The global minimum of a function is the lowest point or value that the function reaches within its entire domain. It represents the absolute minimum value of the function, as opposed to a local minimum which is only the lowest point within a specific region.
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The global minimum of a function is the lowest point on the function's graph, and it represents the absolute minimum value of the function.
To find the global minimum of a function, you must consider the function's behavior over its entire domain, not just a local region.
Concavity can be used to identify the global minimum of a function, as a function is concave up (convex) if it has a global minimum.
The first derivative of a function can be used to identify critical points, including the global minimum, where the derivative is equal to zero.
The second derivative of a function can be used to determine the nature of the critical points, including whether they represent a global minimum, global maximum, or saddle point.
Review Questions
Explain the difference between a global minimum and a local minimum of a function.
A global minimum is the absolute lowest point on the graph of a function, representing the function's lowest value over its entire domain. In contrast, a local minimum is a point on the graph where the function value is lower than the function values at nearby points, but it may not be the lowest value of the function overall. To determine if a critical point is a global minimum, you must consider the function's behavior over its entire domain, not just a local region.
Describe how the concavity of a function's graph can be used to identify the global minimum.
The concavity of a function's graph can provide information about the function's critical points, including the global minimum. If a function is concave up (convex) over its entire domain, then the function has a global minimum. This is because a concave up function has a single, lowest point, which represents the global minimum. Conversely, if a function is not concave up over its entire domain, it may have multiple local minima, and the global minimum may not be easily identifiable without further analysis.
Explain how the first and second derivatives of a function can be used to locate and classify the global minimum.
The first derivative of a function can be used to identify critical points, including the global minimum, where the derivative is equal to zero. However, the first derivative alone cannot distinguish between a global minimum, global maximum, or saddle point. The second derivative can then be used to classify the critical points. If the second derivative is positive at a critical point, then that point represents a local minimum. If the second derivative is negative at a critical point, then that point represents a local maximum. By analyzing the first and second derivatives over the function's entire domain, you can locate and classify the global minimum of the function.
A local minimum is a point on the graph of a function where the function value is lower than the function values at nearby points, but not necessarily the lowest value of the function over its entire domain.
The derivative of a function is a measure of the rate of change of the function at a given point, and it can be used to identify critical points, including local and global minima and maxima.