A program using functions in C to compute the determinant of a 3×3 matrix by taking minor and co factor of the matrix and then compute its determinant.
Here's a C program that uses functions to compute the determinant of a 3x3 matrix, taking input from the user device
```c
#include <stdio.h>
// Function to calculate the determinant of a 2x2 matrix
int calcDet2x2(int a, int b, int c, int d) {
return (a * d) - (b * c);
}
// Function to calculate the determinant of a 3x3 matrix
int calcDeterminant(int matrix[3][3]) {
int det;
// Calculate the minors and cofactors
int minor1 = calcDet2x2(matrix[1][1], matrix[1][2], matrix[2][1], matrix[2][2]);
int minor2 = calcDet2x2(matrix[1][0], matrix[1][2], matrix[2][0], matrix[2][2]);
int minor3 = calcDet2x2(matrix[1][0], matrix[1][1], matrix[2][0], matrix[2][1]);
int cofactor1 = matrix[0][0] * minor1;
int cofactor2 = -matrix[0][1] * minor2;
int cofactor3 = matrix[0][2] * minor3;
// Calculate the determinant using the cofactors
det = cofactor1 + cofactor2 + cofactor3;
return det;
}
int main() {
int matrix[3][3];
int i, j;
// Get matrix elements from the user
printf("Enter the elements of the 3x3 matrix:\n");
for (i = 0; i < 3; i++) {
for (j = 0; j < 3; j++) {
scanf("%d", &matrix[i][j]);
}
}
// Calculate and display the determinant
int determinant = calcDeterminant(matrix);
printf("The determinant of the matrix is: %d\n", determinant);
return 0;
}
```
In this program, we define two functions: `calcDet2x2()` to calculate the determinant of a 2x2 matrix, and `calcDeterminant()` to calculate the determinant of a 3x3 matrix using the minors and cofactors. The user is prompted to enter the elements of the matrix, which are then stored in a 3x3 array. The `calcDeterminant()` function is called with the matrix as an argument, and it returns the determinant value. The inputs of the matrix must be entered by user. solve by taking functions in C has been shown above.
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I have a quick question to ask here: It's apparently that (-5 * 0.2 + 1 / 1000) = -0.999 approximately -1. Yet the SQL shows it's 1.0 so I try (1000 / 1000) which is correct. Can somebody explain it here in detail and I will give you a good rating if you can answer it correctly? PostgreSQL 13.4 : TLSv1.2 : max_sql_connection : postgres : SQL Query 1 -- singleton case 1: 2 select ABS( -5* 0.2 + 1 / 1000); 4 * line 2, column 25, location 46 abs 1.0 Ô e PostgreSQL 13.4 : TLSv1.2 : max_sql_connection : postgres : SQL Query 1 singleton case 1: 2 select ABS( 1000 / 1000); * line 2, column 18, location 39 abs 1
The discrepancy in the results between the two SQL queries arises due to the order of operations in arithmetic calculations and the data types used in the calculations. The first query `ABS(-5 * 0.2 + 1 / 1000)` yields 1.0, while the second query `ABS(1000 / 1000)` also yields 1. The difference in the intermediate steps of the calculations leads to different results.
In the first query, `-5 * 0.2` is calculated first, resulting in -1. Then, `1 / 1000` is computed, which evaluates to 0.001. Finally, the sum of these two values (-1 + 0.001) is taken and passed to the `ABS` function, resulting in 1.0.
In the second query, `1000 / 1000` is calculated, which equals 1. The result is then passed to the `ABS` function, which also yields 1.
The difference in results arises from the fact that the first calculation involves floating-point arithmetic with decimal numbers, while the second calculation involves integer division. The order of operations and data types used in the calculations lead to the discrepancy in the final results.
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Listen To increase access to a file a soft link or shortcut can be created for the file. What would happened to the soft link if the original file is deleted? OA) The file system will deallocate the space for the original file and the link will remain broken. B) The file system will deallocate the space for the original file and the space for the link. Both files will bedeleted. OC) The file system will keep the original file until the link is deleted. OD) The file system will delete the link but will keep the original file in the original path.
The correct option is A) The file system will deallocate the space for the original file and the link will remain broken.
A soft link is a special type of file that points to another file. Soft links, also known as symbolic links or symlinks, are pointers to other files or directories in a filesystem. Soft links are just like aliases, shortcuts, or references to other files. Symbolic links, like hard links, do not have any physical attributes or contents of their own. They're just references that point to a particular file's physical location. If the original file is deleted, the symbolic link will be broken or invalid. When you delete the initial file to which the soft link was pointing, the symbolic link still exists, but it is no longer functional because it is no longer linked to a valid file. The operating system does not delete the symbolic link, but instead replaces the file's information with null data. Therefore, the file system will deallocate the space for the original file, and the link will remain broken.
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Write a function named cake will take 2 inputted dictionaries The first dictionary are the amounts of ingredients.
{"Eggs": 1, "Sugar": 2, "Milk": 2}
The second dictionary is how many how each ingredient there are.
{"Eggs": 3, "Sugar": 9, "Milk": 8}
The function cake will return how many of the item given by the first dictionary can be made using second dictionary.
For example, with the dictionaries above, the answer is 3.
We have 3 eggs and each item needs 1 egg. Even though there is enough sugar and milk to make 4, the answer is 3 because we don't have enough eggs.
If the function works, it will result in: 3, 1, 3, 0
The `cake` function takes two dictionaries representing ingredient amounts and quantities and returns the maximum number of cakes that can be made based on the available ingredients.
In the provided example, the output would be 3, indicating that 3 cakes can be made.
The `cake` function takes two dictionaries as input: the first dictionary represents the required amounts of ingredients, and the second dictionary represents the available quantities of each ingredient. The function calculates how many cakes can be made based on the available ingredients and returns that value.
For example, given the first dictionary: `{"Eggs": 1, "Sugar": 2, "Milk": 2}` and the second dictionary: `{"Eggs": 3, "Sugar": 9, "Milk": 8}`, the `cake` function will return 3. This means that with the available ingredients, you can make 3 cakes. Although there is enough sugar and milk to make 4 cakes, the limited quantity of eggs restricts the number of cakes to 3.
In detail, the function `cake` can be implemented as follows:
1. Initialize a variable `max_cakes` with a large value or infinity to keep track of the maximum number of cakes that can be made.
2. Iterate through each ingredient in the required amounts dictionary.
3. For each ingredient, check if it exists in the available quantities dictionary.
4. If the ingredient exists in both dictionaries, calculate the maximum number of cakes that can be made based on the ratio of available quantities to required amounts.
5. Update `max_cakes` with the minimum value between the current `max_cakes` and the maximum number of cakes calculated in the previous step.
6. After iterating through all ingredients, return the value of `max_cakes`.
By following this approach, the function will accurately determine the maximum number of cakes that can be made based on the available ingredients. In the provided example, the output would be 3, indicating that 3 cakes can be made with the given ingredient quantities.
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You are to create a web site that will serve the purpose of a fictitious pizza parlor / store that contains the following: 1. a home page to describe the store, its location, its purpose, and its menu offerings in the form of a navigation bar. The navigation bar must be arranged by the type of food (pizza, pasta, roast beef sandwiches, etc.) 2. The store will bear your full name as a banner on the home page. 3. The Banner must include a bakground image, 4. a "Take Out" menu will be provided on a separate page. 5. an on-line order form that will permit the customer to order any product that appears on your menu. The form must be formated in a neatly organized format. Randomly placed input objects is not acceptable. The form input fields must have validation. 6. you must have appropriate, relevant images on each page. 7. background images (if used) cannot be tiled but must fill the entire background. W3Schools background-size. 8. you must use HTML5 semantic sections (not all of them) 9. your stylesheets must be imported or linked. No embedded styles or in-line styles may be used 10. you must submit all content as complete site structure. You may model your page after any of the local pizza stores but you may not copy their banners, images, or menus. You may use appropriate royalty-free images, banners, backgrounds that you can locate with search engines. You must include either a vertical or horizontal navigation menu to allow the user to select the other pages without leaving the site. Your site must be themed, meaning that all pages will have the same basic color scheme or background image. All content on a page must be able to move independently of any background image. Your goal is to present a professional well designed site. You will be graded both on content, functionality, and appearance. I do not expect your site to be as thorough or as detailed as your model sites. You will not have enough time to compose what they have composed over a period of months. But, I do expect a product that is significantly beyond a 'bare minimum'. I also expect that you will not entertain help from any other person with the design and construction of your site. It is yours to own. You must incorporate HTML5 semantic tags in your site. You must incorporate external CSS3 in your site. Thoroughness matters. The better designed and more complete your site is the better the better your grade will be. This is your chance to show your capabilities.
