Wall of Questions – Simple Student Involvement

Posted: November 4, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , , , | Leave a comment

Teaching an intensive mode class can be challenging. Talking to anyone for 6 hours in a row (however you try and break it up) requires you to try and maintain engagement with student, but the student has to want to become and stay engaged! We’re humans so we’re always more interested in things when it is relevant to our interests – the question now becomes “How can I make students care about what I’m teaching because it is relevant to them?”

I’ve learned a lot from looking at the great work coming out of CS Unplugged, so I decided to take a low-tech approach to getting the students involved in the knowledge construction in the course.

On the Friday night of teaching, I gave my students a simple homework question: “What is your big question about networking?” This could be technical, social or crystal-ball gazing. The next morning, I handed out some large sticky notes in a variety of garish colours and asked them to write their questions on the notes and stick them on the board. This is what it looked like this morning (after about 6 hours of teaching).

The Big Network Question Board

The blue, orange and pink rectangles are questions. The ones on the left are yet to be answered. The ones on the right have been answered. (The green post-its are 2D bit parity as an audience participation magic trick.)

I’ve been answering these questions as fill-ins, where I have gaps, but a lot of them address issues that I was planning to cover anyway. The range is, however, far wider than I would have thought of but it’s given me a chance to address the applications and implications of networking, to directly answer questions that are of interest to the students.

Here are some (not verbatim) examples: What happened to the versions of the Internet Protocol that aren’t 4 or 6? What would happen if we had a human colony on Mars in terms of network implications? Was the IPv4 allocation ‘fair’ in terms of all countries? Could you run WiFi in the underground train network and, if so, what is the impact of the speed of the train? Will increased WiFi coverage give us cancer?

Every student has a question on the board and, now, every student is (at least to a slight degree) involved in the course. A lot of the questions that are left are security questions, and I’ll answer them as part of my security lectures this afternoon.

If you like this, and want to try it, then I am not claiming any originality for this but I can offer some suggestions:

  1. Give the students a little time to think about the question. It’s a good homework assignment.
  2. Get them to fill out the notes in class. As they finish their notes and pop them up to the board, it appears to encourage other people to finish their own notes to get them up. The notes are also shorter because the students want to get it done quickly.
  3. Once the notes are up, quickly review them to see how you can use them and where they fit into your teaching.
  4. When you can, group the notes by theme based on what you are teaching. I left them unordered for a while and I kept having to exhaustively search them, which is irritating.
  5. Be bold and prominent – the board is an eye-catcher and it clearly says “We have questions!” It’s also dynamic because I can easily rearrange it, move it or regroup the notes.

I’m still thinking about what to do with the notes next. I am planning to keep them but am unsure as to whether I want to ‘capture’ answers to this as I may have a knock-on effect for the next offering of this course.

What pleased me was the students who recognised their own question, because their faces lit up as I spoke to their concern. For a relatively low effort investment, that’s a great reward.

Could I have used an electronic forum? Yes, but then the focus isn’t in the classroom. The board, and your question, are in the classroom. You can go up and look at anyone else’s to see if it’s interesting. Rather than taking the application focus out of the classroom, we’re bringing in the realities and the answers as I go through the teaching.

Is there a risk that they’ll ask something I don’t know? No more than usual, and now I can sneak off and look it up before I answer, because it’s on the board. Being an honest man, I would of course have to say “I had to look this up” but I did warn them that this might happen. If a student can ask a question that has me scratching my head but I can develop an answer, I think that’s a very valuable example and it’s probably a nice moment for the student too.

I’ll certainly be doing this again!

 

369 (+2)

Posted: November 3, 2012 | Author: | Filed under: Education, Opinion | Tags: , , , , , , , , , , , , , , , , | 1 Comment

( +2 )

The post before my previous post was my 369th post. I only saw because I’m in manual posting mode at the moment and it’s funny how my brain immediately started to pull the number apart. It’s the first three powers of 3, of course, 3, 6, 9, but it’s also 123 x 3 (and I almost always notice 1,2,3). It’s divisible by 9 (because the digits add up to 9), which means it’s also divisible by 3 (which give us 123 as I said earlier). So it’s non-prime (no surprises there). Some people will trigger on the 36x part because of the 365/366 number of days in the year.

