Question

Let x, y, and z be vectors in R³ such that (i) z = 3x (ii) y - x = 4 (iii) z × y = 4e₁ (standard basis vector); and (iv) ||x|| = 5. We are asked to determine the value of z· (2y+z) + || (x + 2y) × z||. First, let's simplify the expression z· (2y+z): z· (2y+z) = z·2y + z·z Using the distributive property of the dot product, we can rewrite this as: z· (2y+z) = 2(z·y) + z·z Next, let's find the value of z·y: From equation (ii), we know that y - x = 4. Rearranging this equation, we get: y = x + 4 Substituting this into equation (i), we have: z = 3x Substituting z = 3x into y = x + 4, we get: z·y = 3x·(x + 4) Expanding this using the distributive property, we have: z·y = 3(x·x + 4x) Using the property that x·x = ||x||², we can rewrite this as: z·y = 3(||x||² + 4x) Since we know that ||x|| = 5, we can substitute this into the equation: z·y = 3(5² + 4x) Simplifying further, we have: z·y = 3(25 + 4x) Expanding this, we get: z·y = 75 + 12x Now, let's find the value of z·z: From equation (i), we know that z = 3x. Substituting this into z·z, we have: z·z = (3x)·(3x) Using the property that (a·b)² = ||a||² ||b||² cos²θ, where θ is the angle between a and b, we can rewrite this as: z·z = (3² ||x||²) cos²θ Since ||x|| = 5, we can substitute this into the equation: z·z = (3² 5²) cos²θ Simplifying further, we have: z·z = 9(25) cos²θ z·z = 225 cos²θ Now, let's find the value of || (x + 2y) × z||: Using the distributive property of the cross product, we can rewrite this as: || (x + 2y) × z|| = ||x × z + 2y × z|| Since we know that z = 3x, we can substitute this into the equation: || (x + 2y) × z|| = ||x × 3x + 2y × 3x|| Expanding this using the distributive property, we have: || (x + 2y) × z|| = ||3x × x + 3x × 2y|| Using the property that a × b = -b × a, we can rewrite this as: || (x + 2y) × z|| = ||-x × 3x + 2y × 3x|| Expanding this further, we get: || (x + 2y) × z|| = ||-3x × x + 6y × x|| Using the property that a × a = 0, we can simplify this to: || (x + 2y) × z|| = ||6y × x|| Using the property that ||a × b|| = ||a|| ||b|| sinθ, where θ is the angle between a and b, we can rewrite this as: || (x + 2y) × z|| = 6 ||y|| ||x|| sinθ Since ||x|| = 5, we can substitute this into the equation: || (x + 2y) × z|| = 6 ||y|| (5) sinθ Simplifying further, we have: || (x + 2y) × z|| = 30 ||y|| sinθ Now, let's put it all together: z· (2y+z) + || (x + 2y) × z|| = 2(z·y) + z·z + || (x + 2y) × z|| Substituting the values we found earlier: z· (2y+z) + || (x + 2y) × z|| = 2(75 + 12x) + 225 cos²θ + 30 ||y|| sinθ This is the final expression.

          Let x, y, and z be vectors in R³ such that
(i) z = 3x 
(ii) y - x = 4 
(iii) z × y = 4e₁ (standard basis vector); and 
(iv) ||x|| = 5.

We are asked to determine the value of z· (2y+z) + || (x + 2y) × z||.

First, let's simplify the expression z· (2y+z):

z· (2y+z) = z·2y + z·z

Using the distributive property of the dot product, we can rewrite this as:

z· (2y+z) = 2(z·y) + z·z

Next, let's find the value of z·y:

From equation (ii), we know that y - x = 4. Rearranging this equation, we get:

y = x + 4

Substituting this into equation (i), we have:

z = 3x

Substituting z = 3x into y = x + 4, we get:

z·y = 3x·(x + 4)

Expanding this using the distributive property, we have:

z·y = 3(x·x + 4x)

Using the property that x·x = ||x||², we can rewrite this as:

z·y = 3(||x||² + 4x)

Since we know that ||x|| = 5, we can substitute this into the equation:

z·y = 3(5² + 4x)

Simplifying further, we have:

z·y = 3(25 + 4x)

Expanding this, we get:

z·y = 75 + 12x

Now, let's find the value of z·z:

From equation (i), we know that z = 3x. Substituting this into z·z, we have:

z·z = (3x)·(3x)

Using the property that (a·b)² = ||a||² ||b||² cos²θ, where θ is the angle between a and b, we can rewrite this as:

z·z = (3² ||x||²) cos²θ

Since ||x|| = 5, we can substitute this into the equation:

z·z = (3² 5²) cos²θ

Simplifying further, we have:

z·z = 9(25) cos²θ

z·z = 225 cos²θ

Now, let's find the value of || (x + 2y) × z||:

Using the distributive property of the cross product, we can rewrite this as:

|| (x + 2y) × z|| = ||x × z + 2y × z||

Since we know that z = 3x, we can substitute this into the equation:

|| (x + 2y) × z|| = ||x × 3x + 2y × 3x||

Expanding this using the distributive property, we have:

|| (x + 2y) × z|| = ||3x × x + 3x × 2y||

Using the property that a × b = -b × a, we can rewrite this as:

|| (x + 2y) × z|| = ||-x × 3x + 2y × 3x||

Expanding this further, we get:

|| (x + 2y) × z|| = ||-3x × x + 6y × x||

Using the property that a × a = 0, we can simplify this to:

|| (x + 2y) × z|| = ||6y × x||

Using the property that ||a × b|| = ||a|| ||b|| sinθ, where θ is the angle between a and b, we can rewrite this as:

|| (x + 2y) × z|| = 6 ||y|| ||x|| sinθ

Since ||x|| = 5, we can substitute this into the equation:

|| (x + 2y) × z|| = 6 ||y|| (5) sinθ

Simplifying further, we have:

|| (x + 2y) × z|| = 30 ||y|| sinθ

Now, let's put it all together:

z· (2y+z) + || (x + 2y) × z|| = 2(z·y) + z·z + || (x + 2y) × z||

Substituting the values we found earlier:

z· (2y+z) + || (x + 2y) × z|| = 2(75 + 12x) + 225 cos²θ + 30 ||y|| sinθ

This is the final expression.

Added by Dennis R.

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