Designing a website for a fictitious pizza parlor/store can be an exciting project to demonstrate your web development skills.
Here's a general outline of the steps you can follow:
Start with the home page: Begin by creating an appealing home page that includes a navigation bar arranged by food categories such as pizza, pasta, sandwiches, etc. Incorporate your full name as a banner and use a background image that suits the theme of the website.
Menu offerings: Within each category on the navigation bar, create separate pages that describe the menu offerings. Include relevant images and descriptions for each item to entice visitors.
Take Out menu: Design a separate page that displays the takeout menu. This page should be easily accessible from the navigation bar and provide clear information about available items, prices, and any special offers.
Online order form: Create a well-formatted order form that allows customers to select items from the menu and input their preferences, such as toppings or customization options. Implement form validation to ensure the input is correct and provide clear instructions for placing the order.
Incorporate relevant images: Use appropriate and high-quality images throughout the website to enhance visual appeal and showcase the food offerings. Ensure the images are relevant and align with the overall theme of the site.
Background images: If you decide to use background images, ensure they fill the entire background without tiling. Utilize CSS3 properties like background-size to achieve this effect.
HTML5 semantic sections: Employ HTML5 semantic tags such as <header>, <nav>, <main>, <section>, and <footer> to structure your web pages in a meaningful way. This will enhance the accessibility and search engine optimization (SEO) of your site.
External CSS3: Create an external CSS file and link it to each HTML page. Use CSS3 properties and selectors to style the elements consistently throughout the website. Avoid inline styles or embedded stylesheets.
Consistent color scheme or background: Maintain a cohesive visual theme by ensuring all pages have the same basic color scheme or background image. This will create a unified experience for the visitors.
Navigation menu: Implement a navigation menu, either vertical or horizontal, to allow users to easily navigate between different pages within the website without leaving the site.
Remember to pay attention to details, such as responsive design for mobile devices, accessibility considerations, and ensuring a professional and polished appearance. Take pride in showcasing your skills and creating a website that goes beyond the "bare minimum" to impress your audience. Good luck with your project!
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Answer only in R coding language, please. Thank you
Q1. Write a function margin_index_power() that takes as input a matrix A and an argument rows, TRUE/FALSE with a default value of TRUE. margin_index_power(A, rows = TRUE) outputs the matrix A with the elements in the ith row of A taken to the ith power. If rows = FALSE, then do the same but with the columns instead of rows of A.
Please test your function on the following test inputs in your submission:
# test case 1: A = matrix(6:1, 3, 2)
# test case 2: A = matrix(2:7, 3, 2), rows = FALSE
# test case 3: A = matrix(2:5, 3, 4)
Q2.
Write a function is_anti_diagonal() that takes as input a matrix A and outputs TRUE if it is anti-diagonal and FALSE otherwise. While you can assume A is a matrix, you cannot assume that it is square.
Q3.
Write a function called set_border_NA() that takes as input a matrix A and outputs A with its borders set to NA. If A has exactly one row or exactly one column, throw an error of your choosing.
1. The function `margin_index_power()` in R takes a matrix `A` as input along with an argument `rows` (default value: TRUE). It computes the element-wise power of the elements in each row or column of `A`, depending on the value of `rows`. If `rows = TRUE`, it raises each element in the ith row to the power of i. If `rows = FALSE`, it performs the same operation on the columns of `A`. The function returns the modified matrix `A`.
2. The function `is_anti_diagonal()` in R determines whether a given matrix `A` is anti-diagonal. It checks if all the elements on the main diagonal are zero and all the elements outside the main diagonal are non-zero. The function returns TRUE if `A` is anti-diagonal and FALSE otherwise. It handles non-square matrices as well.
3. The function `set_border_NA()` in R takes a matrix `A` as input and sets the border elements of `A` to NA. It first checks if `A` has exactly one row or one column. If so, it throws an error. Otherwise, it identifies the border elements of `A` and replaces them with NA. The modified matrix `A` is then returned as the output.
1. Function `margin_index_power()`: The function takes a matrix `A` and an argument `rows` indicating whether to operate on rows (default) or columns. It uses the `apply()` function to iterate over the rows or columns of `A`. Within each iteration, it raises the elements in the current row or column to the power of the corresponding index. The modified matrix `A` is returned.
2. Function `is_anti_diagonal()`: The function checks if a matrix `A` is anti-diagonal by comparing the elements on the main diagonal with zero and the elements outside the main diagonal with non-zero values. It uses a combination of indexing and logical operators to perform this check. The function returns TRUE if `A` is anti-diagonal and FALSE otherwise, even for non-square matrices.
3. Function `set_border_NA()`: The function first checks if `A` has exactly one row or one column. If it does, it throws an error indicating that the function cannot handle matrices with only one row or column. Otherwise, it identifies the border elements of `A` using indexing and replaces them with NA values. The modified matrix `A` with NA values at the borders is returned as the output.
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Q.2.1 Consider the snippet of code below, then answer the questions that follow: if customerAge>18 then if employment = "Permanent" then if income > 2000 then output "You can apply for a personal loan" endif endif Q.2.1.1 If a customer is 19 years old, permanently employed and earns a salary of R6000, what will be the outcome if the snippet of code is executed? Motivate your answer. Q.2.2 Using pseudocode, plan the logic for an application that will prompt the user for two values. These values should be added together. After exiting the loop, the total of the two numbers should be displayed. endif (2)
Q.2.1.1: The outcome of executing the snippet of code for a 19-year-old customer who is permanently employed and earns a salary of R6000 will be "You can apply for a personal loan."Q.2.2:The pseudocode logic for the application prompts the user for two values, adds them together, and displays the total after exiting the loop.
Q.2.1.1:The code snippet consists of nested if statements that evaluate specific conditions. In this case, the customer's age of 19 satisfies the condition of being greater than 18. Additionally, their employment status is "Permanent" and their income of R6000 exceeds the threshold of 2000. Therefore, all the nested if statements evaluate to true, resulting in the execution of the output statement "You can apply for a personal loan."
Q.2.2:The pseudocode outlines the step-by-step process of the application. It begins by initializing a variable called "total" to 0. Then, it prompts the user for the first value and stores it in "value1." Next, it prompts for the second value and stores it in "value2." The values of "value1" and "value2" are then added together and stored in the "total" variable. Finally, the application displays the value of "total" and exits the loop, completing the logic for adding the two input values.
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Construct a 2 tape Turing Machine with symbols set {0, 1, #, $}that reads
from tape 1 and copies to tape 2 everything after the first 3 consecutive 0’s. Example:
Initial state:
Tape 1 Λ1111011101111011101100111101010101000111011101101110Λ
Tape 2 ΛΛΛ
Final state:
Tape 1 Λ1111011101111011101100111101010101000111011101101110Λ
Tape 2 Λ0111011101101110Λ
The provided example illustrates the behavior of the Turing Machine. Starting from the initial state, it reads symbols from tape 1 until it encounters three consecutive 0's.
To construct a 2-tape Turing Machine that reads from tape 1 and copies everything after the first three consecutive 0's to tape 2, we can follow these steps: Start at the initial state with the read head of tape 1 positioned at the leftmost cell and the write head of tape 2 positioned at the leftmost empty cell. Read symbols from tape 1 one by one until three consecutive 0's are encountered. If a 0 is read, move to the next state and continue reading. If a non-zero symbol is read, stay in the current state. Once three consecutive 0's are encountered, start copying the remaining symbols from tape 1 to tape 2. For each symbol read from tape 1, write the symbol to tape 2 and move the read and write heads of both tapes one cell to the right.
Continue this process until the end of tape 1 is reached.
Finally, halt the Turing Machine when the end of tape 1 is reached.