That’s pretty much where I stop on this, and no doubt there will be much more in the comments from more mathematical folk than I, but numbers almost always pop out at me. Like some people (certainly not all) in the fields of Science Technology Engineering and Mathematics, numbers and facts fascinate me. However, I know many fine Computer Scientists who do not notice these things at all – and this is one of those great examples where the stereotypes fall down. Our discipline, like all the others, has mathematical people, some of whom are also artists, musicians, poets, jugglers, juggalos, but it also has people who are not as mathematical. This is one of the problems when we try to establish who might be good at what we do or who might enjoy it. We try to come up with a simple identification scheme that we can apply – the risk being, of course, that if we get it wrong we risk excluding more people than we include.

So many students tell me that they can’t do computing/programming because they’re no good at maths. Point 1, you’re probably better at maths than you think, but Point 2, you don’t have to be good at maths to program unless you’re doing some serious formal and proof work, algorithmic efficiencies or mathematical scientific programming. You can get by on a reasonable understanding of the basics, and yes, I do mean algebra here but very, very low level,  and focus as you need to. Yes, certain things will make more sense if your mind is trained in a certain way, but this comes with training and practice.

It’s too easy to put people in a box when they like or remember numbers, and forget that half the population (at one stage) could bellow out 8675309 if they were singing along to the radio. Or recite their own phone number from the house they lived in when they were 10, for that matter. We’re all good for about 7 digit numbers, and a few of these slots, although the introduction of smart phones has reduced the number of numbers we have to remember.

So in this 369(+2)th post, let me speak to everyone out there who ever thought that the door to programming was closed because they couldn’t get through math, or really didn’t enjoy it. Programming is all about solving problems, only some of which are mathematical. Do you like solving problems? Did you successfully dress yourself today?

Did you, at any stage in the past month, run across an unfamiliar door handle and find yourself able to open it, based on applying previous principles, to the extent that you successfully traversed the door? Congratulations, human, you have the requisite skills to solve problems. Programming can give you a set of tools to apply that skill to bigger problems, for your own enjoyment or to the benefit of more people.

Road to Intensive Teaching: Post 1

Posted: November 2, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , , , , , , , , | Leave a comment

I’m back on the road for intensive teaching mode again and, as always, the challenge lies in delivering 16 hours of content in a way that will stick and that will allow the students to develop and apply their understanding of the core knowledge. Make no mistake, these are keen students who have committed to being here, but it’s both warm and humid where I am and, after a long weekend of working, we’re all going to be a bit punch-drunk by Sunday.

That’s why there is going to be a heap of collaborative working, questioning, voting, discussion. That’s why there are going to be collaborative discussions of connecting machines and security. Computer Networking is a strange beast at the best of times because it’s often presented as a set of competing models and protocols, with very few actual axioms beyond “never early adopt anything because of a vendor promise” and “the only way to merge two standards is by developing another standard. Now you have three standards.”

There is a lot of serious Computer Science lurking in networking. Algorithmic efficiency is regularly considered in things like routing convergence and the nature of distributed routing protocols. Proofs of correctness abound (or at least are known about) in a variety of protocols that , every day, keep the Internet humming despite all of the dumb things that humans do. It’s good that it keeps going because the Internet is important. You, as a connected being, are probably smarter than you, disconnected. A great reach for your connectivity is almost always a good thing. (Nyancat and hate groups notwithstanding. Libraries have always contained strange and unpleasant things.)

“If I have seen further, it is by standing on the shoulders of giants” (Newton, quoting Bernard of Chartres) – the Internet brings the giants to you at a speed and a range that dwarfs anything we have achieved previously in terms of knowledge sharing. It’s not just about the connections, of course, because we are also interested in how we connect, to whom we connect and who can read what we’re sharing.

There’s a vast amount of effort going into making the networks more secure and, before you think “Great, encrypted cat pictures”, let me reassure you that every single thing that comes out of your computer could, right now, be secretly and invisibly rerouted to a malicious third party and you would never, ever know unless you were keeping a really close eye (including historical records) on your connection latency. I have colleagues who are striving to make sure that we have security protocols that will make it harder for any country to accidentally divert all of the world’s traffic through itself. That will stop one typing error on a line somewhere from bringing down the US network.

