Erect the Fence II
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Identifying Problem Isomorphism
“Erect the Fence II” can be mapped to “Smallest Circle Enclosing Points”.
“Erect the Fence II” appears to be a unique problem, as it involves geometric calculations specific to the scenario of enclosing a set of points (trees) with a circle of minimal radius. The task of finding the smallest enclosing circle for a given set of points in a 2D plane is not a common one in typical coding problems.
An approximate mapping can be drawn to the problem “Smallest Circle Enclosing Points”. In this problem, the task is to find the smallest possible circle that can enclose all the given points in a 2D plane. While this problem might not be exactly isomorphic, it deals with a similar theme of enclosing a set of points using a minimal geometric figure.
10 Prerequisite LeetCode Problems
“1924. Erect the Fence II” is a geometric problem that might involve concepts like Convex Hull and could involve complex data structures like Balanced Binary Search Trees. Here are ten simpler problems to prepare for it:
“593. Valid Square” - Basic understanding of geometric properties and calculations.
“223. Rectangle Area” - Involves geometric computations in 2D space.
“149. Max Points on a Line” - Gives insight into working with points on a plane.
“356. Line Reflection” - Involves geometric transformations and point symmetry.
“587. Erect the Fence” - It is the precursor problem and involves Convex Hull.
“447. Number of Boomerangs” - Deals with distances between points in a plane.
“939. Minimum Area Rectangle” - Understanding of geometric properties and calculations.
“218. The Skyline Problem” - Advanced problem involving geometric computations and using data structures like heaps.
“850. Rectangle Area II” - Complex geometric problem, involving the concepts of area and overlap of multiple rectangles.
“239. Sliding Window Maximum” - While not a geometric problem, the understanding of deque (a data structure) from this problem can be quite helpful for geometric problems.
The jump in complexity and the shift in the problem domain (from array/string to geometry) is quite big and may require you to study additional resources related to computational geometry.
“Erect the Fence II” could be a relatively complex problem involving computational geometry and mathematical algorithms, especially if it includes more complex operations such as the construction of Convex Hulls and others. Before you tackle such a problem, here are some problems that can help you build a solid understanding of dealing with points in a 2D plane and other related concepts:
Number of Islands (LeetCode 200): This problem helps you understand how to traverse a 2D grid effectively and how to group together points (or in this case, landmasses).
Convex Polygon (LeetCode 469): Understanding whether given points form a convex polygon is a precursor to constructing a convex hull.
Minimum Time Visiting All Points (LeetCode 1266): This problem will provide you with a good understanding of how to minimize distance while traversing points on a 2D plane.
K Closest Points to Origin (LeetCode 973): This problem will help you with sorting points based on their distance from a particular point (in this case, the origin).
Perfect Rectangle (LeetCode 391): This problem is another interesting problem involving points and rectangles.
Robot Bounded In Circle (LeetCode 1041): This problem involves understanding movements in a 2D plane, which is essential for computational geometry problems.
Problem Classification
Problem Statement:You are given a 2D integer array trees where trees[i] = [xi, yi] represents the location of the ith tree in the garden.
You are asked to fence the entire garden using the minimum length of rope possible. The garden is well-fenced only if all the trees are enclosed and the rope used forms a perfect circle. A tree is considered enclosed if it is inside or on the border of the circle.
More formally, you must form a circle using the rope with a center (x, y) and radius r where all trees lie inside or on the circle and r is minimum.
Return the center and radius of the circle as a length 3 array [x, y, r]. Answers within 10-5 of the actual answer will be accepted.
Example 1:
Input: trees = [[1,1],[2,2],[2,0],[2,4],[3,3],[4,2]] Output: [2.00000,2.00000,2.00000] Explanation: The fence will have center = (2, 2) and radius = 2
Example 2:
Input: trees = [[1,2],[2,2],[4,2]] Output: [2.50000,2.00000,1.50000] Explanation: The fence will have center = (2.5, 2) and radius = 1.5
Constraints:
1 <= trees.length <= 3000 trees[i].length == 2 0 <= xi, yi <= 3000
Analyze the provided problem statement. Categorize it based on its domain, ignoring ‘How’ it might be solved. Identify and list out the ‘What’ components. Based on these, further classify the problem. Explain your categorizations.
Visual Model of the Problem
How to visualize the problem statement for this problem?
Problem Restatement
Could you start by paraphrasing the problem statement in your own words? Try to distill the problem into its essential elements and make sure to clarify the requirements and constraints. This exercise should aid in understanding the problem better and aligning our thought process before jumping into solving it.
Abstract Representation of the Problem
Could you help me formulate an abstract representation of this problem?
Given this problem, how can we describe it in an abstract way that emphasizes the structure and key elements, without the specific real-world details?
Terminology
Are there any specialized terms, jargon, or technical concepts that are crucial to understanding this problem or solution? Could you define them and explain their role within the context of this problem?
Problem Simplification and Explanation
Could you please break down this problem into simpler terms? What are the key concepts involved and how do they interact? Can you also provide a metaphor or analogy to help me understand the problem better?