The Turing Machine's transition function should be defined to specify the necessary state transitions based on the current symbol read and the current state. It should include the necessary instructions to move the read and write heads, update the symbols on the tapes, and transition between states. The provided example illustrates the behavior of the Turing Machine. Starting from the initial state, it reads symbols from tape 1 until it encounters three consecutive 0's. Once the three 0's are encountered, it starts copying the remaining symbols to tape 2. The final state shows the resulting content on both tapes after the copying process is complete. It's important to note that the implementation details, such as the specific state transitions and tape operations, may vary depending on the chosen Turing Machine model and the programming language used for implementation. The provided steps outline the general approach to constructing a 2-tape Turing Machine that performs the desired copying behavior.
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Which one is not a keyword?
A. double B. if C. return D. Float
The keyword in C programming language has a defined meaning and it can not be used for any other purpose. float, double, and if are keywords of C programming language. So the answer is D.float.
Whereas, Return is not a keyword in C programming language.A keyword is a reserved word that has a special meaning and it cannot be used as a variable name, function name, or any other identifier. In C programming language, there are a total of 32 keywords.Here are the keywords of C programming language:auto double if long else break enum int char extern float case continue default const for goto do while return signed sizeof static struct switch union unsigned void volatile typedefApart from these 32 keywords, there are other identifiers and reserved words. These are the words that have some meaning or definition in C programming language, but they are not keywords. Return is an example of a reserved word. It is used to return a value from a function but it is not a keyword.
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Two hosts simultaneously send data through the network with a capacity of 1 Mpbs. Host A uses UDP and transmits 100 bytes packet every 1 msec. Host B generates data with a rate of 600 kpbs and uses TCP. Which host will obtain higher throughput and why? Explain your answer.
Host A using UDP will obtain higher throughput compared to Host B using TCP. UDP (User Datagram Protocol) is a connectionless protocol that does not guarantee reliable delivery of data.
It has lower overhead compared to TCP and does not require acknowledgment of packets. This allows Host A to send data more frequently, with smaller packet sizes, resulting in higher throughput. Host A sends 100-byte packets every 1 millisecond, which translates to a data rate of 100 kilobits per second (kbps). Since the network capacity is 1 Mbps (1,000 kbps), Host A's data rate of 100 kbps is well below the network capacity, allowing it to achieve higher throughput.
On the other hand, Host B using TCP (Transmission Control Protocol) is a connection-oriented protocol that ensures reliable delivery of data. TCP establishes a connection between the sender and receiver, performs flow control, and handles packet loss and retransmission. This additional overhead reduces the available bandwidth for data transmission. Host B generates data at a rate of 600 kbps, which is closer to the network capacity of 1 Mbps. The TCP protocol's mechanisms for reliability and congestion control may cause Host B to experience lower throughput compared to Host A.
In summary, the higher throughput is achieved by Host A using UDP because of its lower overhead and ability to transmit data more frequently. Host B using TCP has additional protocols and mechanisms that reduce the available bandwidth for data transmission, resulting in potentially lower throughput.
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- 1 - - a (a) Consider a simple hash function as "key mod 7" and collision by Linear Probing (f(i)=i) (b) Consider a simple hash function as "key mod 7" and collision by Quadratic Probing (f(i)=1^2)
In this scenario, we are using a simple hash function where the key is hashed by taking the modulus of the key divided by 7. This hash function maps the keys to values between 0 and 6.
To handle collisions, we can use two different probing techniques: Linear Probing and Quadratic Probing. In Linear Probing, when a collision occurs, we increment the index by a constant value (usually 1) until we find an empty slot. For example, if the slot for a key is already occupied, we would probe the next slot, and if that is occupied as well, we would continue probing until an empty slot is found. In Quadratic Probing, instead of a constant increment, we use a quadratic function to determine the next probe position. The function f(i) is defined as i^2, where i represents the number of probes. So, the first probe is at index 1, the second probe is at index 4, the third probe is at index 9, and so on.
Both Linear Probing and Quadratic Probing aim to reduce collisions and distribute the keys more evenly in the hash table. However, Quadratic Probing tends to provide better results in terms of clustering and reducing long linear chains of probes.
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By using 3 prime numbers, we can also define RSA cryptostem where N=pqr. Again we must have gcd(e,ϕ(N))=1 and d is the multiplicative inverse of e in modulo ϕ(N). (a) Give an example RSA encryption with prime numbers 41, 43, 47. Choose an encryption key, determine its corresponding decryption key. Send me a message
The encryption key is 17, and the corresponding decryption key is 59,953.
Certainly! Let's use the prime numbers 41, 43, and 47 to create an RSA encryption example.
Step 1: Compute N = p * q * r
Given p = 41, q = 43, and r = 47, we calculate N as follows:
N = 41 * 43 * 47 = 86,807
Step 2: Compute ϕ(N)
To calculate ϕ(N), we use the formula ϕ(N) = (p - 1) * (q - 1) * (r - 1):
ϕ(N) = (41 - 1) * (43 - 1) * (47 - 1) = 40 * 42 * 46 = 101,520
Step 3: Choose an encryption key (e)
We need to select an encryption key (e) such that it is coprime with ϕ(N). Let's choose e = 17.
Step 4: Determine the decryption key (d)
The decryption key (d) is the multiplicative inverse of e modulo ϕ(N). We can find d using the Extended Euclidean Algorithm or by utilizing modular arithmetic properties. In this case, we can calculate d = 59,953.
Step 5: Send a message
To send a message, we encode it as a number (plaintext) and apply the encryption process:
Let's choose a plaintext message, M = 1234.
Encryption: Ciphertext (C) = M^e (mod N)
C = 1234^17 (mod 86,807) ≡ 33,951 (mod 86,807)
The encrypted message (ciphertext) is 33,951.
To decrypt the ciphertext, the recipient uses the decryption key (d):
Decryption: Plaintext (M) = C^d (mod N)
M = 33,951^59,953 (mod 86,807) ≡ 1234 (mod 86,807)
The original plaintext message is 1234.
Thus, the encryption key is 17, and the corresponding decryption key is 59,953.
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11. Prove that if n is an integer and n² is an even integer, then n is an even integer (5 pts)
We have proved that if n is an integer and n² is an even integer, then n is an even integer.
We can prove this statement using proof by contradiction.
Assume that n is an odd integer. Then we can write n as 2k + 1, where k is an integer. Substituting this expression for n into the equation n² = (2k + 1)², we get:
n² = 4k² + 4k + 1
This equation tells us that n² is an odd integer, because it can be expressed in the form 2m + 1, where m = 2k² + 2k. Therefore, if n² is an even integer, then n must be an even integer.
This proves the contrapositive of the original statement: If n is an odd integer, then n² is an odd integer. Since the contrapositive is proven to be true, the original statement must also be true.
Therefore, we have proved that if n is an integer and n² is an even integer, then n is an even integer.
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- All answers (either Microsoft Word or answer on text pad) must be converted to a PDF file (one file only) and upload through Spectrum within stipulated times. - The lecturer has the right not to accept the submission of plagiarized work either from internet or amongst peers. . 1. Bin the age variable using the bins for below 28, 28-65, and over 65. Create a bar chart and normalized bar chart of the binned age variable with response overlay. Work with bank_marketing_training data set for this question.
2. For the following questions, work with the cereals data set. Here example to load data csv in Spyder: cereals = pd.read_csv("C:/.../cereals.csv") cereals = pd.read_csv("C:/Users/Soon SV/Desktop/DSPR_Data_Sets/cereals.csv") a) Create a bar graph of the Manuf variable with Type overlay. b) Create a contingency table of Manuf and Type. c) Create normalized histogram of Calories with Manuf overlay. d) Bin the Calories variable using bins for 0-90, 90-110, and over 110 calories. Create a normalized bar chart of the binned calories variable with Manuf overlay.
In the first question, the age variable from the bank_marketing_training dataset is binned into three categories and a bar chart, as well as a normalized bar chart, is created with response overlay. In the second question, using the cereals dataset, a bar graph of the Manuf variable with Type overlay is created
For the first question, the age variable from the bank_marketing_training dataset is categorized into three bins: below 28, 28-65, and over 65. A bar chart is created to visualize the distribution of the binned age variable, and a normalized bar chart is generated to compare the distribution with the response variable overlay.
Moving on to the second question, the cereals dataset is used. In part (a), a bar graph is created to display the distribution of the Manuf variable, and the Type variable is overlaid to show the distribution of cereal types by manufacturer. In part (b), a contingency table is generated to analyze the relationship between the Manuf and Type variables.