“The network” is amazing. It’s empowering. It is changing the way that people think and live, mostly for the better in my opinion. It is harder to ignore the rest of the world or the people who are not like you, when you can see them, talk to them and hear their stories all day, every day. The Internet is a small but exploding universe of the products of people and, increasingly, the products of the products of people.

This is one of the representations of what the Internet looks like, graphically.

Computer Networking is really, really important for us in the 21st Century. Regrettably, the basics can be a bit dull, which is why I’m looking to restructure this course to look at interesting problems, which drives the need for comprehensive solutions. In the classroom, we talk about protocols and can experiment with them, but even when we have full labs to practise this, we don’t see the cosmos above, we see the reality below.

Maybe a green light will come on!

Nobody is interested in the compaction issues of mud until they need to build a bridge or a road. That’s actually very sensible because we can’t know everything – even Sherlock Holmes had his blind spots because he had to focus on what he considered to be important. If I give the students good reasons, a grand framing, a grand challenge if you will, then all of the clicking, prodding, thinking and protocol examination suddenly has a purpose. If I get it really right, then I’ll have difficulty getting them out of the classroom on Sunday afternoon.

Fingers crossed!

(Who am I kidding? My fingers have an in-built crossover!)

A Late Post On Deadlines, Amusingly Enough

Posted: November 1, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , , , , , , , | 1 Comment

Currently still under a big cloud at the moment but I’m still teaching at Singapore on the weekend so I’m typing this at the airport. All of my careful plans to have items in the queue have been undermined by having a long enough protracted spell of illness (to be precise, I’m working at about half speed due to migraine or migraine-level painkillers). I have very good parts of the day where I teach and carry out all of the face-to-face things I need to do, but it drains me terribly and leaves me with no ‘extra’ time and it was the extra time I was using to do this. I’m confident that I will teach well over this weekend, I wouldn’t be going otherwise, but it will be a blur in the hotel room outside of those teaching hours.

This brings me back to the subject of deadlines. I’ve now been talking about my time banking and elastic time management ideas to a lot of people and I’ve got quite polished in my responses to the same set of questions. Let me distill them for you, as they have relevance to where I am at the moment:

  1. Not all deadlines can be made flexible.

    I completely agree. We have to grant degrees, finalise resource allocations and so on. Banking time is about teaching time management and the deadline is the obvious focal point, but some deadlines cannot be missed. This leads me to…

  2. We have deadlines in industry that are fixed! Immutable! Miss it and you miss out! Why should I grant students flexible deadlines?

    Because not all of your deadlines are immutable, in the same way that not all are flexible. The serious high-level government grants? The once in a lifetime opportunities to sell product X to company YYPL? Yes, they’re fixed. But to meet these fixed deadlines, we move those other deadlines that we can. We shift off other things. We work weekends. We stay up late. We delay reading something. When we learn how to manage our deadlines so that we can make time for those that are both important and immovable, we do so by managing our resources to shift other deadlines around.

    Elastic time management recognises that life is full of management decisions, not mindless compliance. Pretending that some tiny assignment of pre-packaged questions we’ve been using for 10 years is the most important thing in an 18 year old’s life is not really very honest. But we do know that the students will do things if they are important and we provide enough information that they realise this!

I have had to shift a lot of deadlines to make sure that I am ready to teach for this weekend. On top of that I’ve been writing a paper that is due on the 17th of November, as well as working on many other things. How did I manage this? I quickly looked across my existing resources (and remember I’m at half-speed, so I’ve had to schedule half my usual load) and broke things down into: things that had to happen before this teaching trip, and things that could happen after. I then looked at the first list and did some serious re-arrangement. Let’s look at some of these individually.

Blog posts, which are usually prepared 1-2 days in advance, are now written on the day. My commitment to my blog is important. I think it is valuable but, and this is key, no-one else depends upon it. The blog is now allocated after everything else, which is why I had my lunch before writing this. I will still meet my requirement to post every day but it may show up some hours after my usual slot.

I haven’t been sleeping enough, which is one of the reasons that I’m in such a bad way at the moment. All of my deadlines now have to work around me getting into bed by 10pm and not getting out before 6:15am. I cannot lose any more efficiency so I have to commit serious time to rest. I have also built in some sitting around time to make sure that I’m getting some mental relaxation.

I’ve cut down my meeting allocations to 30 minutes, where possible, and combined them where I can. I’ve said ‘no’ to some meetings to allow me time to do the important ones.

