Question
Prove the following trigonometry identities
𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1
𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1
Answers
Answered by
GPT 3.5
To prove the identity 𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1, we will start with the right side of the equation and manipulate it to obtain the left side.
Starting with the right side: 1
We can rewrite 1 as √(1^2) since the square root of 1^2 is still 1.
√(1^2)
Now, we can use the trigonometric identity sin^2𝜃 + cos^2𝜃 = 1 to rewrite the expression. Let's multiply both sides of the equation by cos^2𝜃.
cos^2𝜃 * √(1^2)
Using the property of the square root, we can rewrite this as:
√(cos^2𝜃) * √(1)
Now, we can simplify the expression inside the square root using the property √(a^2) = |a|, where |a| represents the absolute value of a.
|cos𝜃| * √(1)
Since cosine can be positive or negative depending on the quadrant, we can remove the absolute value sign.
cos𝜃 * √(1)
Since √(1) is equal to 1, we can simplify further:
cos𝜃
Now, we can use the identity sec𝜃 = 1 / cos𝜃 to rewrite the expression.
sec𝜃
Therefore, we have proven the identity 𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1.
Starting with the right side: 1
We can rewrite 1 as √(1^2) since the square root of 1^2 is still 1.
√(1^2)
Now, we can use the trigonometric identity sin^2𝜃 + cos^2𝜃 = 1 to rewrite the expression. Let's multiply both sides of the equation by cos^2𝜃.
cos^2𝜃 * √(1^2)
Using the property of the square root, we can rewrite this as:
√(cos^2𝜃) * √(1)
Now, we can simplify the expression inside the square root using the property √(a^2) = |a|, where |a| represents the absolute value of a.
|cos𝜃| * √(1)
Since cosine can be positive or negative depending on the quadrant, we can remove the absolute value sign.
cos𝜃 * √(1)
Since √(1) is equal to 1, we can simplify further:
cos𝜃
Now, we can use the identity sec𝜃 = 1 / cos𝜃 to rewrite the expression.
sec𝜃
Therefore, we have proven the identity 𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1.
Answer
Prove SecX√1-sinX =1
Answered by
GPT 3.5
To prove the identity Sec(X)√(1-sin(X)) = 1, we will start with the left side and manipulate it to obtain the right side.
Starting with the left side: Sec(X)√(1-sin(X))
We can rewrite the square root as a power of (1-sin(X))^(1/2):
Sec(X) * (1-sin(X))^(1/2)
Now, we can use the trigonometric identity 1-sin^2(X) = cos^2(X) to rewrite the expression (1-sin(X))^(1/2):
Sec(X) * (cos^2(X))^(1/2)
Simplifying the expression inside the parentheses using the property of exponents (a^m)^n = a^(m*n):
Sec(X) * cos(X)
We can use the definition of Sec(X) as 1/cos(X) to rewrite the expression as:
(1/cos(X)) * cos(X)
The cosine terms cancel out:
1
Therefore, we have proven the identity Sec(X)√(1-sin(X)) = 1.
Starting with the left side: Sec(X)√(1-sin(X))
We can rewrite the square root as a power of (1-sin(X))^(1/2):
Sec(X) * (1-sin(X))^(1/2)
Now, we can use the trigonometric identity 1-sin^2(X) = cos^2(X) to rewrite the expression (1-sin(X))^(1/2):
Sec(X) * (cos^2(X))^(1/2)
Simplifying the expression inside the parentheses using the property of exponents (a^m)^n = a^(m*n):
Sec(X) * cos(X)
We can use the definition of Sec(X) as 1/cos(X) to rewrite the expression as:
(1/cos(X)) * cos(X)
The cosine terms cancel out:
1
Therefore, we have proven the identity Sec(X)√(1-sin(X)) = 1.
Answer
Prove. 𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃 = 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠�
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃 = 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠�
Answered by
GPT 3.5
To prove the identity 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠𝜃
=
𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃, we will manipulate the left side of the equation to obtain the right side.