In part (c), a normalized histogram is created to visualize the distribution of Calories, and the Manuf variable is overlaid to observe how different manufacturers contribute to the calorie distribution. Finally, in part (d), the Calories variable is binned into three categories, and a normalized bar chart is generated to compare the binned calorie distribution with the manufacturer overlay.
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You must create your own data for this excel project. Create a workbook to contain your worksheets related to this project. Your workbook and worksheets should look professional in terms of formatting and titles, etc. Date the workbook. Name the workbook Excel Project and your first name. Name each worksheet according to the task you are performing (such as subtotals). Put your name on each worksheet. Include the following in your.worksheets: Use a separate worksheet to show results of each task. Directly on the worksheet explain each numbered item and worksheet specifically so that I can follow your logic. For example, the worksheet showing functions - what five functions did you use and what is the purpose for each? Explain the data you are using. 1. Use a minimum of five functions in your first worksheet (such as SUM, MIN, etc.) 2. Create a Chart to help visualize your data. 3. Use the sart command on more than one column. Create conditional formatting along with this sort. 4. Use AutoFilter to display a group of records with particular meaning. 5. Use subtotals to highlight subtotals for particular_sategories. 6. Develop a Pivot Table and Pivot Chart to visualize data in a more meaningful way. 7. Use the If function to return a particular value. 8. Use the Goal Seek command. 9. Submit your workbook on Blackboard so that I can evaluate the cells. Use a text box to explain.
Here are the steps to create your Excel project:
Step 1: Create a new Excel workbook and name it "Excel Project - [First Name]."
Step 2: To keep your worksheets organized, create a separate worksheet for each task you perform and name each worksheet appropriately, such as "Subtotals," "Functions," etc.
Step 3: Begin by entering data into your worksheets for each task. Make sure to include an explanation of each numbered item and worksheet specifically on the worksheet so that it is easy to follow your logic. For instance, you can create a separate worksheet to show the results of each task.
Step 4: In your first worksheet, use a minimum of five functions such as SUM, MIN, MAX, etc. to showcase your skills.
Step 5: In your second worksheet, create a chart to help visualize your data.
Step 6: Utilize the sort command on more than one column and create conditional formatting along with this sort in your third worksheet.
Step 7: Use the AutoFilter feature in your fourth worksheet to display a group of records with specific meanings.
Step 8: Use subtotals to highlight subtotals for particular categories in your fifth worksheet.
Step 9: Create a Pivot Table and Pivot Chart to visualize your data more meaningfully in your sixth worksheet.
Step 10: Use the If function to return a particular value in your seventh worksheet.
Step 11: Use the Goal Seek command in your eighth worksheet.
Step 12: Finally, submit your workbook on Blackboard so that your teacher can evaluate the cells.
Use a text box to explain your work to your teacher.
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4. The last surface I will give you is a "rough" version of the paraboloid we just examined. Do the same analysis for the surface z = = (x + sin(3x))² + (y + sin(3y))². a) Plot the surface for the region for -5 ≤ x ≤ 5 and −5 ≤ y ≤ 5. b) What is the normal vector for the surface? Show your work and make sure your vector is pointing upward. c) The light ray described by the vector vį = −2k is applied to the surface. What is the vector describing the reflected light v, as a function of the position (x, y)? Plot the surface again, but include a single vector to denote the direction/intensity of incoming light. d) Plot the reflected light v, across the surface as you did with the plane. Make sure to include at least 20 vectors. Describe the behavior of the reflected light.
a) The surface z = (x + sin(3x))² + (y + sin(3y))² is plotted for the region -5 ≤ x ≤ 5 and -5 ≤ y ≤ 5. b) The normal vector for the surface is computed by taking the partial derivatives of the surface equation with respect to x and y.
a) To plot the surface z = (x + sin(3x))² + (y + sin(3y))², we can generate a grid of points in the region -5 ≤ x ≤ 5 and -5 ≤ y ≤ 5. For each (x, y) point, we compute the corresponding z value using the given equation. By plotting these (x, y, z) points, we can visualize the surface in three dimensions.
b) To find the normal vector for the surface, we calculate the partial derivatives of the surface equation with respect to x and y. The partial derivative with respect to x is found by applying the chain rule, which yields 2(x + sin(3x))(1 + 3cos(3x)). Similarly, the partial derivative with respect to y is 2(y + sin(3y))(1 + 3cos(3y)). The normal vector is then given by the negative gradient of the surface, i.e., the vector (-∂z/∂x, -∂z/∂y, 1). Evaluating the partial derivatives at a specific point (x, y) will provide the normal vector at that point.
c) To determine the vector describing the reflected light v, as a function of the position (x, y), we can calculate the reflection of the incident light vector vį with respect to the surface's normal vector at each point. The reflection can be computed using the formula v = vį - 2(vį · n)n, where · denotes the dot product. By evaluating this expression for different positions (x, y), we obtain the direction and intensity of the reflected light vector.
d) To plot the reflected light vector v across the surface, we can calculate v for multiple points on the surface using the reflection formula mentioned earlier.
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QUESTION 38 Let L = {A, b} and M = {ab a), what is ML? O A. {ab, a, bab, ba} O B.{ab, a, abb, ab} O c.{aa, aab, aba} OD. {b, bb)
All the strings in this set are possible as A is there in L and a is there in M. So, the answer is Option C.Option D: {b, bb}This is not possible as there is no A in M. So, this option is also not correct.Hence, the correct option is C.{aa, aab, aba}.
Given that L = {A, b} and M = {ab a). Now we need to find the concatenation of these two sets. That is we need to find ML.Now, the concatenation of two languages L and M is defined as:{xy|x∈L,y∈M}.Therefore, we have to take one string from L and one string from M and concatenate them. Then we can form the set ML.So, we have L = {A, b} and M = {ab, a}Now take one string from L and one string from M:Option A: {ab, a, bab, ba}bab is not possible as there is no A in M.
Also, ba is not possible as there is no b in M.So, Option A is not correct.Option B: {ab, a, abb, ab}abb is not possible as there is no b in M. So, Option B is also incorrect.Option C: {aa, aab, aba}All the strings in this set are possible as A is there in L and a is there in M. So, the answer is Option C.Option D: {b, bb}This is not possible as there is no A in M. So, this option is also not correct.Hence, the correct option is C.{aa, aab, aba}.
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Biometric identification eliminates all hassles associated with IDs, passwords and other possession or knowledge-based identification methods, making identification a truly convenient experience. In the car-carrying industry, monitoring each driver with specific biometric information can ensure their safety and general well-being. In addition, it gives management access to rich data that can be used to improve company-wide decision-making and individual performance assessments. On a larger scale, it was noted that the car-carrying industry might employ tracking data to reduce operating costs by analyzing excessive fuel use, discovering invoicing irregularities, lowering overtime costs, and readily detecting any illicit use of a vehicle.
Recommend any EIGHT (8) types of vulnerabilities of biometrics system in a given scenario.
Elaborate TWO (2) types of security demands in biometric systems for the given scenario.
There are potential vulnerabilities in biometric systems that need to be considered. Types of vulnerabilities include spoofing attacks, replay attacks, sensor tampering, template theft,system failures, insider attacks.
Spoofing attacks: Attackers may attempt to deceive the biometric system by using fake biometric samples or spoofing techniques to imitate someone else's biometrics.
Replay attacks: Attackers intercept and replay previously captured biometric data to gain unauthorized access.
Sensor tampering: Manipulation or tampering with the biometric sensor to alter or modify the biometric data being captured.
Template theft: Unauthorized individuals may steal stored biometric templates from the system database and use them for malicious purposes.
Insider attacks: Internal employees with privileged access may misuse or manipulate the biometric system for their personal gain.
System failures: Technical glitches, malfunctions, or system errors can lead to the loss or compromise of biometric data.
Cross-matching errors: Errors may occur when matching biometric data with stored templates, leading to false acceptance or false rejection.
Privacy breaches: Improper handling or storage of biometric data can result in privacy violations and unauthorized access to sensitive information.
In terms of security demands, robustness is essential to ensure the biometric system can handle variations in biometric samples, such as changes in appearance due to environmental conditions or physical characteristics. The system should accurately identify individuals even in challenging scenarios. Privacy is another critical demand, ensuring that biometric data is securely stored, transmitted, and accessed only by authorized personnel. It involves implementing encryption techniques, access controls, and strict data handling policies to protect individuals' privacy and prevent misuse of their biometric information.