I’ve pushed off certain organisational problems by doing a small amount now and then handing them to someone to look after while I’m in Singapore. I’ve sketched out key plans that I need to look at and started discussions that will carry on over the next few days but show progress is being made.

I’ve printed out some key reading for plane trips, hotel sitting and the waiting time in airports.

Finally, I’ve allocated a lot of time to get ready for teaching and I have an entire day of focus, testing and preparation on top of all of the other preparation I’ve done.

What has happened to all of the deadlines in my life? Those that couldn’t be moved, or shouldn’t be moved, have stayed where they are and the rest have all been shifted around, with the active involvement of other participants, to allow me room to do this. That is what happens in the world. Very few people have a world that is all fixed deadline and, if they do, it’s often at the expense of the invisible deadlines in their family space and real life.

I did not learn how to do this by somebody insisting that everything was equally important and that all of their work requirements trumped my life. I am learning to manage my time maturely by thinking about my time as a whole, by thinking about all of my commitments and then working out how to do it all, and to do it well. I think it’s fair to say that I learned nothing about time management from the way that my assignments were given to me but I did learn a great deal from people who talked to me about their processes, how they managed it all and through an acceptance of this as a complex problem that can be dealt with, with practice and thought.

 

Another semester over – what have I learned?

Posted: October 29, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , | Leave a comment

Monday the 29th marks the last official teaching activities, barring the exam and associated marking, for my grand challenges in Computer Science course. It’s been a very busy time and I’ve worked very hard on it but my students have worked even harder. Their final projects are certainly up where I wanted them to be and I believe that the majority of the course has gone well.

However, I’m running some feedback activities this week and I’ll find out how I can make it better for next year. At this stage we look like we’re going to have a reasonably large group for next year’s intake – somewhere in the region of 10-20 – and this is going to change how I run the course. Certain things just won’t work at that scale unless I start to take better advantage of group structure. I’ve already learnt a lot about how hard it is to connect students and data and, in our last meeting, I commented that I was thinking about making more data available in advance. Well, maybe, was the reply from students but we learned so much about how the data in the world is actually stored and treated.

Hmm. Back to the drawing board maybe – but also I’m going to wait for all of the final feedback.

Do I have students who I would happily put out in front of a class to run it for a while, doubly so for a community involvement project, with the confidence that they’ll communicate confidently, competently and with passion? Well, yes, actually – although there’ll be a small range. (And now I’ve just made at least three people paranoid – that’s what you get for reading my blog.)

There is so much going on that the next two months are going to be pretty frantic. Next year is already shaping up to be a real make-or-break year for my career and that means I need to sit down with a list of things that I want to achieve and a list of things that I am and am not prepared to do in order to achieve things. The achievement list is going to be a while coming, as goal lists always are, but the will/won’t/want list is forming. Here’s a rough draft.

  1. I still want to teach and be pretty involved in teaching. That’s easy as I’m not senior or research-loaded enough to get out of teaching. (I don’t really have a choice.
  2. I need to have more time to work on my non-work projects. I’ve just spent all of a Sunday working and the only reason I stopped was that I couldn’t spell constructivist reliably any more. (Yes, that just took three tries.)
  3. I want to have enough time to spend time with my students and not looked rushed or feel guilty about the time.
  4. I want to have the time to be able to help out any colleagues who could use my assistance AND I want to have the time to be able to seek help from my colleagues!
  5. I don’t want to take on anything that I have to give up on, or push to the sidelines for next year.

So, obviously, it all boils down to time, planning and allocation of priorities. With that in mind, I’ll wish you a happy Monday or good weekend. I’m going to have some dinner.

I am a potato – heading towards caramelisation. (Programming Language Threshold Concepts Part II)

Posted: October 28, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , , , , | Leave a comment

Following up on yesterday’s discussion of some of the chapters in “Threshold Concepts Within the Disciplines”, I finished by talking about Flanagan and Smith’s thoughts on the linguistic issues in learning computer programming. This led me to the theory of markedness, a useful way to think about some of the syntactic structures that we see in computer programs. Let me introduce the concept of markedness with an example. Consider the pair of opposing concepts big/small. If you ask how ‘big’ something is, then you’re not actually assuming that the thing you’re asking about is ‘big’, you’re asking about its size. However, ask someone how ‘small’ something is and there’s a presumption that it’s actually small (most of the time). The same thing happens for old/young. Asking someone how old they are, bad jokes aside, is not implying that they are old – the word “old” here is standing in for the concept of age. This is an example of markedness in the relationship between lexical opposites: the assumed meaning (the default) is referred to as the unmarked form, where the marked form is more restrictive (in that it doesn’t subsume both concepts) and it is generally not the default. You see this in gender and plural forms too. In Lions/LionessesLions is an unmarked form because it’s the default and it doesn’t exclude the Lionesses, whereas Lionesses would not be the general form used (for whatever reasons, good or bad) and excludes the male lions.