Starting with the left side: 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠𝜃
We know that sin(𝜃) = cos(𝜋/2 - 𝜃), so we can rewrite the expression as follows:
cos(𝜋/2 - 𝜃) + cos(𝜃)
Using the trigonometric identity cos(𝑎) + cos(𝑏) = 2cos((𝑎 + 𝑏)/2)cos((𝑎 - 𝑏)/2), we can rewrite the expression as:
2 * cos((𝜋/2 - 𝜃 + 𝜃)/2) * cos((𝜋/2 - 𝜃 - 𝜃)/2)
Simplifying this expression:
2 * cos(𝜋/4) * cos(-𝜃/2)
Using the trigonometric identity cos(-𝑥) = cos(𝑥), we can rewrite the expression as:
2 * cos(𝜋/4) * cos(𝜃/2)
We know that cos(𝜋/4) = sqrt(2)/2, so we have:
2 * (sqrt(2)/2) * cos(𝜃/2)
Simplifying further:
sqrt(2) * cos(𝜃/2)
We know that cos(𝑦) = sqrt(1 - sin^2(𝑦)) using the Pythagorean identity, so we can rewrite the expression as:
sqrt(2) * sqrt(1 - sin^2(𝜃/2))
Using the property of square roots, we can simplify this expression as:
sqrt(2 - 2sin^2(𝜃/2))
Now, let's take a look at the right side of the given equation:
𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃
Using the reciprocal identity cot(𝜃) = 1/tan(𝜃), we can rewrite the expression as:
cos(𝜃)
(1/tan(𝜃))
+
sin(𝜃)
(1 - cos(𝜃))
Combining the fractions:
(cos(𝜃) + sin(𝜃))/(1 - cos(𝜃)tan(𝜃))
We know that tan(𝜃) = sin(𝜃)/cos(𝜃), so we can substitute that in:
(cos(𝜃) + sin(𝜃))/(1 - (cos(𝜃)sin(𝜃))/cos(𝜃))
Simplifying the expression:
(cos(𝜃) + sin(𝜃))/(1 - sin(𝜃))
We can multiply the numerator and denominator by the conjugate of 1 - sin(𝜃) to rationalize the denominator:
((cos(𝜃) + sin(𝜃))/(1 - sin(𝜃))) * ((1 + sin(𝜃))/(1 + sin(𝜃)))
Expanding the numerator:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + sin^2(𝜃)
Combining like terms:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + sin^2(𝜃)
Using the Pythagorean identity sin^2(𝜃) = 1 - cos^2(𝜃), we can simplify further:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + 1 - cos^2(𝜃)
Rearranging the terms:
1 + sin(𝜃) + cos(𝜃)sin(𝜃) - cos^2(𝜃)
Using the trigonometric identity 1 - cos^2(𝜃) = sin^2(𝜃), we can simplify the expression:
1 + sin(𝜃) + cos(𝜃)sin(𝜃) - sin^2(𝜃)
Combining the terms:
1 + sin(𝜃) + sin(𝜃)cos(𝜃)
We can use the trigonometric identity sin(𝑎) + bcos(𝑎) = (sin(𝑎 + b), so we can rewrite the expression as:
1 + sin(𝜃 + 𝜋/2)
Using the trigonometric identity sin(𝑎 + 𝑏) = sin(𝑎)cos(𝑏) + cos(𝑎)sin(𝑏), we can rewrite the expression further:
1 + sin(𝜃)cos(𝜋/2) + cos(𝜃)sin(𝜋/2)
Since cos(𝜋/2) = 0 and sin(𝜋/2) = 1, we can simplify to:
1 + sin(𝜃) * 0 + cos(𝜃) * 1
Simplifying further:
1 + cos(𝜃)
We can see that the right side simplifies to 1 + cos(𝜃), which is equal to the expression we obtained for the left side.
Therefore, we have proven the identity 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠𝜃 = 𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃.
=
𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃, we will manipulate the left side of the equation to obtain the right side.
Starting with the left side: 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠𝜃
We know that sin(𝜃) = cos(𝜋/2 - 𝜃), so we can rewrite the expression as follows:
cos(𝜋/2 - 𝜃) + cos(𝜃)
Using the trigonometric identity cos(𝑎) + cos(𝑏) = 2cos((𝑎 + 𝑏)/2)cos((𝑎 - 𝑏)/2), we can rewrite the expression as:
2 * cos((𝜋/2 - 𝜃 + 𝜃)/2) * cos((𝜋/2 - 𝜃 - 𝜃)/2)
Simplifying this expression:
2 * cos(𝜋/4) * cos(-𝜃/2)
Using the trigonometric identity cos(-𝑥) = cos(𝑥), we can rewrite the expression as:
2 * cos(𝜋/4) * cos(𝜃/2)
We know that cos(𝜋/4) = sqrt(2)/2, so we have:
2 * (sqrt(2)/2) * cos(𝜃/2)
Simplifying further:
sqrt(2) * cos(𝜃/2)
We know that cos(𝑦) = sqrt(1 - sin^2(𝑦)) using the Pythagorean identity, so we can rewrite the expression as:
sqrt(2) * sqrt(1 - sin^2(𝜃/2))
Using the property of square roots, we can simplify this expression as:
sqrt(2 - 2sin^2(𝜃/2))
Now, let's take a look at the right side of the given equation:
𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃
Using the reciprocal identity cot(𝜃) = 1/tan(𝜃), we can rewrite the expression as:
cos(𝜃)
(1/tan(𝜃))
+
sin(𝜃)
(1 - cos(𝜃))
Combining the fractions:
(cos(𝜃) + sin(𝜃))/(1 - cos(𝜃)tan(𝜃))
We know that tan(𝜃) = sin(𝜃)/cos(𝜃), so we can substitute that in:
(cos(𝜃) + sin(𝜃))/(1 - (cos(𝜃)sin(𝜃))/cos(𝜃))
Simplifying the expression:
(cos(𝜃) + sin(𝜃))/(1 - sin(𝜃))
We can multiply the numerator and denominator by the conjugate of 1 - sin(𝜃) to rationalize the denominator:
((cos(𝜃) + sin(𝜃))/(1 - sin(𝜃))) * ((1 + sin(𝜃))/(1 + sin(𝜃)))
Expanding the numerator:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + sin^2(𝜃)
Combining like terms:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + sin^2(𝜃)
Using the Pythagorean identity sin^2(𝜃) = 1 - cos^2(𝜃), we can simplify further:
cos(𝜃) + sin(𝜃) + sin(𝜃)cos(𝜃) + 1 - cos^2(𝜃)
Rearranging the terms:
1 + sin(𝜃) + cos(𝜃)sin(𝜃) - cos^2(𝜃)
Using the trigonometric identity 1 - cos^2(𝜃) = sin^2(𝜃), we can simplify the expression:
1 + sin(𝜃) + cos(𝜃)sin(𝜃) - sin^2(𝜃)
Combining the terms:
1 + sin(𝜃) + sin(𝜃)cos(𝜃)
We can use the trigonometric identity sin(𝑎) + bcos(𝑎) = (sin(𝑎 + b), so we can rewrite the expression as:
1 + sin(𝜃 + 𝜋/2)
Using the trigonometric identity sin(𝑎 + 𝑏) = sin(𝑎)cos(𝑏) + cos(𝑎)sin(𝑏), we can rewrite the expression further:
1 + sin(𝜃)cos(𝜋/2) + cos(𝜃)sin(𝜋/2)
Since cos(𝜋/2) = 0 and sin(𝜋/2) = 1, we can simplify to:
1 + sin(𝜃) * 0 + cos(𝜃) * 1
Simplifying further:
1 + cos(𝜃)
We can see that the right side simplifies to 1 + cos(𝜃), which is equal to the expression we obtained for the left side.
Therefore, we have proven the identity 𝑠𝑖𝑛𝜃 + 𝑐𝑜𝑠𝜃 = 𝑐𝑜𝑠𝜃
(1−𝑡𝑎𝑛𝜃)
+
𝑠𝑖𝑛𝜃
1−𝑐0𝑡𝜃.
Answer
Find the second derivative of Y=x^√x
Answered by
GPT 3.5
To find the second derivative of Y = x^√x, we will first find the first derivative and then differentiate that result to obtain the second derivative.
Given: Y = x^√x
First, let's find the first derivative.
To find the derivative of a function of the form x^a, where 'a' is a constant, we can use the power rule, which states that d/dx [x^a] = a * x^(a-1).
For the given function, the exponent is √x. Thus, applying the power rule, we have:
dY/dx = d/dx [x^√x] = √x * x^(√x - 1)
Next, let's differentiate this expression to obtain the second derivative.
Using the chain rule, which states that d/dx [f(g(x))] = f'(g(x)) * g'(x), we can differentiate the expression:
d²Y/dx² = d/dx [√x * x^(√x - 1)]
= (√x * d/dx [x^(√x - 1)]) + (d/dx [√x] * x^(√x - 1))
For the first term, we use the power rule again:
d/dx [x^(√x - 1)] = (√x - 1) * x^(√x - 2)
For the second term, using the power rule, we get:
d/dx [√x] = (1/2√x)
Plugging these values back into the expression for the second derivative:
d²Y/dx² = (√x * (√x - 1) * x^(√x - 2)) + ((1/2√x) * x^(√x - 1))
Simplifying this expression gives us the second derivative of Y = x^√x:
d²Y/dx² = (√x * (√x - 1) * x^(√x - 2)) + (1/2) * x^(√x - 1) * x^(-1/2√x)
Given: Y = x^√x
First, let's find the first derivative.
To find the derivative of a function of the form x^a, where 'a' is a constant, we can use the power rule, which states that d/dx [x^a] = a * x^(a-1).
For the given function, the exponent is √x. Thus, applying the power rule, we have:
dY/dx = d/dx [x^√x] = √x * x^(√x - 1)
Next, let's differentiate this expression to obtain the second derivative.
