(b) Construct the question text for a problem with exactly the same format as (a) but one dimension higher. That is: - Your question text will include two functions w = G(x, y, z) and z = F(x, y); - You have some freedom here in choosing numerical values for your version of the problem, e.g. you can define the 3D point of interest in the higher dimension question in any way you chose; - All the object names should be updated appropriately, e.g. if a line in the original problem becomes a plane when you added the new dimension, your question text should refer to a 'plane'; Example: your question text would start with the text "Let w be a function of x, y and z: W = G(x, y, z). Suppose that..." Note: in part (c),you will be solve this p () the problem Solve

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(a) Let z be a function of x and y: z = G(x, y). Suppose that G(1,2)= 30. Let the tangent plane to the graph of G at (1, 2, 30) be z = 30 + 2(x − 1) − 3(y − 2) The equation G (x, y) = 30 defines y implicitly as a function of x and we let that function be F(x). Find the tangent line to the graph of F at the point (1, 2).

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(b) Construct the question text for a problem with exactly the same format as (a) but one dimension higher. That is: - Your question text will include two functions w = G(x, y, z) and z = F(x, y); - You have some freedom here in choosing numerical values for your version of the problem, e.g. you can define the 3D point of interest in the higher dimension question in any way you chose; - All the object names should be updated appropriately, e.g. if a line in the original problem becomes a plane when you added the new dimension, your question text should refer to a 'plane'; Example: your question text would start with the text “Let w be a function of x, y and z: w = G(x, y, z). Suppose that..." Note: in part (c), eithe () problem solve the structing.