Programming has not only given us smartphones, tablets, and extremely useful software programs, it has changed the way electrical and computer engineers are designing circuits. For example, an LED effect such as a blinking light could be built using a 555 timer circuit rather simply. However, using a cheap MCU, the circuitry is less complex and a few lines of code can achieve the same effect. It is even possible to create much more complex lighting effects using just a few more lines of code.
The first general-purpose 8-bit microprocessor in the world was the Intel 8008. After its introduction, MCUs quickly began replacing discrete logic. Due to their small size, ease of use, and programmability, engineers quickly welcomed them into the field. However, in the 80s, memory was scarce and even more important, it was expensive. In January of 1983, memory was approximately $2,396 per megabyte, whereas today it is approximately half a penny per megabyte. Consequently, the cost of memory in the past put a limit on the applications MCUs could be used for. Engineers needed to program with caution, making sure their code used as few lines as possible and did not surpass their memory limit.
Bjarne Stroustrup, creator of C++. (Source: Wiki)
Today, MCUs are cheap and memory is abundant. Furthermore, MCUs have been integrated into products we use every day such as: displays, printers, keyboards, phones, washing machines, microwaves, and most importantly, cars. A new luxury car today could consist of hundreds of MCUs.
With all the great development in software and MCUs up to this point, it is imperative that engineers build a strong foundation in programming. Programming not only gives people a deep insight on how computers work, it opens up a large array of new tools you can use your computer for. Overall, programming has made our lives unbelievably technically involved. Programming is the powerful force driving modern day technology, and we still have a long road to drive.
Other notable happenings in 1982:
Sun Microsystems incorporates.
Adobe was founded, placing PostScript description language in the Apple LaserWriter.
Symantec was founded, mostly selling security and information management software.
Hercules, maker of high-resolution screens, was founded.
Maxtor was founded, now absorbed into Seagate.
Commodore 64 sold with 64 kilobytes of RAM for $200, the fastest selling computer of all time.
HX-20, the first notebook-sized portable computer, debuted.
I cut my teeth on an Apple II! Learned programming in assembly language on a Z80 processor. And quickly moved to Fortran and C. I have been out of the electronics and computer programming for over 20 years and am just amazed at what the people can now program. Gone are the days of trying to fit code into 2K of memory!
With my youngest starting college, I am once again getting reacclimated with C++ and am amazed at the extension of this programming language. Then I discovered visual C++. WOW! Even an oldtimer can get into the new stuff!
Remember the Intel MDS80, the development system for the MCS-48 series processors? If I remember right the system had two 8" floppy drives, and that's the machine we used to write the 1K of code we squeezed into an 8048. At one point the place I worked at had lost the ability to move the source code out of the MDS80 and its 8" drives, so I once had to type all the code into my new flagship machine, a `286 PC clone. It was a huge improvement, though, because I could assemble (not compile, this was Assembly) in as little as five minutes. Yup, just type into the command line on the PC, and walk down the hall for a cup of coffee. When I came back from the cafeteria I'd pull a windowed part out of the uV eraser, burn the HEX file with my Needham programmer and start debugging the latest change.
There isn't a day I don't marvel at how far embedded software development has come, and what what the next big change will be.
Very nice historical synopsis on coding! I always appreciated having to learn assembly as it gave me an understanding of what was really happening at the bit level, but I also deeply appreciate the evolution of higher level programming languages to get the job done. I think it is important for an engineer to learn low level programming so that they have low level control when needed, but can also use higher level languages to implement solutions that meet customer and project criteria and compatibility requirements.
Nice retrospective, Cabe. I think the time will come when all engineers will have to have good programming skills when they leave college (not just one or two classes in programming). I don't think that mechanical engineers will be able to avoid it. From what I can tell, though, engineering curriculums don't seem to be making that a priority yet, but I think the time is coming.
Charles, now a days programming and computer literacy is a mandatory for all the engineering branches. Even mechanical and civil graduates are doing programming courses, inorder to grab a job in IT domain. Moreover, now a days most of the branches had introduced C/C++ programming in their curriculum either as main subject or elective.
The thing is, when I was covering app programming, everything was about getting simpler and also being more visual, so even people who didn't have coding expertise could use visual tools to code to build applications. Is something similar happening in the engineering world? I am not super up to speed on CAD tools, but I imagine there is a similar trend there, no?
When I was in school FORTRAN counted for foreign language credit. We ran stacks of punchcards to the VAX gnomes. Many a student broke down in tears when they accidentally dropped their stack of (unnumbered) cards.
In the DOS days I was a BASIC guru and a whiz with Turbo BASIC.