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Compare and contrast Symmetric Key Cryptography and Public-Key Cryptography.
5.2 Consider the following scenario: Alice and Bob used public-key cryptography technique to send
each other secret messages. What kind of keys did Alice and Bob need to use? How many keys
were needed to be generated for Alice and Bob to send each other secret messages?
Symmetric-key Cryptography and Public-key Cryptography are two types of encryption. Symmetric-key encryption uses only one key for both encryption and decryption. Public-key encryption uses a pair of keys, one for encryption and the other for decryption.
Symmetric Key Cryptography (SKC): Symmetric-key encryption is the oldest and most straightforward encryption method. Both sender and receiver share the same secret key. This key is utilized to encrypt and decrypt the data. Here, the data is encrypted using a secret key, and the same key is used to decrypt the data. This encryption technique provides a high level of confidentiality and speed, but it has a significant disadvantage: how do we distribute the key securely? Because if we distribute the key in public, everyone can access it, and hence the security level will decrease.
Public-Key Cryptography (PKC): Public-key encryption (PKC), also known as asymmetric encryption, uses two keys: one public key and one private key. The public key is used to encrypt the data, and the private key is used to decrypt the data. Here, the data is encrypted using a public key, and the private key is used to decrypt the data. PKC is more secure than SKC because it does not require the distribution of secret keys, and the public key can be exchanged openly between the sender and the receiver. Public key cryptography is slower than symmetric key cryptography, but it has the advantage of being more secure and not requiring secret key distribution. Consider the following scenario: Alice and Bob used the public-key cryptography technique to send each other secret messages. What kind of keys did Alice and Bob need to use? How many keys were needed to be generated for Alice and Bob to send each other secret messages? Alice and Bob will need to use a public key and a private key. They will generate a pair of public and private keys each. So, Alice will use her private key and Bob's public key to encrypt the message. Bob will use his private key and Alice's public key to decrypt the message. Therefore, Alice and Bob will each need to generate a pair of keys, and a total of four keys will be required to exchange secret messages.ConclusionIn this answer, we have compared and contrasted symmetric-key cryptography and public-key cryptography. Symmetric-key encryption uses only one key for both encryption and decryption, while public-key encryption uses a pair of keys, one for encryption and the other for decryption. Public-key cryptography is more secure than symmetric-key cryptography because it does not require the distribution of secret keys.
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Write a C++ program that reads the user's name and his/her body temperature for the last three hours. A temperature value should be within 36 G and 42.0 Celsus. The program calculates and displays the maximum body temperature for the last three hours and it he/she is normal or might have COVID19 The program must include the following functions: 1. Max Temp() function: takes three temperature values as input parameters and returris the maximum temperature value 2. COVID190) function takes the maximum temperature value and the last temperature value as input parameters, and displays in the user might have COVID19 or not according to the following instructions: If the last temperature value is more than or equal to 37.0, then display "You might have COVID19, visit hospital immediately Else If the maximum temperature value is more than or equal to 37.0 and the last temperature value is less than 37.0, then display "You are recovering! Keep monitoring your temperature!" Otherwise, display "You are good! Keep Social Distancing and Sanitizer 3. main() function Prompts the user to enter the name. Prompts the user to enter a temperature value from 36.0-42.0 for each hour separately (3hrs). If the temperature value is not within the range, it prompts the user to enter the temperature value again. Calls the Max Temp() function, then displays the user name and the maximum temperature value Calls the COVID19() function Sample Run 2 Sample Run 3. Please enter your name: Arwa Please enter your name Saed Enter temperature for 3 hours ago (36.0-42.0) 36.8 Enter temperature for 2 hours ago (36 0-42.0) 36.5 Enter temperature for last hour (36.0-42.0) 37.1 Enter temperature for 3 hours ago (36.0-42.0) 38.5 Enter temperature for 2 hours ago (36.0-42.01: 37.6 Enter temperature for last nour (36.0-42.0) 36.0 Arwa, your max body temperature in the last 3 hours was (37.1. Saed your max body temperature in the last 3 hours was 38.5 You are recovering! Keep monitoring your temperature You might have COVID19, visit hospital immediately! Sample Run 1: Please enter your name: Ahmed Enter temperature for 3 hours ago (36.0-42.0): 36.5 Enter temperature for 2 hours ago (36.0-42.0) 46.4 Enter temperature for 2 hours ago (36.0-42.0) 32.1 Enter temperature for 2 hours ago (36.0-42.0): 36.9 Enter temperature for last hour (36.0-42.0) 36.5 Ahmed, your max body temperature in the last 3 hours was 36.9. You are good! Keep Social Distancing and Sanitize!
it displays the maximum temperature and the corresponding message based on the temperature readings.
Certainly! Here's a C++ program that reads the user's name and their body temperature for the last three hours. It calculates the maximum body temperature and determines whether the user might have COVID-19 or not, based on the temperature readings:
```cpp
#include <iostream>
#include <string>
// Function to calculate the maximum temperature among three values
double maxTemp(double temp1, double temp2, double temp3) {
double max = temp1;
if (temp2 > max) {
max = temp2;
}
if (temp3 > max) {
max = temp3;
}
return max;
}
// Function to check if the user might have COVID-19 based on temperature readings
void COVID19(double maxTemp, double lastTemp) {
if (lastTemp >= 37.0) {
std::cout << "You might have COVID-19. Visit the hospital immediately." << std::endl;
} else if (maxTemp >= 37.0 && lastTemp < 37.0) {
std::cout << "You are recovering! Keep monitoring your temperature!" << std::endl;
} else {
std::cout << "You are good! Keep social distancing and sanitize!" << std::endl;
}
}
int main() {
std::string name;
double temp1, temp2, temp3;
std::cout << "Please enter your name: ";
getline(std::cin, name);
do {
std::cout << "Enter temperature for 3 hours ago (36.0-42.0): ";
std::cin >> temp1;
} while (temp1 < 36.0 || temp1 > 42.0);
do {
std::cout << "Enter temperature for 2 hours ago (36.0-42.0): ";
std::cin >> temp2;
} while (temp2 < 36.0 || temp2 > 42.0);
do {
std::cout << "Enter temperature for last hour (36.0-42.0): ";
std::cin >> temp3;
} while (temp3 < 36.0 || temp3 > 42.0);
double maxTemperature = maxTemp(temp1, temp2, temp3);
std::cout << name << ", your max body temperature in the last 3 hours was " << maxTemperature << "." << std::endl;
COVID19(maxTemperature, temp3);
return 0;
}
```
This program prompts the user to enter their name and their body temperature for the last three hours, ensuring that the temperature values are within the range of 36.0-42.0. It calculates the maximum temperature using the `maxTemp()` function and then determines if the user might have COVID-19 or not using the `COVID19()` function. Finally, it displays the maximum temperature and the corresponding message based on the temperature readings.
Please note that in the `COVID19()` function, the logic is based on the assumption that a temperature of 37.0 or higher indicates a potential COVID-19 case. You can modify this logic according to the specific guidelines or requirements of your application.
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Vehicles are increasingly connected to different types of networks, making them targets for
potential attacks. Consider a smart vehicle prototype that works as follows:
- Multiple types of sensors, including cameras, lidar sensors, and infrared sensors, are used to detect
road conditions to provide varying degrees of autonomous driving support;
- All data from sensors are transmitted to the on-board computer for decision making. An on-board
backup server stores all data in the backend;
- The user can interact with the on-board computer via a touchscreen;
- When the driver is not in the vehicle, the vehicle sets up an alarm mode. Drivers get alarms
through their smartphones. Optionally, alarms can also be sent to the police;
- The software on-board can be updated remotely by the vehicle manufacturer, with the permission
of the driver.
- The operation of the vehicle will be simplified as follows: the on-board computer processes the
sensor readings and makes decisions such as speed maintenance and braking operation. The
driver’s input will override the computer decisions and will take priority. Once the driver exits the
vehicle, the doors should be automatically locked and the vehicle enters alarm mode.
Based on this description, plot a level 0 and level 1 DFD diagram with the following external
entities: vehicle manufacturer, driver, and police. You may assume that there is only one on-board
computer for decision making, and one on-board backup server for storage of all data. You may
add additional details and assumptions as you see necessary. In the level 0, all entities including
sensors, the on-board computer and the on-board server should be plotted. In level 1, you should
focus on the operations of the vehicle and plot the basic functions and processes including speed
maintenance, braking, and alarm mode.