Why is this important for programming languages? Because we often have syntactic elements (the structures and the tokens that we type) that take the form of opposing concepts where one is the default, and hence unmarked, form. Many modern languages employ object-oriented programming practices (itself a threshold concept) that allow programmers to specify how the data that they define inside their programs is going to be used, even within that program. These practices include the ability to set access controls, that strictly define how you can use your code, how other pieces of code that you write can use your code, and how other people’s code can use it, as well. The fundamental access control pairs are public and private, one of which says anyone can use this piece of code to calculate things or can change this value, the other restricts such use or change to the owner. In the Java programming language, public dominates, by far, and can be considered unmarked. Private, however, changes the way that you can work with your own code and it’s easy for students to get this wrong.  (To make it more confusing, there is another type of access control that sits effectively between public and private, which is an even more cognitively complex concept and is probably the least well understood of the lot!) One of the issues with any programming language is that deviating from the default requires you to understand what you are doing because you are having to type more, think more and understand more of the implications of your actions.

However, it gets harder, because we sometimes have marked/unmarked pairs where the unmarked element is completely invisible. If we didn’t have the need to describe how people could use our code then we wouldn’t need the access modifiers – the absence of public, private or protected wouldn’t signify anything. There are some implicit modes of operation in programming languages that can be overridden with keywords but the introduction of these keywords just doesn’t illustrate a positive/negative asymmetry (as with big/small or private/public), these illustrate an asymmetry between “something” and “nothing”. Now, the presence of a specific and marked keyword makes it glaringly obvious that there has been an invisible assumption sitting in that spot the whole time.

One of these troublesome word/nothing pairs is found in several languages and consists of the keyword static, with no matching keyword. What do you think the opposite (and pair) of static is? If you’re like most humans, you’d think dynamic. However, not only is this not what this keyword actually means but there is no dynamic keyword that balances it. Let’s look at this in Java:

public static void main(String [] args) {...}
public static int numberOfObjects(int theFirst) {...}
public int getValues() {...}

You’ll see that static keyword twice.Where static isn’t used, however, there’s nothing at all, and this (by its absence) also has a definite meaning and this defines what the default expectation is of behaviour in the Java programming language. From a teaching perspective, this means that we now have a default context, with a separation between those tokens and concepts that are marked and unmarked, and it becomes easier to see why students will struggle with instance methods and fields (which is what we call things without static) if we start with static, and struggle with the concept of static if we start the other way around! What further complicates is this is that every single program we write must contain at least one static method, because it is the starting point for the program’s execution. Even if you don’t want to talk about static yet, you must use it anyway (unless you want to provide the students with some skeleton code or a harness that removes this – but now we’ve put the wizard behind the curtain even more).

One other point I found very interesting in Flanagan and Smith’s chapter was the discussion of barriers and traps in programming languages, from Thimbleby’s critique of Java (1999). Barriers are the limitations on expressiveness that mean that what you want to say in a programming language can only be said in a certain way or in a certain place – which limits how we can explain the language and therefore affects learnability. As students tend to write their lines of code as and when they think of them, at least initially, these barriers will lead the students to make errors because they haven’t developed the locally valid computational idiom. I could ask for food in German as “please two pieces ham thick tasty” and, while I’ll get some looks, I’ll also get ham. Students hitting a barrier get confusing error messages that are given back to them at a time when they barely have enough framework to understand what these messages mean, let alone how to fix them. No ham for them!

THIS IS AN IMPORTANT QUESTION!