"Electrical engineering is without a doubt one of the fastest growing disciplines today. Between the constantly changing curricula and rapidly advancing technology, engineers are required to keep themselves up-to-date with the latest tech and tools."
Cabe, we can say electrical engineering is the mother of modern engineering. In 70's there are only 3 branches like electrical, mechanical and civil. Later electrical branch is divided in to electronics, computer, communication etc. While I done my graduation in 90's all such divisions are under the electrical department.
Electrical and electronic engineering are quite a bit different from program writing, probably almost opposites. Yes, engineers do need to understand a lot about computers if they are qoing to design a system that uses or interfaces with a computer, but really, desgining circuits that actually function and are constrained by cost and size limitations is a quite different thing than creating code that is so very bloated that one person can't even read all of it, let alone understand exactly what it is doing.
William, learning a tool or software for professional work and learning a programming language is different. In some of the tools, command line access and writing scripts are very much requires for executing the batch file during simulation or synthesis. Such command line access may be difficult for most of the non-IT professionals.
That is for certain. The ability to make the process between program writing and the production of correctly functioning code can be quite daunting at best.
The closest I get to embedded code is writing detailed functional specifications that describe both the "screens" and the I/O actions in sequential detail. The challenge is that in addition to creating the description of what happens when everything goes exactly right, it also needs to describe what happens when things don't function correctly. That part requires an excellent understanding of the entire non-software portion of the system, and sometimes requires extensive discussions with the person writing the actual code. The problem there is that most programmers don't seem to be quite normal people. It is not clear to me if it is programming that makes them that way, or if they are programmers because they are that way.
Seriously doubt he ever really uttered it, but IBMs Thomas Watson supposedly said in the 1940s that there would only ever be a need for about 5 computers in the United States. Microcomputers changed that whole paradigm.
They came on the scene when computer science was making some great strides, and application software written by companies other than the computer manufacturer was really coming into its own.
BTW, AutoCAD was hardly the first Computer Aided Design software. There were numerous, completely incompatible and incomprehensible electonic drafting programs before it. AutoDesk had the vision to see that the PC would grow up.
As for Java, don't slight the contributions of Sun co-founder Bill Joy in the development and emergence of the language. Interestingly in light of recent issues with security, the license has always included a caveat that it was not to be used to program safety systems - medical, missiles, or nuclear sites.
AutoCAD wasn't the first drafting program at all, but that is when they started. Now they are an industry standard. The first "modern" as we know it CAD package that stuck. Keep in mind, Photoshop wasn't the first graphical program. The iPOD wasn't the first MP3 player either. But they are now considered the most important.
WilliamK, I agree with your perspective on the need for other skill sets beyond programming. The biggest challenge over the last number of years, and continuing into the future, is the need for multidisciplinary engineering teams that combine a broad set of capabilities from mechanical, to electrical, to electronic design and software. There's no doubt that engineers need to understand how software works but everyone doesn't need to have specific programming skills themselves.
I agree apresher. I hired a couple of CS majors for my embedded designs and quickly found that they really didn't have the proper skill set for developing embedded designs. I'm sure there are CS guys that can get the job done, but EEs perform much better with the limited resources (execution speed, memory, etc) of an embedded design and the EEs also do a better job at troubleshooting system errors since they have a better understanding of glue logic and the other components in a system.
tekochip- I think you hit the nail on the head with "limited resources." Based on my experience in interviews and seeing CS's in action, it seems many CS schools don't touch on coding efficiency.
Now that I think about it, I haven't seen strong evidence CS schools even touch on good code. Graduates seem to hit the field either "having the knack," or (to paraphrase Steve Martin,) "not have knack.)
Stroustrup suggests that the origin of the name C++ is related to George Orwell's "Newspeak" described in the appendix to his novel 1984: "any word ... could be strengthened by the affix plus-, or, for greater strength, doubleplus-." This is part of a soi-disant "C" language. See Orwell, 1984, pp 315 and 322.
While every company might have their own solution for PLM, Aras Innovator 10 intends to make PLM easier for all company sizes through its customization. The program is also not resource intensive, which allows it to be appropriated for any use. Some have even linked it to the Raspberry Pi.
solidThinking updated its Inspire program with a multitude of features to expedite the conception and prototype process. The latest version lets users blend design with engineering and manufacturing constraints to produce the cheapest, most efficient design before production.
MIT students modified a 3D printer to enable it to print more than one object and print on top of existing printed objects. All of this was made possible by modifying a Solidoodle with a height measuring laser.
Siemens released Intosite, a cloud-based, location-aware SaaS app that lets users navigate a virtual production facility in much of the same fashion as traversing through Google Earth. Users can access PLM, IT, and other pertinent information for specific points on a factory floor or at an outdoor location.
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