} = 0 \), and \( a_x = 0 \). You will have four equations total, two for the horizontal and two for the vertical direction.