This course can also be taken for academic credit as ECEA 5734, part of CU Boulder’s Master of Science in Electrical Engineering degree.
제공자:
콜로라도 대학교 볼더 캠퍼스
콜로라도 대학교
Algorithms for Battery Management Systems 특화 과정콜로라도 대학교 볼더 캠퍼스이 강좌에 대하여
최근 조회 14,756회
공유 가능한 수료증
완료 시 수료증 획득
100% 온라인
지금 바로 시작해 나만의 일정에 따라 학습을 진행하세요.
다음 특화 과정의 5개 강좌 중 5번째 강좌:
유동적 마감일
일정에 따라 마감일을 재설정합니다.
중급 단계
완료하는 데 약 23시간 필요
영어
자막: 프랑스어, 포르투갈어 (유럽), 러시아어, 영어, 스페인어
배울 내용
How to design balancers and power-limits estimators for lithium-ion battery packs
공유 가능한 수료증
완료 시 수료증 획득
100% 온라인
지금 바로 시작해 나만의 일정에 따라 학습을 진행하세요.
다음 특화 과정의 5개 강좌 중 5번째 강좌:
유동적 마감일
일정에 따라 마감일을 재설정합니다.
중급 단계
완료하는 데 약 23시간 필요
영어
자막: 프랑스어, 포르투갈어 (유럽), 러시아어, 영어, 스페인어
제공자:
콜로라도 대학교 볼더 캠퍼스
CU-Boulder is a dynamic community of scholars and learners on one of the most spectacular college campuses in the country. As one of 34 U.S. public institutions in the prestigious Association of American Universities (AAU), we have a proud tradition of academic excellence, with five Nobel laureates and more than 50 members of prestigious academic academies.
콜로라도 대학교
The University of Colorado is a recognized leader in higher education on the national and global stage. We collaborate to meet the diverse needs of our students and communities. We promote innovation, encourage discovery and support the extension of knowledge in ways unique to the state of Colorado and beyond.
석사 학위 취득 시작
This 강좌 is part of the 100% online Master of Science in Electrical Engineering from 콜로라도 대학교 볼더 캠퍼스.
If you are admitted to the full program, your courses count towards your degree learning.
강의 계획 - 이 강좌에서 배울 내용
완료하는 데 3시간 필요
Passive balancing methods for battery packs
In previous courses, you learned how to write algorithms to satisfy the estimation requirements of a battery management system. Now, you will learn how to write algorithms for two primary control tasks: balancing and power-limits computations. This week, you will learn why battery packs naturally become unbalanced, some balancing strategies, and how passive circuits can be used to balance battery packs.
완료하는 데 3시간 필요
7개 동영상 (총 79분), 12 개의 읽기 자료, 6 개의 테스트
7개의 동영상
5.1.2: Introduction to battery-pack balancing10m
5.1.3: How do battery packs become imbalanced?15m
5.1.4: What are the criteria for specifying a balancing setpoint for a battery pack?13m
5.1.5: What are the criteria for specifying when to balance a battery pack?13m
5.1.6: What kinds of circuits can be used for passively balancing a battery pack?16m
5.1.7: Summary of "Passive balancing methods for battery packs"; what next?2m
12개의 읽기 자료
Notes for lesson 5.1.11m
Frequently asked questions5m
Course resources5m
How to use discussion forums5m
Earn a certificate5m
Are you interested in earning an MSEE degree?5m
Notes for lesson 5.1.21m
Notes for lesson 5.1.31m
Notes for lesson 5.1.41m
Notes for lesson 5.1.51m
Notes for lesson 5.1.61m
Notes for lesson 5.1.71m
6개 연습문제
Practice quiz for lesson 5.1.29m
Practice quiz for lesson 5.1.39m
Practice quiz for lesson 5.1.49m
Practice quiz for lesson 5.1.59m
Practice quiz for lesson 5.1.69m
Quiz for week 130m
완료하는 데 3시간 필요
Active balancing methods for battery packs
Passive balancing can be effective, but wastes energy. Active balancing methods attempt to conserve energy and have other advantages as well. This week, you will learn about active-balancing circuitry and methods, and will learn how to write Octave code to determine how quickly a battery pack can become out of balance. This is useful for determining the dominant factors leading to imbalance, and for estimating how quickly the pack must be balanced to maintain it in proper operational condition.