Constraints
Given the problem statement and the constraints provided, identify specific characteristics or conditions that can be exploited to our advantage in finding an efficient solution. Look for patterns or specific numerical ranges that could be useful in manipulating or interpreting the data.
What are the key insights from analyzing the constraints?
Case Analysis
Could you please provide additional examples or test cases that cover a wider range of the input space, including edge and boundary conditions? In doing so, could you also analyze each example to highlight different aspects of the problem, key constraints and potential pitfalls, as well as the reasoning behind the expected output for each case? This should help in generating key insights about the problem and ensuring the solution is robust and handles all possible scenarios.
Identification of Applicable Theoretical Concepts
Can you identify any mathematical or algorithmic concepts or properties that can be applied to simplify the problem or make it more manageable? Think about the nature of the operations or manipulations required by the problem statement. Are there existing theories, metrics, or methodologies in mathematics, computer science, or related fields that can be applied to calculate, measure, or perform these operations more effectively or efficiently?
Problem Breakdown and Solution Methodology
Given the problem statement, can you explain in detail how you would approach solving it? Please break down the process into smaller steps, illustrating how each step contributes to the overall solution. If applicable, consider using metaphors, analogies, or visual representations to make your explanation more intuitive. After explaining the process, can you also discuss how specific operations or changes in the problem’s parameters would affect the solution? Lastly, demonstrate the workings of your approach using one or more example cases.
Inference of Problem-Solving Approach from the Problem Statement
How did you infer from the problem statement that this problem can be solved using ?
Stepwise Refinement
Could you please provide a stepwise refinement of our approach to solving this problem?
How can we take the high-level solution approach and distill it into more granular, actionable steps?
Could you identify any parts of the problem that can be solved independently?
Are there any repeatable patterns within our solution?
Solution Approach and Analysis
Given the problem statement, can you explain in detail how you would approach solving it? Please break down the process into smaller steps, illustrating how each step contributes to the overall solution. If applicable, consider using metaphors, analogies, or visual representations to make your explanation more intuitive. After explaining the process, can you also discuss how specific operations or changes in the problem’s parameters would affect the solution? Lastly, demonstrate the workings of your approach using one or more example cases.
Thought Process
Explain the thought process by thinking step by step to solve this problem from the problem statement and code the final solution. Write code in Python3. What are the cues in the problem statement? What direction does it suggest in the approach to the problem? Generate insights about the problem statement.
From Brute Force to Optimal Solution
Could you please begin by illustrating a brute force solution for this problem? After detailing and discussing the inefficiencies of the brute force approach, could you then guide us through the process of optimizing this solution? Please explain each step towards optimization, discussing the reasoning behind each decision made, and how it improves upon the previous solution. Also, could you show how these optimizations impact the time and space complexity of our solution?
Coding Constructs
Consider the following piece of complex software code.
What are the high-level problem-solving strategies or techniques being used by this code?
If you had to explain the purpose of this code to a non-programmer, what would you say?
Can you identify the logical elements or constructs used in this code, independent of any programming language?
Could you describe the algorithmic approach used by this code in plain English?
What are the key steps or operations this code is performing on the input data, and why?
Can you identify the algorithmic patterns or strategies used by this code, irrespective of the specific programming language syntax?
Language Agnostic Coding Drills
Your mission is to deconstruct this code into the smallest possible learning units, each corresponding to a separate coding concept. Consider these concepts as unique coding drills that can be individually implemented and later assembled into the final solution.
Dissect the code and identify each distinct concept it contains. Remember, this process should be language-agnostic and generally applicable to most modern programming languages.
Once you’ve identified these coding concepts or drills, list them out in order of increasing difficulty. Provide a brief description of each concept and why it is classified at its particular difficulty level.
Next, describe the problem-solving approach that would lead from the problem statement to the final solution. Think about how each of these coding drills contributes to the overall solution. Elucidate the step-by-step process involved in using these drills to solve the problem. Please refrain from writing any actual code; we’re focusing on understanding the process and strategy.
Targeted Drills in Python
Now that you’ve identified and ordered the coding concepts from a complex software code in the previous exercise, let’s focus on creating Python-based coding drills for each of those concepts.
Begin by writing a separate piece of Python code that encapsulates each identified concept. These individual drills should illustrate how to implement each concept in Python. Please ensure that these are suitable even for those with a basic understanding of Python.
In addition to the general concepts, identify and write coding drills for any problem-specific concepts that might be needed to create a solution. Describe why these drills are essential for our problem.
Once all drills have been coded, describe how these pieces can be integrated together in the right order to solve the initial problem. Each drill should contribute to building up to the final solution.
Remember, the goal is to not only to write these drills but also to ensure that they can be cohesively assembled into one comprehensive solution.
Q&A
Similar Problems
Given the problem , identify and list down 10 similar problems on LeetCode. These should cover similar concepts or require similar problem-solving approaches as the provided problem. Please also give a brief reason as to why you think each problem is similar to the given problem.