Traps are unknown and unexpected problems, such as those caused by not using the right way to compare two things in a program. In short, it is possible in many programming languages to ask “does this equal that” and return an answer of true or false that does not depend upon the values of this or that, but where they are being stored in memory. This is a trap. It is confusing for the novice to try to work out why the program is telling her that two containers that have the value “3” in them are not the same because they are duplicates rather than aliases for the same entity. These traps can seriously trip someone up as they attempt to form a correct mental model and, in the worst case, can lead to magical or cargo-cult thinking once again. (This is not helped by languages that, despite saying that they will take such-and-such an action, take actions that further undermine consistent mental models without being obvious about it. Sekrit Java String munging, I’m looking at you.)

This way of thinking about languages is of great interest to me because, instead of talking about usability in an abstract sense, we are now discussing concrete benefits and deficiencies in the language. Is it heavily restrictive on what goes where, such as Pascal’s pre-declaration of variables or Java’s package import restrictions? Does the language have a large number on unbalanced marked/unmarked pairs where one of them is invisible and possibly counterintuitive, such as static? Is it easy to turn a simple English statement into a programmatic equivalent that does not do what was expected?

The authors suggested ways to dealing with this, including teaching students about formal grammars for programming languages – effectively treating this as learning a new language because the grammar, syntax and semantics are very, very different from English.(Suggestions included Wittgenstein’s Sprachspiel, language game, which will be a post for another time.) Another approach is to start from logic and then work forwards, turning this into forms that will then match the programming languages and giving us a Rosetta stone between English speakers and program speakers.

I have found the whole book very interesting so far and, obviously, so too this chapter. Identifying the problems and their locations, regrettably, is only the starting point. Now I have to think about ways to overcome this, building on what these and other authors have already written.

Imagine that you are a raw potato…

Posted: October 27, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , | Leave a comment

Tuber or not tuber.

The words in the title of this post, surprisingly, are the first words in the Editors’ Preface to Land, Meyer and Smiths 2008 edited book “Threshold Concepts within the Disciplines”. Our group has been looking at the penetration of certain ideas through the discipline, examining how much the theory social constructivism accompanies the practice of group work for example, or, as in this case, seeing how many people identify threshold concepts in what they are trying to teach. Everyone who teaches first year Computer Science knows that some ideas seem to be sticking points and Meyer and Land’s two papers on “Threshold Concepts and Troublesome Knowledge” (2003 and 2005) provide a way of describing these sticking points by characterising why these particular aspects are hard – but also by identifying the benefits when someone actually gets it.

Threshold concept theory, in the words of Cousin, identifies the “the kind of complicated learner transitions learners undergo” and identifies portals that change the way that you think about a given discipline. This is deeply related to our goal of “Thinking as a discipline practitioner” because we must assume that a sound practitioner has passed through these portals and has transformed the way that they think in order to be able to practice correctly. Put simply, being a mathematician is more than plugging numbers into formulae.

As you can read, and I’ve mentioned in a previous post, threshold concepts are transformative, integrative, irreversible and (unfortunately) troublesome. Once you have passed through the hurdle then a new vista opens up before you but, my goodness, sometimes that’s a steep hurdle and, unsurprisingly, this is where many students fall.

The potato example in the preface describes the irreversible chemical process of cooking and how the way that we can use the potato changes at each stage. Potatoes, thankfully unaware, have no idea of what is going on nor can they oscillate on their pathway to transformation. Students, especially in the presence of the challenging, can and do oscillate on their transformational road. Anyone who teaches has seen this where we make great strides on one day and, the next, some of the progress ebbs away because a student has fallen back to a previous way of thinking. However, once we have really got the new concept to stick, then we can move forward on the basis of the new knowledge.

Threshold concepts can also be thought of as marking the boundary of areas within a discipline and, in this regard, have special interest to teachers and learners alike. Being able to subdivide knowledge into smaller sections to develop mastery that then allows further development makes the learning process easier to stage and scaffold. However, the looming and alien nature of the portal between sections introduces a range of problems that will apply to many of our students, so we have to ready to assist at these key points.

The book then provides a collection of chapters that discuss how these threshold concepts manifest inside different disciplines and in what forms the alien and troublesome nature can appear. It’s unsurprising again, for anyone teaching Computer Science or programming, that there are a large number of fundamental concepts in programming that are considered threshold concepts. These include the notion of program state, the collection of data that describes the information within a program. While state is an everyday concept (the light is on, the lift is on level 4), the concentration on state, the limitations and implications of manipulation and the new context raise this banal and everyday concepts into the threshold area. A large number of students can happily tell you which floor the lift is on, but cannot associate this physical state with the corresponding programmatic state in their own code.

