In diesem Artikel besprechen wir den linearen Suchalgorithmus. Unter Suchen versteht man den Vorgang, ein bestimmtes Element in der Liste zu finden. Wenn das Element in der Liste vorhanden ist, wird der Prozess als erfolgreich bezeichnet und der Prozess gibt die Position dieses Elements zurück. andernfalls wird die Suche als erfolglos bezeichnet.
Zwei beliebte Suchmethoden sind die lineare Suche und die binäre Suche. Deshalb werden wir hier die beliebte Suchtechnik diskutieren, d. h. den linearen Suchalgorithmus.
Die lineare Suche wird auch als bezeichnet Sequentielle Suchalgorithmus. Es ist der einfachste Suchalgorithmus. Bei der linearen Suche durchlaufen wir einfach die Liste vollständig und ordnen jedes Element der Liste dem Element zu, dessen Position gefunden werden soll. Wenn die Übereinstimmung gefunden wird, wird der Speicherort des Elements zurückgegeben. andernfalls gibt der Algorithmus NULL zurück.
Es wird häufig verwendet, um ein Element in der ungeordneten Liste zu suchen, d. h. der Liste, in der die Elemente nicht sortiert sind. Die zeitliche Komplexität der linearen Suche im schlimmsten Fall beträgt An).
Die bei der Implementierung der linearen Suche verwendeten Schritte sind wie folgt aufgeführt:
- Zuerst müssen wir die Array-Elemente mit a durchlaufen für Schleife.
- In jeder Iteration von for-Schleife, Vergleichen Sie das Suchelement mit dem aktuellen Array-Element und -
- Wenn das Element übereinstimmt, wird der Index des entsprechenden Array-Elements zurückgegeben.
- Wenn das Element nicht übereinstimmt, fahren Sie mit dem nächsten Element fort.
- Wenn es keine Übereinstimmung gibt oder das Suchelement nicht im angegebenen Array vorhanden ist, wird zurückgegeben -1.
Sehen wir uns nun den Algorithmus der linearen Suche an.
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Algorithmus
Linear_Search(a, n, val) // 'a' is the given array, 'n' is the size of given array, 'val' is the value to search Step 1: set pos = -1 Step 2: set i = 1 Step 3: repeat step 4 while i <= 1 6 n step 4: if a[i]="=" val set pos="i" print go to [end of if] i="i" + loop] 5: 'value is not present in the array ' 6: exit < pre> <h2>Working of Linear search</h2> <p>Now, let's see the working of the linear search Algorithm.</p> <p>To understand the working of linear search algorithm, let's take an unsorted array. It will be easy to understand the working of linear search with an example.</p> <p>Let the elements of array are -</p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm.webp" alt="Linear Search Algorithm"> <p>Let the element to be searched is <strong>K = 41</strong> </p> <p>Now, start from the first element and compare <strong>K</strong> with each element of the array.</p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-2.webp" alt="Linear Search Algorithm"> <p>The value of <strong>K,</strong> i.e., <strong>41,</strong> is not matched with the first element of the array. So, move to the next element. And follow the same process until the respective element is found.</p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-3.webp" alt="Linear Search Algorithm"> <p>Now, the element to be searched is found. So algorithm will return the index of the element matched.</p> <h2>Linear Search complexity</h2> <p>Now, let's see the time complexity of linear search in the best case, average case, and worst case. We will also see the space complexity of linear search.</p> <h3>1. Time Complexity</h3> <table class="table"> <tr> <th>Case</th> <th>Time Complexity</th> </tr> <tr> <td> <strong>Best Case</strong> </td> <td>O(1)</td> </tr> <tr> <td> <strong>Average Case</strong> </td> <td>O(n)</td> </tr> <tr> <td> <strong>Worst Case</strong> </td> <td>O(n)</td> </tr> </table> <ul> <tr><td>Best Case Complexity -</td> In Linear search, best case occurs when the element we are finding is at the first position of the array. The best-case time complexity of linear search is <strong>O(1).</strong> </tr><tr><td>Average Case Complexity -</td> The average case time complexity of linear search is <strong>O(n).</strong> </tr><tr><td>Worst Case Complexity -</td> In Linear search, the worst case occurs when the element we are looking is present at the end of the array. The worst-case in linear search could be when the target element is not present in the given array, and we have to traverse the entire array. The worst-case time complexity of linear search is <strong>O(n).</strong> </tr></ul> <p>The time complexity of linear search is <strong>O(n)</strong> because every element in the array is compared only once.</p> <h3>2. Space Complexity</h3> <table class="table"> <tr> <td> <strong>Space Complexity</strong> </td> <td>O(1)</td> </tr> </table> <ul> <li>The space complexity of linear search is O(1).</li> </ul> <h2>Implementation of Linear Search</h2> <p>Now, let's see the programs of linear search in different programming languages.</p> <p> <strong>Program:</strong> Write a program to implement linear search in C language.</p> <pre> #include int linearSearch(int a[], int n, int val) { // Going through array sequencially for (int i = 0; i <n; i++) { if (a[i]="=" val) return i+1; } -1; int main() a[]="{70," 40, 30, 11, 57, 41, 25, 14, 52}; given array val="41;" value to be searched n="sizeof(a)" sizeof(a[0]); size of res="linearSearch(a," n, val); store result printf('the elements the are - '); for (int i="0;" < n; printf('%d ', a[i]); printf('