완료하는 데 3시간 필요
6개 동영상 (총 73분), 6 개의 읽기 자료, 6 개의 테스트
6개의 동영상
5.2.2: How to balance actively using transformer-based circuits7m
5.2.3: How to balance actively using a shared active bus14m
5.2.4: Using simulation to show how quickly we must balance a battery pack14m
5.2.5: Introducing Octave code to simulate balancing: The main program loop21m
5.2.6: Summary of "Active balancing methods for battery packs"; what next?3m
6개의 읽기 자료
Notes for lesson 5.2.11m
Notes for lesson 5.2.21m
Notes for lesson 5.2.31m
Notes for lesson 5.2.41m
Notes for lesson 5.2.51m
Notes for lesson 5.2.61m
6개 연습문제
Practice quiz for lesson 5.2.19m
Practice quiz for lesson 5.2.29m
Practice quiz for lesson 5.2.39m
Practice quiz for lesson 5.2.49m
Practice quiz for lesson 5.2.515m
Quiz for week 230m
완료하는 데 2시간 필요
How to find available battery power using a simplified cell model
This week, we begin by reviewing the HPPC power-limit method from course 1. Then, you will learn how to extend the method to satisfy limits on SOC, load power, and electronics current. You will learn how to implement the power-limits computation methods in Octave code, and will see results for a representative scenario.
완료하는 데 2시간 필요
5개 동영상 (총 44분), 5 개의 읽기 자료, 5 개의 테스트
5개의 동영상
5.3.2: How to compute available battery power based on cell terminal voltage8m
5.3.3: How to consider other performance limits when computing available battery power7m
5.3.4: Introducing Octave code to compute power limits using simplified cell model12m
5.3.5: Summary of "How to find available battery power using a simplified cell model"; what next?1m
5개의 읽기 자료
Notes for lesson 5.3.11m
Notes for lesson 5.3.21m
Notes for lesson 5.3.31m
Notes for lesson 5.3.41m
Notes for lesson 5.3.51m
5개 연습문제
Practice quiz for lesson 5.3.19m
Practice quiz for lesson 5.3.29m
Practice quiz for lesson 5.3.39m
Practice quiz for lesson 5.3.415m
Quiz for week 330m
완료하는 데 4시간 필요
How to find available battery power using a comprehensive cell model
The HPPC method, even as extended last week, makes some simplifying assumptions that are not met in practice. This week, we explore a more accurate method that uses full state information from an xKF as its input, along with a full ESC cell model to find power limits. You will learn how to implement this method in Octave code and will compare its computations to those from the HPPC method you learned about last week.
완료하는 데 4시간 필요
6개 동영상 (총 69분), 6 개의 읽기 자료, 6 개의 테스트
6개의 동영상
5.4.2: How to solve for a future battery condition using the bisection algorithm11m
5.4.3: How to use bisection to estimate available power using comprehensive cell model16m
5.4.4: Introducing Octave code to compute power limits using comprehensive cell model9m
5.4.5: Using simulation to compare and contrast different power-estimation methods12m
5.4.6: Concluding remarks for the specialization6m
6개의 읽기 자료
Notes for lesson 5.4.11m
Notes for lesson 5.4.21m
Notes for lesson 5.4.31m
Notes for lesson 5.4.41m
Notes for lesson 5.4.51m
Notes for lesson 5.4.61m
6개 연습문제
Practice quiz for lesson 5.4.19m
Practice quiz for lesson 5.4.215m
Practice quiz for lesson 5.4.315m
Practice quiz for lesson 5.4.420m
Practice quiz for lesson 5.4.520m
Quiz for week 440m
검토
BATTERY PACK BALANCING AND POWER ESTIMATION의 최상위 리뷰
SP 제공2020년 7월 15일
This is one of the best and most useful specialization in my eyes. I would encourage every person interested in EV domain to learn it. Thank you Dr Gregory Plett for this course
SG 제공2020년 8월 4일
Professor visualization is excellent and his explanation is extraordinary with the material.I am very Happy to complete this course and very Informative.
DC 제공2020년 5월 9일
Especially the last Week 6 (Honors Course) was extremely useful, to better understand the advanced physical/chemical models for lithium batteries.
SM 제공2020년 6월 27일
Excellent courses. Dr. Plett did a great job teaching this very relevant topic.
Algorithms for Battery Management Systems 특화 과정 정보
In this specialization, you will learn the major functions that must be performed by a battery management system, how lithium-ion battery cells work and how to model their behaviors mathematically, and how to write algorithms (computer methods) to estimate state-of-charge, state-of-health, remaining energy, and available power, and how to balance cells in a battery pack.
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