Until students master some of these concepts, their questions will always appear facile, potentially ill-formed and (regrettably) may be interpreted as lazy. Flanagan and Smith raise an interesting point in that programming languages, which are written in pseudo-English with a precise but alien grammar, may be leading a linguistic problem, where the translation to a comprehensible form is one of the first threshold concepts that a student faces. As an example, consider this simple English set of instructions:

There are 10 apples in the basket.
Take each apple out of the basket, polish it, and place it in the sink.

Now let’s look at what the ‘take each apple’ instruction looks like in the C programming language.

for (int i  = 0; i < numberOfApples; i++) {
  // commands here
}

This is second nature to me to read but a number of you have just looked at that and gone ‘huh’? If you don’t learn what each piece does, understand its importance and can then actually produce it when asked then the risk is that you will just reproduce this template whenever I ask you to count apples. However, there are two situations that humans understand readily: “do something so many times” and “do something UNTIL something happens”. In programs we write these two cases differently – but it’s a linguistic distinction that, from Flanagan and Smith’s work “From Playing to Understanding”, correlates quite well with an ability to pick the more appropriate way of writing the program. If the language itself is the threshold, and for some students it certainly appears that it is, then we are not even able to assume that the students will reach the first stage of ‘local thresholds’ found within the subdomain itself, they are stuck on the outside reading a menu in a foreign language trying to work out if it says “this way to the toilet”.

Such linguistic thresholds will make students appear very, very slow and this is a problem. If you ask a student a question and the words make no sense in the way that you’re presenting them, then they will either not respond (if they have a choice) as they don’t know what you asked, they will answer a different question (by taking a stab at the meaning) or they will ask you what you mean. If someone asks you what you mean when, to you, the problem is very simple, we run the risk of throwing up a barrier between teacher and learner, the teacher assuming that the learner is stupid or lazy, the student assuming that the teacher either doesn’t know what they’re saying or doesn’t care about them.

I’ll write more on the implications of all of this tomorrow.

Recursive Tutorial: A tutorial on writing a tutorial

Posted: October 24, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , , | Leave a comment

I assigned the Grand Challenge students a slightly strange problem for yesterday’s tutorial: “How would you write an R tutorial for Year 11 High School Students?” R is an open source statistics package that is incredibly powerful and versatile but it is nowhere near as friendly to use or accessible as traditional GUI tools such as Microsoft Excel. R has some menus and buttons on it but most of these are used to control the environment, rather than applying the statistical and mathematical functions. R Studio is an associated Integrated Development Environment (IDE) that makes working with R easier but, at its core, R relies upon you knowing enough R to type the right commands.

Discussing this with students, we compared Excel and R to find out what the core differences were and some of them are not important early on but become more important later. Excel, for example, allows you to quickly paste and move around data, apply some functions, draw some graphs and come to a result quickly, mostly by pushing buttons and using on-line help with a little typing. But, and it’s an important but, unless you write a program in Excel (and not that many people do), re-applying all of that manipulation to a new data source requires you to click and push and move across the screen all over again. You have to recreate a long and complicated combination of mechanical and cognitive functions. R, by contrast, requires you to type commands to get things to happen but it remembers them by default and you can easily extract them. Because of how R works, you drag in data (from a file, say) and then execute a set of manipulation steps. If you’re familiar with R then this is straight-forward. If not, then steep learning curve. However, re-using these instructions and manipulations on a new data source is trivial. You change the file and re-run all of the steps.

Why am I talking about new data sources? Because it’s often the case that you want to do the same thing with new data OR you realise that the data you were working with was incomplete or in error. Unless you write a lot of Visual Basic in Excel (and that no longer works on Macs so it’s not a transferable option), your Excel spreadsheet with changed data requires you to potentially reapply or check the application of everything in the spreadsheet, especially if there is any sorting of data, creation of new columns or summary data – and let’s not even start talking about pivot tables! But, for single run, for finance, for counting stuff, Excel is almost always going to be more easy to teach people to use than R. For scientists, however, R is better to use for two very important reasons: it is less likely to do something that is irreversible to your data and the vast majority of its default choices are sensible.