element is %d', (res="=" -1) not present in array'); else at %d position array', res); 0; pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-4.webp" alt="Linear Search Algorithm"> <p> <strong>Program:</strong> Write a program to implement linear search in C++.</p> <pre> #include using namespace std; int linearSearch(int a[], int n, int val) { // Going through array linearly for (int i = 0; i <n; i++) { if (a[i]="=" val) return i+1; } -1; int main() a[]="{69," 39, 29, 10, 56, 40, 24, 13, 51}; given array val="56;" value to be searched n="sizeof(a)" sizeof(a[0]); size of res="linearSearch(a," n, val); store result cout<<'the elements the are - '; for (int i="0;" < n; cout< <a[i]<<' cout<<'
element is '<<val; (res="=" -1) not present in array'; else at '<<res<<' position 0; pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-5.webp" alt="Linear Search Algorithm"> <p> <strong>Program:</strong> Write a program to implement linear search in C#.</p> <pre> using System; class LinearSearch { static int linearSearch(int[] a, int n, int val) { // Going through array sequencially for (int i = 0; i <n; i++) { if (a[i]="=" val) return i+1; } -1; static void main() int[] a="{56," 30, 20, 41, 67, 31, 22, 14, 52}; given array int val="14;" value to be searched n="a.Length;" size of res="linearSearch(a," n, val); store result console.write('the elements the are - '); for (int i="0;" < n; console.write(' ' + a[i]); console.writeline(); console.writeline('element is (res="=" -1) not present in array'); else console.write('element at +' position pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-6.webp" alt="Linear Search Algorithm"> <p> <strong>Program:</strong> Write a program to implement linear search in Java.</p> <pre> class LinearSearch { static int linearSearch(int a[], int n, int val) { // Going through array sequencially for (int i = 0; i <n; i++) { if (a[i]="=" val) return i+1; } -1; public static void main(string args[]) int a[]="{55," 29, 10, 40, 57, 41, 20, 24, 45}; given array val="10;" value to be searched n="a.length;" size of res="linearSearch(a," n, val); store result system.out.println(); system.out.print('the elements the are - '); for (int i="0;" < n; system.out.print(' ' + a[i]); system.out.println('element is (res="=" -1) not present in array'); else at +' position pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-7.webp" alt="Linear Search Algorithm"> <p> <strong>Program:</strong> Write a program to implement linear search in JavaScript.</p> <pre> var a = [54, 26, 9, 80, 47, 71, 10, 24, 45]; // given array var val = 71; // value to be searched var n = a.length; // size of array function linearSearch(a, n, val) { // Going through array sequencially for (var i = 0; i <n; i++) { if (a[i]="=" val) return i+1; } -1 var res="linearSearch(a," n, val); store result document.write('the elements of the array are: '); for (i="0;" i < n; document.write(' ' + a[i]); <br>' + 'Element to be searched is: ' + val); if (res == -1) document.write(' <br>' + 'Element is not present in the array'); else document.write(' <br>' + 'Element is present at ' + res +' position of array'); </n;></pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-8.webp" alt="Linear Search Algorithm"> <p> <strong>Program:</strong> Write a program to implement linear search in PHP.</p> <pre> <?php $a = array(45, 24, 8, 80, 62, 71, 10, 23, 43); // given array $val = 62; // value to be searched $n = sizeof($a); //size of array function linearSearch($a, $n, $val) { // Going through array sequencially for ($i = 0; $i < $n; $i++) { if ($a[$i] == $val) return $i+1; } return -1; } $res = linearSearch($a, $n, $val); // Store result echo 'The elements of the array are: '; for ($i = 0; $i < $n; $i++) echo ' ' , $a[$i]; echo ' <br>' , 'Element to be searched is: ' , $val; if ($res == -1) echo ' <br>' , 'Element is not present in the array'; else echo ' <br>' , 'Element is present at ' , $res , ' position of array'; ?> </pre> <p> <strong>Output</strong> </p> <img src="//techcodeview.com/img/ds-tutorial/52/linear-search-algorithm-9.webp" alt="Linear Search Algorithm"> <p>So, that's all about the article. Hope the article will be helpful and informative to you.</p> <hr></n;></pre></n;></pre></n;></pre></n;></pre></=> Ausgabe
Programm: Schreiben Sie ein Programm zur Implementierung der linearen Suche in PHP.
<?php $a = array(45, 24, 8, 80, 62, 71, 10, 23, 43); // given array $val = 62; // value to be searched $n = sizeof($a); //size of array function linearSearch($a, $n, $val) { // Going through array sequencially for ($i = 0; $i < $n; $i++) { if ($a[$i] == $val) return $i+1; } return -1; } $res = linearSearch($a, $n, $val); // Store result echo \\'The elements of the array are: \\'; for ($i = 0; $i < $n; $i++) echo \\' \\' , $a[$i]; echo \\' <br>' , 'Element to be searched is: ' , $val; if ($res == -1) echo ' <br>' , 'Element is not present in the array'; else echo ' <br>' , 'Element is present at ' , $res , ' position of array'; ?> Ausgabe
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