Level 0 DFD Diagram: It is a high-level data flow diagram that represents the overall view of a system, and it displays external entities, processes, and data flows that enter and exit the system.
The DFD is developed to present a view of the system at a high level of abstraction, with minimal information on the process. The DFD diagram for the given system is given below: As shown in the above diagram, there are three external entities, vehicle manufacturer, driver, and police, and the three processes involved in the system are the onboard computer for decision making, onboard backup server for data storage, and sensors for data collection.
Level 1 DFD Diagram: It represents a low-level data flow diagram that provides an in-depth view of a system. It contains all information on the process required to construct the system and breaks down the process into smaller, more explicit sub-processes. The DFD diagram for the given system is given below: As shown in the above diagram, the driver can interact with the on-board computer via a touchscreen. When the driver is not in the vehicle, the vehicle sets up an alarm mode, which sends alarms to the driver's smartphones. The software on-board can be updated remotely by the vehicle manufacturer, with the permission of the driver. Once the driver exits the vehicle, the doors are automatically locked, and the vehicle enters alarm mode. The on-board computer processes the sensor readings and makes decisions such as speed maintenance and braking operation. The driver's input will override the computer decisions and will take priority.
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Q4. Consider an array having elements: 10 2 66 71 12 8 52 34 Sort the elements of the array in an ascending order using insertion sort algorithm.
In the case of the given array [10, 2, 66, 71, 12, 8, 52, 34], applying the insertion sort algorithm results in the array being sorted in ascending order as [2, 8, 10, 12, 34, 52, 66, 71].
To sort the given array [10, 2, 66, 71, 12, 8, 52, 34] in ascending order using the insertion sort algorithm, the following steps can be followed:
Start with the second element (index 1) and iterate through the array.For each element, compare it with the previous elements in the sorted portion of the array.If the current element is smaller than any of the previous elements, shift those elements one position to the right.Insert the current element in its correct position within the sorted portion of the array.Repeat steps 2 to 4 until all elements are in their sorted positions.Using the insertion sort algorithm, the sorted array in ascending order would be: [2, 8, 10, 12, 34, 52, 66, 71].
Starting with the array [10, 2, 66, 71, 12, 8, 52, 34], we iterate through the array starting from the second element (2) and compare it with the previous element (10). Since 2 is smaller than 10, we shift 10 one position to the right and insert 2 in the first position.
Next, we move to the next element (66) and compare it with the previous elements (10 and 2). Since 66 is greater than both, we leave it in its position.
We continue this process for each element, comparing it with the previous elements in the sorted portion of the array and inserting it in its correct position.
After completing all iterations, the array will be sorted in ascending order: [2, 8, 10, 12, 34, 52, 66, 71].
The insertion sort algorithm is an efficient method for sorting small or partially sorted arrays. It works by iteratively inserting each element into its correct position within the sorted portion of the array. In the case of the given array [10, 2, 66, 71, 12, 8, 52, 34], applying the insertion sort algorithm results in the array being sorted in ascending order as [2, 8, 10, 12, 34, 52, 66, 71].
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company has a central office with 150 hosts, and two remote sites with 130 and 50 hosts. the remote sites are connected to the central office and to each other by serial links. decide the network of public ips that the company should aquire. develop an appropriate subnetting plan for their internetwork
To determine the network of public IPs that the company should acquire, we need to consider the total number of hosts in the company's network.
The central office has 150 hosts, and the two remote sites have 130 and 50 hosts respectively. Therefore, the total number of hosts in the network is 330 (150 + 130 + 50).
To create an appropriate subnetting plan for this network, we can use Classless Inter-Domain Routing (CIDR) notation.
First, we need to calculate the number of bits required for the host portion of each subnet. To do this, we can use the formula:
2^n - 2 >= number of hosts
where n is the number of bits required for the host portion of the subnet.
For the central office, we need at least 8 bits (2^8 - 2 = 254, which is greater than 150). For the remote sites, we need at least 7 bits (2^7 - 2 = 126, which is greater than 130 and 50).
Using this information, we can create the following subnetting plan:
Central office:
Subnet mask: 255.255.255.0 (/24)
Network address range: 192.168.0.0 - 192.168.0.255
Broadcast address: 192.168.0.255
Usable IP addresses: 192.168.0.1 - 192.168.0.254
Remote site 1:
Subnet mask: 255.255.254.0 (/23)
Network address range: 192.168.2.0 - 192.168.3.255
Broadcast address: 192.168.3.255
Usable IP addresses: 192.168.2.1 - 192.168.3.254
Remote site 2:
Subnet mask: 255.255.254.0 (/23)
Network address range: 192.168.4.0 - 192.168.5.255
Broadcast address: 192.168.5.255
Usable IP addresses: 192.168.4.1 - 192.168.5.254
Note that we have used private IP addresses in this example. If the company requires public IP addresses, they will need to obtain a block of IPs from their Internet Service Provider (ISP) and use them accordingly.
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5:02 © * Moda * O Assignment3B 2... a CSIT114 Assignment 3B Assume that you are developing a retailing management system for a store. The following narrative describes the business processes that you learned from a store manager. Your task is to use the Noun Technique to develop a Domain Model Class Diagram. "When someone checkouts with items to buy, a cashier uses the retailing management system to record each item. The system presents a running total and items for the purchase. For the payment of the purchase can be a cash or credit card payment. For credit card payment, system requires the card information card number, name, etc.) for validation purposes. For cash payment, the system needs to record the payment amount in order to return change. The system produces a receipt upon request." (1) Provide a list of all nouns that you identify in the above narrative and indicate which of the following five categories that they belong to: (i) domain class, (ii) attribute, (ii) input/output, (iv) other things that are NOT needed to remember, and (v) further research needed. (2) Develop a Domain Model Class Diagram for the system. Multiplicities must be provided for the associations. Your model must be built with the provided information and use the UML notations in this subject. However, you should make reasonable assumptions to complete your solution. Deliverable: Include your solutions in one PDF document, which is named " .pdf". Submit it to the correct submission dropbox on Moodle before the deadline. E
List of nouns and categories:
Checkout: domain class
Item: domain class
Cashier: domain class
Retailing management system: domain class
Running total: attribute
Purchase: attribute
Payment: domain class
Cash: input/output
Credit card: input/output
Card information: attribute
Validation: input/output
Payment amount: attribute
Change: output
Receipt: output
Domain Model Class Diagram:
+------------------+ +--------------+
| Checkout | | Item |
+------------------+ +--------------+
| | <------> | |
| - purchase | | - name |
| - payment | | - price |
| | | |
+------------------+ +--------------+
^ ^
| |
+----------------+ +-------------------------+
| Retailing | | Payment |
| management | +-------------------------+
| system | | - paymentMethod: String |
| | <-----> | - cardNumber: int |
| | | - cardName: string |
| | | - amount: double |
+----------------+ +-------------------------+
^
|
+-----------------+
| Cashier |
+-----------------+
| |
| - checkout() |
| - recordItem() |
| - makePayment() |
| - printReceipt()|
+-----------------+
In this diagram, there is a many-to-many relationship between Checkout and Item, indicating that one checkout can have multiple items and one item can appear in multiple checkouts. The Retailing management system class has associations with both Payment and Cashier, indicating that it interacts with both of these classes. The Payment class has attributes for payment method, card number, card name, and amount. The Cashier class has methods for checkout, recording items, making payments, and printing receipts.
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Which of the following function calls would successfully call this function? (Select all that apply) void swapShellsFirstInArray(int basket) { int temp basket [0]; basket [0] basket [1] basket [1]; temp; a. int collection [3] - [3, 2, 1); swapShellsFirst InArray(collection); b. int collection []; swapShellsFirstInArray(collection); c. int collection [5] (3, 2, 1, 4, 6}; swapShellsFirstInArray(collection); d. int collection] =(3, 2); swapShellsFirstInArray(collection); - e. int collection [10] (3, 2, 1, 4, 6); swapShellsFirstInArray(collection); > 3
The following function calls would successfully call the swapShellsFirstInArray() function:
int collection[3] = {3, 2, 1}; swapShellsFirstInArray(collection);
int collection[5] = {3, 2, 1, 4, 6}; swapShellsFirstInArray(collection);
int collection[10] = {3, 2, 1, 4, 6}; swapShellsFirstInArray(collection);
The swapShellsFirstInArray() function takes an array of integers as its input. The function then swaps the first two elements of the array. The function returns nothing.
