Hebrew University of Jerusalem
Build a Modern Computer from First Principles: From Nand to Tetris (Project-Centered Course)
Hebrew University of Jerusalem

Build a Modern Computer from First Principles: From Nand to Tetris (Project-Centered Course)

Shimon Schocken
Noam  Nisan

Instructors: Shimon Schocken

Top Instructor

213,900 already enrolled

Included with Coursera Plus

Gain insight into a topic and learn the fundamentals.
4.9

(3,618 reviews)

43 hours to complete
3 weeks at 14 hours a week
Flexible schedule
Learn at your own pace
97%
Most learners liked this course
Gain insight into a topic and learn the fundamentals.
4.9

(3,618 reviews)

43 hours to complete
3 weeks at 14 hours a week
Flexible schedule
Learn at your own pace
97%
Most learners liked this course

Details to know

Shareable certificate

Add to your LinkedIn profile

Taught in English

See how employees at top companies are mastering in-demand skills

Placeholder
Placeholder

Earn a career certificate

Add this credential to your LinkedIn profile, resume, or CV

Share it on social media and in your performance review

Placeholder

There are 8 modules in this course

Course introduction and overview, the roles of abstraction and implementation in systems design, the road ahead.

What's included

4 videos1 reading1 programming assignment

We will start with a brief introduction of Boolean algebra, and learn how Boolean functions can be physically implemented using logic gates. We will then learn how to specify gates and chips using a Hardware Description Language (HDL), and how to simulate the behaviour of the resulting chip specifications using a hardware simulator. This background will set the stage for Project 1, in which you will build, simulate, and test 15 elementary logic gates. The chipset that you will build this module will be later used to construct the computer's Arithmetic Logic Unit (ALU) and memory system. This will be done in modules 2 and 3, respectively.

What's included

8 videos1 reading1 programming assignment

General Course Information

What's included

1 video3 readings

Using the chipset that we've built in the previous module, we will now proceed to build a family of adders -- chips designed to add numbers. We will then take a big step forward and build an Arithmetic Logic Unit. The ALU, which is designed to perform a whole set of arithmetic and logical operations, is the computer's calculating brain. Later in the course we will use this ALU as the centerpiece chip from which we will build the computer's Central Processing Unit, or CPU. Since all these chips operate on binary numbers (0's and 1's), we will start this module with a general overview of binary arithmetic, and only then delve into building the ALU.

What's included

6 videos1 reading1 programming assignment

Having built the computer's ALU, this module we turn to building the computer's main memory unit, also known as Random Access Memory, or RAM. This will be done gradually, going bottom-up from elementary flip-flop gates to one-bit registers to n-bit registers to a family of RAM chips. Unlike the computer's processing chips, which are based on combinational logic, the computer's memory logic requires a clock-based sequential logic. We will start with an overview of this theoretical background, and then move on to build our memory chipset.

What's included

6 videos1 reading1 programming assignment

A critically important aspect of building a new computer system is designing the low-level machine language, or instruction set, with which the computer can be instructed to do various things. As it turns out, this can be done before the computer itself is actually built. For example, we can write a Java program that emulates the yet-to-be-built computer, and then use it to emulate the execution of programs written in the new machine language. Such experiments can give us a good appreciation of the bare bone "look and feel" of the new computer, and lead to decisions that may well change and improve both the hardware and the language designs. Taking a similar approach, in this module we assume that the Hack computer and machine language have been built, and write some low-level programs using the Hack machine language. We will then use a supplied CPU Emulator (a computer program) to test and execute our programs. This experience will give you a taste of low-level programming, as well as a solid hands-on overview of the Hack computer platform.

What's included

10 videos1 reading1 programming assignment

Let's recap the last four modules: we've built some elementary logic gates (module 1), and then used them to build an ALU (module 2) and a RAM (module 3). We then played with low-level programming (module 4), assuming that the overall computer is actually available. In this module we assemble all these building blocks into a general-purpose 16-bit computer called Hack. We will start by building the Hack Central Processing Unit (CPU), and we will then integrate the CPU with the RAM, creating a full-blown computer system capable of executing programs written in the Hack machine language.

What's included

6 videos1 reading1 programming assignment

Every computer has a binary machine language, in which instructions are written as series of 0's and 1's, and a symbolic machine language, also known as assembly language, in which instructions are expressed using human-friendly mnemonics. Both languages do exactly the same thing, and are completely equivalent. But, writing programs in assembly is far easier and safer then writing in binary. In order to enjoy this luxury, someone has to translate our symbolic programs into binary code that can execute as-is on the target computer. This translation service is done by an agent called assembler. The assembler can be either a person who carries out the translation manually, or a computer program that automates the process. In this module and final project in the course we learn how to build an assembler. In particular, we'll develop the capability of translating symbolic Hack programs into binary code that can be executed as-is on the Hack platform. Each one of you can choose to accomplish this feat in two different ways: you can either implement an assembler using a high-level language, or you can simulate the assembler's operation using paper and pencil. In both cases we give detailed guidelines about how to carry out your work.

What's included

8 videos1 reading1 programming assignment

Instructors

Instructor ratings
4.9 (795 ratings)
Shimon Schocken

Top Instructor

Hebrew University of Jerusalem
2 Courses236,236 learners
Noam  Nisan

Top Instructor

Hebrew University of Jerusalem
1 Course213,900 learners

Offered by

Recommended if you're interested in Algorithms

Why people choose Coursera for their career

Felipe M.
Learner since 2018
"To be able to take courses at my own pace and rhythm has been an amazing experience. I can learn whenever it fits my schedule and mood."
Jennifer J.
Learner since 2020
"I directly applied the concepts and skills I learned from my courses to an exciting new project at work."
Larry W.
Learner since 2021
"When I need courses on topics that my university doesn't offer, Coursera is one of the best places to go."
Chaitanya A.
"Learning isn't just about being better at your job: it's so much more than that. Coursera allows me to learn without limits."

Learner reviews

4.9

3,618 reviews

  • 5 stars

    93.03%

  • 4 stars

    5.74%

  • 3 stars

    0.55%

  • 2 stars

    0.16%

  • 1 star

    0.49%

Showing 3 of 3618

JJ
5

Reviewed on May 6, 2020

AI
5

Reviewed on Jun 13, 2021

MH
5

Reviewed on Jun 21, 2021

New to Algorithms? Start here.

Placeholder

Open new doors with Coursera Plus

Unlimited access to 10,000+ world-class courses, hands-on projects, and job-ready certificate programs - all included in your subscription

Advance your career with an online degree

Earn a degree from world-class universities - 100% online

Join over 3,400 global companies that choose Coursera for Business

Upskill your employees to excel in the digital economy

Frequently asked questions