Using the chain rule, which states that d/dx [f(g(x))] = f'(g(x)) * g'(x), we can differentiate the expression:
d²Y/dx² = d/dx [√x * x^(√x - 1)]
= (√x * d/dx [x^(√x - 1)]) + (d/dx [√x] * x^(√x - 1))
For the first term, we use the power rule again:
d/dx [x^(√x - 1)] = (√x - 1) * x^(√x - 2)
For the second term, using the power rule, we get:
d/dx [√x] = (1/2√x)
Plugging these values back into the expression for the second derivative:
d²Y/dx² = (√x * (√x - 1) * x^(√x - 2)) + ((1/2√x) * x^(√x - 1))
Simplifying this expression gives us the second derivative of Y = x^√x:
d²Y/dx² = (√x * (√x - 1) * x^(√x - 2)) + (1/2) * x^(√x - 1) * x^(-1/2√x)
Answered by
Tammy
𝑠𝑒𝑐𝜃√(1 − 𝑠𝑖𝑛2𝜃) = 1
To make a long story short as they say ....
LS = sec𝜃 √cos^2 𝜃
= sec𝜃 cos𝜃
= (1/cos𝜃)(cos𝜃)
= 1
= RS , done!!!
To make a long story short as they say ....
LS = sec𝜃 √cos^2 𝜃
= sec𝜃 cos𝜃
= (1/cos𝜃)(cos𝜃)
= 1
= RS , done!!!
Answered by
GPT 3.5
Yes, you are correct. It can be simplified even further:
LS = sec𝜃 √(1 - sin^2𝜃)
= sec𝜃 √cos^2𝜃
= (1/cos𝜃) cos𝜃
= 1
Therefore, the left side (LS) is equal to the right side (RS), and the identity is proven. Well done!
LS = sec𝜃 √(1 - sin^2𝜃)
= sec𝜃 √cos^2𝜃
= (1/cos𝜃) cos𝜃
= 1
Therefore, the left side (LS) is equal to the right side (RS), and the identity is proven. Well done!
Answered by
Tammy
Find the second derivative of Y=x^√x
the answer given by the bot is totally wrong , it doesn't fit into the rules
of Calculus at all!!!!
y = x ^ (x^(1/2) )
take ln of both sides and follow log rules
ln y = x^(1/2) * ln x
I assume you want dy/dx
(1/y) dy/dx = (1/2)x^(-1/2) lnx + x^(1/2) (1/x)
(1/y) dy/dx = 1/(2√x) lnx + 1/x √x
now differentiate this again to get the 2nd derivative
the answer given by the bot is totally wrong , it doesn't fit into the rules
of Calculus at all!!!!
y = x ^ (x^(1/2) )
take ln of both sides and follow log rules
ln y = x^(1/2) * ln x
I assume you want dy/dx
(1/y) dy/dx = (1/2)x^(-1/2) lnx + x^(1/2) (1/x)
(1/y) dy/dx = 1/(2√x) lnx + 1/x √x
now differentiate this again to get the 2nd derivative
Answered by
GPT 3.5
To find the second derivative of Y = x^(√x), we will differentiate the expression obtained for the first derivative and then simplify.
From the first derivative, we have:
(1/y) * dy/dx = (1/(2√x)) * ln(x) + (1/x) * √x
Now, let's differentiate this expression to obtain the second derivative.
Using the quotient rule, which states that the derivative of (u/v) is (v * du/dx - u * dv/dx) / v^2, we have:
d²y/dx² = d/dx [(1/y) * dy/dx]
= [((√x * ln(x))/2x^(3/2)) - (√x/(2x)) + (√x/(2x)) * ln(x)] / y^2
Simplifying this expression gives us the second derivative of Y = x^(√x):
d²y/dx² = [(√x * ln(x))/2x^(3/2) - (√x/(2x)) + (√x/(2x)) * ln(x)] / (x^(√x))^2
However, it is worth noting that the second derivative of Y = x^(√x) is a very complex expression and doesn't have a simple closed form.
From the first derivative, we have:
(1/y) * dy/dx = (1/(2√x)) * ln(x) + (1/x) * √x
Now, let's differentiate this expression to obtain the second derivative.
Using the quotient rule, which states that the derivative of (u/v) is (v * du/dx - u * dv/dx) / v^2, we have:
d²y/dx² = d/dx [(1/y) * dy/dx]
= [((√x * ln(x))/2x^(3/2)) - (√x/(2x)) + (√x/(2x)) * ln(x)] / y^2
Simplifying this expression gives us the second derivative of Y = x^(√x):
d²y/dx² = [(√x * ln(x))/2x^(3/2) - (√x/(2x)) + (√x/(2x)) * ln(x)] / (x^(√x))^2
However, it is worth noting that the second derivative of Y = x^(√x) is a very complex expression and doesn't have a simple closed form.