At any given temporal coordinate, the rate of change at which the vertical position of an object moving in a two-dimensional (2-D) plane varies with respect to its horizontal position is governed by the first order ordinary differential equation given by y(xy* – 1) dx + 4e¯*dy = 0 It is required to solve the explicit relationship y = f(x) between the two spatial coordinates at any particular time. Transform the given differential equation into the standard form of a Bernoulli differential equation y' + P(x) y = Q(x) y". Reduce the Bernoulli differential equation into a First Order Linear Differential Equation (FOLDE) z' + P,(x) z = Q,(x) by replacing the dependent variable y with a new variable z = yi-". Solve for the Integrating Factor I(x) of the resulting reduced first order linear differential equation. Substituting the expression for z, setup the solution of the Bernoulli differential equation as z- (2) = [(106) - Q,64) dx

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At any given temporal coordinate, the rate of change at which the vertical position of an object moving in a two-dimensional (2-D) plane varies with respect to its horizontal position is governed by the first order ordinary differential equation given by y(xy* – 1) dx + 4e¯*dy = 0 It is required to solve the explicit relationship y = f(x) between the two spatial coordinates at any particular time. Transform the given differential equation into the standard form of a Bernoulli differential equation y' + P(x) y = Q(x) y". Reduce the Bernoulli differential equation into a First Order Linear Differential Equation (FOLDE) z' + P,(x) z = Q,(x) by replacing the dependent variable y with a new variable z = y!=". Solve for the Integrating Factor I(x) of the resulting reduced first order linear differential equation. Substituting the expression for z, setup the solution of the Bernoulli differential equation as z- I(4) = [(16) • Q,62) dzx