Integral Calculus through Data and Modeling
Johns Hopkins University via Coursera Specialization
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Overview
This specialization builds on topics introduced in single and multivariable differentiable calculus to develop the theory and applications of integral calculus. , The focus on the specialization is to using calculus to address questions in the natural and social sciences. Students will learn to use the techniques presented in this class to process, analyze, and interpret data, and to communicate meaningful results, using scientific computing and mathematical modeling. Topics include functions as models of data, differential and integral calculus of functions of one and several variables, differential equations, and optimization and estimation techniques.
Syllabus
Course 1: Calculus through Data & Modelling: Series and Integration
- Offered by Johns Hopkins University. This course continues your study of calculus by introducing the notions of series, sequences, and ... Enroll for free.
Course 2: Calculus through Data & Modelling: Techniques of Integration
- Offered by Johns Hopkins University. In this course, we build on previously defined notions of the integral of a single-variable function ... Enroll for free.
Course 3: Calculus through Data & Modelling: Integration Applications
- Offered by Johns Hopkins University. This course continues your study of calculus by focusing on the applications of integration. The ... Enroll for free.
Course 4: Calculus through Data & Modelling: Vector Calculus
- Offered by Johns Hopkins University. This course continues your study of calculus by focusing on the applications of integration to vector ... Enroll for free.
- Offered by Johns Hopkins University. This course continues your study of calculus by introducing the notions of series, sequences, and ... Enroll for free.
Course 2: Calculus through Data & Modelling: Techniques of Integration
- Offered by Johns Hopkins University. In this course, we build on previously defined notions of the integral of a single-variable function ... Enroll for free.
Course 3: Calculus through Data & Modelling: Integration Applications
- Offered by Johns Hopkins University. This course continues your study of calculus by focusing on the applications of integration. The ... Enroll for free.
Course 4: Calculus through Data & Modelling: Vector Calculus
- Offered by Johns Hopkins University. This course continues your study of calculus by focusing on the applications of integration to vector ... Enroll for free.
Courses
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This course continues your study of calculus by focusing on the applications of integration to vector valued functions, or vector fields. These are functions that assign vectors to points in space, allowing us to develop advanced theories to then apply to real-world problems. We define line integrals, which can be used to fund the work done by a vector field. We culminate this course with Green's Theorem, which describes the relationship between certain kinds of line integrals on closed paths and double integrals. In the discrete case, this theorem is called the Shoelace Theorem and allows us to measure the areas of polygons. We use this version of the theorem to develop more tools of data analysis through a peer reviewed project. Upon successful completion of this course, you have all the tools needed to master any advanced mathematics, computer science, or data science that builds off of the foundations of single or multivariable calculus.
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This course continues your study of calculus by focusing on the applications of integration. The applications in this section have many common features. First, each is an example of a quantity that is computed by evaluating a definite integral. Second, the formula for that application is derived from Riemann sums. Rather than measure rates of change as we did with differential calculus, the definite integral allows us to measure the accumulation of a quantity over some interval of input values. This notion of accumulation can be applied to different quantities, including money, populations, weight, area, volume, and air pollutants. The concepts in this course apply to many other disciplines outside of traditional mathematics. We will expand the notion of the average value of a data set to allow for infinite values, develop the formula for arclength and curvature, and derive formulas for velocity, acceleration, and areas between curves. Through examples and projects, we will apply the tools of this course to analyze and model real world data.
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In this course, we build on previously defined notions of the integral of a single-variable function over an interval. Now, we will extend our understanding of integrals to work with functions of more than one variable. First, we will learn how to integrate a real-valued multivariable function over different regions in the plane. Then, we will introduce vector functions, which assigns a point to a vector. This will prepare us for our final course in the specialization on vector calculus. Finally, we will introduce techniques to approximate definite integrals when working with discrete data and through a peer reviewed project on, apply these techniques real world problems.
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This course continues your study of calculus by introducing the notions of series, sequences, and integration. These foundational tools allow us to develop the theory and applications of the second major tool of calculus: the integral. Rather than measure rates of change, the integral provides a means for measuring the accumulation of a quantity over some interval of input values. This notion of accumulation can be applied to different quantities, including money, populations, weight, area, volume, and air pollutants. The concepts in this course apply to many other disciplines outside of traditional mathematics. Through projects, we will apply the tools of this course to analyze and model real world data, and from that analysis give critiques of policy. Following the pattern as with derivatives, several important methods for calculating accumulation are developed. Our course begins with the study of the deep and significant result of the Fundamental Theorem of Calculus, which develops the relationship between the operations of differentiation and integration. If you are interested in learning more advanced mathematics, this course is the right course for you.
Taught by
Joseph W. Cutrone, PhD