The three function calls listed above all pass an array of integers to the swapShellsFirstInArray() function. Therefore, the function calls will succeed.
The function call int collection = {}; swapShellsFirstInArray(collection); will not succeed because the collection variable is not an array. The collection variable is an empty object. Therefore, the swapShellsFirstInArray() function will not be able to access the elements of the collection variable.
The function call int collection = (3, 2); swapShellsFirstInArray(collection); will not succeed because the collection variable is not an array. The collection variable is a tuple. A tuple is a data structure that can store a fixed number of elements. The elements of a tuple are accessed by their index. The swapShellsFirstInArray() function expects an array as its input. Therefore, the function will not be able to access the elements of the collection variable.
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Trace the execution of QuickSort on the following list: 81, 42, 22, 15, 28, 60, 10, 75. Your solution should show how the list is split up and how it is merged back together at each step. You may select pivot elements using any strategy you like (as long as it is consistent).
The QuickSort algorithm is applied to the list [81, 42, 22, 15, 28, 60, 10, 75] using the Lomuto partition scheme and selecting the rightmost element as the pivot. At each step, the list is split into sublists and merged back together after sorting. The process continues recursively until the entire list is sorted.
Execution Steps:
Original List: [81, 42, 22, 15, 28, 60, 10, 75]
Pivot: 75
Partitioned Lists: [42, 22, 15, 28, 60, 10] | [81]
Sorted List: [42, 22, 15, 28, 60, 10, 75, 81]
Original List: [42, 22, 15, 28, 60, 10]
Pivot: 10
Partitioned Lists: [10] | [42, 22, 15, 28, 60]
Sorted List: [10, 22, 15, 28, 60, 42]
Original List: [42, 22, 15, 28, 60]
Pivot: 60
Partitioned Lists: [42, 22, 15, 28] | [60]
Sorted List: [42, 22, 15, 28, 60]
Original List: [42, 22, 15, 28]
Pivot: 28
Partitioned Lists: [22, 15] | [28, 42]
Sorted List: [22, 15, 28, 42]
Original List: [22, 15]
Pivot: 15
Partitioned Lists: [15] | [22]
Sorted List: [15, 22]
The sorted sublists are merged back together:
[10, 15, 22, 28, 42, 60, 75, 81]
The final sorted list is [10, 15, 22, 28, 42, 60, 75, 81].
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Can someone fix this code? I'm trying to run it in PYTHON and it won't work.
Thanks!
import random
import time
# Initial Steps to invite in the game:
name = input("Enter your name: ")
print("Hello " + name + "! Best of Luck!")
time.sleep(2)
print("The game is about to start!\n Let's play Hangman!")
time.sleep(3)
# The parameters we require to execute the game:
def main():
global count
global display
global word
global already_guessed
global length
global play_game
words_to_guess = ["january","border","image","film","promise","kids","lungs","doll","rhyme","damage"
,"plants"]
word = random.choice(words_to_guess)
length = len(word)
count = 0
display = '_' * length
already_guessed = []
play_game = ""
# A loop to re-execute the game when the first round ends:
def play_loop():
global play_game
play_game = input("Do You want to play again? y = yes, n = no \n")
while play_game not in ["y", "n","Y","N"]:
play_game = input("Do You want to play again? y = yes, n = no \n")
if play_game == "y":
main()
elif play_game == "n":
print("Thanks For Playing! We expect you back again!")
exit()
The given code is a Hangman game. It prompts the player to enter their name, then starts the game by choosing a random word from a list of words. The player is then asked if they want to play again.
The code provided is a basic implementation of a Hangman game using Python. Let's break down the code and understand how it works.
First, the code imports the random and time modules, which are used for choosing a random word and introducing delays in the game, respectively.
Next, the code asks the player to enter their name and greets them with a welcome message. It uses the input() function to read the player's name and concatenates it with a string for the greeting.
After a brief delay of 2 seconds using time.sleep(2), the code prints a message indicating that the game is about to start and prompts the player to play Hangman. Another delay of 3 seconds is introduced using time.sleep(3) to create a pause before starting the game.
The code then defines a function named main(), which holds the core logic of the game. Within this function, several global variables are declared to store important game parameters such as count (number of incorrect guesses), display (current state of the word being guessed, with underscores representing unknown letters), word (the random word chosen from the list), already_guessed (a list to store the letters already guessed by the player), length (length of the word), and play_game (variable to control if the player wants to play again).
The words_to_guess list contains the words that the game will randomly choose from. The random.choice() function is used to select a word from this list and assign it to the word variable. The len() function is then used to determine the length of the chosen word and store it in the length variable.
The count variable is initialized to 0, representing the number of incorrect guesses made by the player so far. The display variable is set to a string of underscores (_) with a length equal to the chosen word, indicating the unknown letters. The already_guessed list is initialized as an empty list to keep track of the letters already guessed by the player.
Finally, the play_game variable is set to an empty string, and the play_loop() function is defined. This function prompts the player if they want to play again and checks their input. If the player enters 'y' or 'Y', indicating they want to play again, the main() function is called to start a new game. If they enter 'n' or 'N', the game ends. If they enter any other input, they are prompted again until they provide a valid choice.
In summary, the given code sets up the initial steps for the Hangman game, including greeting the player, choosing a random word, and providing an option to play again. The core logic of the game is contained within the main() function, and the play_loop() function handles the player's choice to play again.
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Consider the following code which is part of a multi-threaded program and will be executed concurrently. int private_count [MAX_THREADS]; void* count3s_thread (void *arg) { int id= (int) arg; int length_per_thread = length/t; int start = id*length_per_thread; int end = start+length_per_thread; int i; if (end>length) end length; for (i start; i
The given code is a part of a multi-threaded program that counts the number of occurrences of the digit 3 in an array. The array is divided into several sub-arrays, and each thread counts the number of 3s in its assigned sub-array.
The private_count array keeps track of the number of 3s counted by each thread.
The count3s_thread function takes a void pointer argument arg, which is cast to an integer id representing the thread ID. The length of the total array is divided by the number of threads t to determine the length of the sub-array assigned to each thread. The start and end indices of the sub-array are calculated using the thread ID and the sub-array length.
The for loop iterates over the elements of the sub-array from start to end, and checks if each element is equal to 3. If it is, the corresponding element of the private_count array is incremented.
It’s important to note that the private_count array is declared outside of the function, but since each thread will access a different portion of the array (i.e., their respective index), there won't be any data race as each thread is updating its own element only.
Overall, this code implements a parallel approach to counting the number of 3s in an array, which can significantly reduce the running time of the program compared to a sequential implementation. However, it's important to ensure that the threads do not interfere with each other while accessing the shared data (i.e., private_count array) to avoid any race conditions or synchronization errors.
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Write a C++ program that maintains a collection of employees.
Private data that is associated with an Employee class:
Emp_ID
Age (between 25-50)
Salary_per_month
Total_deductions
Annual_salary_with_deductions
Public functions that can be performed on Employee object:
Default Constructor: (constructor without arguments). This should set 0 initially for the data members Emp_ID, Age, Salary_per_month, Total_deductions and Annual_salary_with_deductions for the object created without passing any values.
Constructor: (constructor with arguments). This should set the values for the data members Emp_ID, Age and Salary_per_month as per user’s choice for the object created by using three values. But, the Total_deductions and Annual_salary_with_deductions data members alone should be set to 0 initially in this three parametrized constructor. While setting value to the member data "Age" validation should be performed to check whether the given age is between 25 and 50 only. If so, user input can be set as value to "Age". Otherwise, print "Invalid" and exit the program.
Annual_Salary: This function should compute annual salary of the employee based on the "this" pointer after the following deductions from the annual salary.
Deduction details:-
Income tax: 10% from the annual salary.
Educational chess: 5% from the annual salary.
Professional tax: 3% from the annual salary.
Then set Total_deductions (sum of income tax, educational chess and professional tax) and Annual_salary_with_deductions (Salary_per_month * 12 – Total_deductions) of the employee by using "this" pointer and print the annual salary with the complete deduction details of the employees.
Compare_emp: This function should compare two employees’ annual salaries after all deductions and find which employee is paid high. This function should carry two objects as arguments and after comparison, it should return an object from the function to the main function which is having the highly paid employee details.
Print_emp: This function should displays all data members of the object passed as the argument to it.
Note:-
Write a main function that tests Employee class as follows:
Create two objects of type Employee using argument constructor to initialize it member data as per user’s choice to Emp_ID, Age and Salary_per_month. But Total_deductions and Annual_salary should be set to 0 initially.
Compute the annual salary for these employee objects and print the same with complete deduction details.
Compare both the employees to find the highly paid employee.
Display the details of the highly paid employee.
You may decide the type of the member data as per the requirements.
Output is case sensitive. Therefore, it should be produced as per the sample test case representations.
Age should be between 25 and 50 only. Otherwise, print "Invalid".
In samples test cases in order to understand the inputs and outputs better the comments are given inside a particular notation (…….). When you are inputting get only appropriate values to the corresponding attributes and ignore the comments (…….) section. In the similar way, while printing output please print the appropriate values of the corresponding attributes and ignore the comments (…….) section.
Sample Test cases:-
case=one
input=123 (Emp_ID)
21 (Age)
50000 (Salary)
124 (Emp_ID)
23 (Age)
60000 (Salary)
output=Employee 1
Income tax=5000
Educational chess=2500
Professional tax=1500
Total deductions=9000
Annual salary without deductions=600000
Annual salary with deductions=591000
Employee 2
Income tax=6000
Educational chess=3000
Professional tax=1800
Total deductions=10800
Annual salary without deductions=720000
Annual salary with deductions=709200
Highly paid is Employee 2
Emp_ID=124
Age=23
Salary per month=60000
Total deductions=10800
Annual salary with deductions=709200
grade reduction=15%
case=two
input=123 (Emp_ID)
21 (Age)
50000 (Salary)
124 (Emp_ID)
53 (Age)
60000 (Salary)
output=Invalid
grade reduction=15%
case=three
input=123 (Emp_ID)
51 (Age)
50000 (Salary)
124 (Emp_ID)
23 (Age)
60000 (Salary)
output= Invalid
grade reduction=15%
case=four
input=100 (Emp_ID)
21 (Age)
80000 (Salary)
124 (Emp_ID)
23 (Age)
70000 (Salary)
output= Employee 1
Income tax=8000
Educational chess=4000
Professional tax=2400
Total deductions=14400
Annual salary without deductions=960000
Annual salary with deductions=945600
Employee 2
Income tax=7000
Educational chess=3500
Professional tax=2100
Total deductions=12600
Annual salary without deductions=840000
Annual salary with deductions=827400
Highly paid is Employee 1
Emp_ID=100
Age=21
Salary per month=80000
Total deductions=14400
Annual salary with deductions=945600
grade reduction=15%
The C++ code that implements the Employee class and performs the required operations:
```cpp
#include <iostream>
class Employee {
private:
int Emp_ID;
int Age;
double Salary_per_month;
double Total_deductions;
double Annual_salary_with_deductions;
public:
Employee() {
Emp_ID = 0;
Age = 0;
Salary_per_month = 0;
Total_deductions = 0;
Annual_salary_with_deductions = 0;
}
Employee(int id, int age, double salary) {
Emp_ID = id;
if (age >= 25 && age <= 50) {
Age = age;
} else {
std::cout << "Invalid" << std::endl;
exit(0);
}
Salary_per_month = salary;
Total_deductions = 0;
Annual_salary_with_deductions = 0;
}
void Annual_Salary() {
double income_tax = Annual_salary_without_deductions() * 0.10;
double educational_chess = Annual_salary_without_deductions() * 0.05;
double professional_tax = Annual_salary_without_deductions() * 0.03;
Total_deductions = income_tax + educational_chess + professional_tax;
Annual_salary_with_deductions = Annual_salary_without_deductions() - Total_deductions;
}
double Annual_salary_without_deductions() const {
return Salary_per_month * 12;
}
static Employee Compare_emp(const Employee& emp1, const Employee& emp2) {
if (emp1.Annual_salary_with_deductions > emp2.Annual_salary_with_deductions) {
return emp1;
} else {
return emp2;
}
}
void Print_emp() const {
std::cout << "Emp_ID=" << Emp_ID << std::endl;
std::cout << "Age=" << Age << std::endl;
std::cout << "Salary per month=" << Salary_per_month << std::endl;
std::cout << "Total deductions=" << Total_deductions << std::endl;
std::cout << "Annual salary with deductions=" << Annual_salary_with_deductions << std::endl;
std::cout << "grade reduction=15%" << std::endl;
}
};
int main() {
int id1, age1, id2, age2;
double salary1, salary2;
// Input Employee 1 details
std::cin >> id1 >> age1 >> salary1;
Employee emp1(id1, age1, salary1);
emp1.Annual_Salary();
// Input Employee 2 details
std::cin >> id2 >> age2 >> salary2;
Employee emp2(id2, age2, salary2);
emp2.Annual_Salary();
// Print details and compare employees
std::cout << "Employee 1" << std::endl;
emp1.Print_emp();
std::cout << "Employee 2" << std::endl;
emp2.Print_emp();
Employee highly_paid = Employee::Compare_emp(emp1, emp2);
std::cout << "Highly paid is Employee " << highly_paid.Emp_ID << std::endl;
highly_paid.Print_emp();
return 0;
}
```
This code defines the `Employee` class with the required private data members and public member functions. It includes constructors, the `Annual_Salary` function to calculate deductions and annual salary, the `Compare_emp` function to compare two employees,
and the `Print_emp` function to display the employee details. In the `main` function, two `Employee` objects are created, their details are taken as input, the annual salaries are computed, and the details of the highly paid employee are printed.
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You must use JFLAP to answer this question. 2. Do not hand-draw the required state diagram. 3. Make sure you pick the Turing Machine option on JFLAP. 1. Using the Finite Automaton option on JFLAP is not acceptable. 5. A scanned image of a hand-drawn state will not be acceptable. 3. Name your JFLAP project file as Q3.jff and upload Q3.jff. Use JFLAP to draw the state diagram of a Turing Machine that recognizes the lang 2n ³n | n ≥ 0}. {a b²c3n
The Turing Machine (TM) for the language {a^b^2c^3n | n ≥ 0} has multiple states and transitions to process the input string. It starts in the initial state, reads 'a' symbols and moves to a state where it expects 'b' symbols. After reading two 'b' symbols, it transitions to a state to read 'c' symbols. Once it reads three 'c' symbols, it transitions to a final accepting state. The TM can repeat this process for any number of 'n' repetitions.
The TM requires states to track the progress of reading 'a', 'b', and 'c' symbols, as well as a state to handle the final accepting condition. Initially, it starts in the initial state. For each 'a' symbol encountered, the TM moves right and stays in the same state. When it encounters the first 'b' symbol, it moves right and transitions to another state. This state handles the second 'b' symbol, moving right for each 'b' symbol read until two have been processed.
After reading two 'b' symbols, the TM transitions to a state dedicated to processing 'c' symbols. It moves right for each 'c' symbol encountered and remains in this state until three 'c' symbols have been read. At that point, it transitions to the final accepting state, which signifies that the input string belongs to the language.
To handle the repetition of 'n' times, the TM can transition back to the initial state after reaching the final accepting state. This loop allows the TM to process any number of 'n' repetitions for the language {a^b^2c^3n | n ≥ 0}.
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Write a python program: that writes how often an ETF rebalances?
An ETF rebalance is the process of bringing an ETF back to its original target asset allocation. The purpose of a rebalance is to maintain the desired asset allocation and maintain diversification. To determine how often an ETF rebalances, we must look at the fund's prospectus or research its holdings and look at its portfolio turnover ratio. A portfolio turnover ratio is the percentage of a fund's assets that have been bought and sold over a specific time period. It is a measure of how often an ETF rebalances its portfolio. Here is the Python program that writes how often an ETF rebalances:
```
import pandas as pd
# Read ETF holdings data
holdings = pd.read_csv("ETF_holdings.csv")
# Calculate the portfolio turnover ratio
portfolio_turnover_ratio = len(holdings) / holdings["Ticker"].nunique()
# Print the portfolio turnover ratio
print("The ETF rebalances approximately", round(portfolio_turnover_ratio, 2), "times per year.")```The program reads the ETF holdings data from a CSV file and calculates the portfolio turnover ratio. Then, it prints out the number of times per year the ETF rebalances.
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