The students came up with a list of things that Excel does (good and bad): it’s strongly visual, lay-user friendly, tells you what you can do, does what it damn well wants to, data changes may require manual reapplication. There’s a corresponding list for R: steep learning curve, visual display for R environment but command-line interface for commands, does what you tell it to do (except when it’s too smart). I surveyed the class to find out who was using R rather than Excel and the majority of students were using R for their analysis but, and again it’s an important but, only because they had to. In situations where Excel was enough (simple manipulation, straight forward analysis), then Excel got used because Excel is far easier to use and far friendlier.

The big question for the students was “How do I start doing something?” In Excel, you type numbers into the spreadsheet and then can just start selecting things using a relatively good on-line help system. In R you are faced with a blinking prompt and you have to know enough to type streams of commands like this:

newtab <-read.csv("~/days.txt",header=FALSE)
plot(seq(1,nrow(newtab)),newtab$V1) 
boxplot(newtab) 
abline(a=1500,b=0) 
mean(newtab)

And, with a whole set of other commands, you can get graphs like this. (I realise that this is not a box plot!)

Once you’re used to it, this is meaningful, powerful and re-applicable. I can update the data and re-run this to my heart’s content, analysing vast quantities of data without having to keep mouse clicking into cells. But let’s remember our context. I’m not talking about higher education students, I’m talking about school students and it’s important to remember that teaching people something before they’re ready to use it or before they have an opportunity to use it is potentially not the best use of effort.

My students pointed out that the school students of today are all learning how to use graphing calculators, with giant user manuals, and (in some cases) the students switch on their calculators to see a menu rather than the traditional calculator single line. But the syntax and input modes for calculators vary widely. Some use ( ) for operations like sin, so a student will see sin(30) when they start doing trig, whereas some don’t. This means that some of the students I might want to teach R to have not necessarily got their head around the fact that functions exist, except as something that Excel requires them to do. Let’s go to the why here, because it’s important. Why are students learning how to use these graphing calculators? So they can pass their exams, where the competent and efficient use of these things will help them. Yes, it appears that students may be carrying out the kind of operations I would like them to put into a more powerful tool, but why should they?

If a teach a high school student about Excel then there are many places that they might use this kind of software: micro-budgeting, keeping track of things, the ‘simple’ approximation of a database storing books or things like that. However, the general practice of using Excel is familiarisation with a GUI interface that is very, very common and that most students need experience with. If I teach them R then I might be extending their knowledge but (a) the majority are probably not yet ready for it and (b) they are highly unlikely to need to use it for anything in the near future.

The conclusion that my students reached was that, if we really wanted to provide exposure to an industry-like scientific or engineering tool at the earlier stage, then why not use one that was friendlier, more helpful but still had a more scientific focus. They suggested Matlab (as a number of them had been exposed) or Mathematica. Now this whole exercise was designed to get them to practice their thinking about outreach, community, communication and sharing knowledge, so I wasn’t ever actually planning to run an R tutorial at Year 11. But these students thought through and asked the very important questions:

  • Who is this aimed at?
  • What do they already know?
  • What do they need to know?
  • Why are we doing this?

Of course, I have also learned a great deal from this as well – I had no idea that the calculators had quite got to this point, nor that there were schools were students would have to select through a graphical menu to get to the simple “3+3 EXE” section of the calculator! Don’t tell my Grand Challenge students but I think I’m learning roughly as much as they are!

Students and Programming: A stroll through the archives in the contemplation of self-regulation.

Posted: October 23, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , | Leave a comment

I’ve been digging back into the foundations of Computer Science Education to develop some more breadth in the area and trying to fill in some of the reading holes that have developed as I’ve chased certain ideas forward. I’ve been looking at Maye’s “Psychology of How Novices Learn Computer Programming” from 1981, following it forward to a number of papers including McCracken (Chair) et al’s “A multi-national, multi-institutional study of assessment of programming skills of first-year CS students”. Among the many interesting items presented in this paper was a measure of Degree of Closeness (DoC): a quantification of how close the student had come to providing a correct solution, assessed on their source code. The DoC is rated on a five-point scale, with 1 being the furthest from a correct solution. These “DoC 1” students are of a great deal of interest to me because they include those students who submitted nothing – possible evidence of disengagement or just the student being overwhelmed. In fact the DoC 1 students were classified into three types:

  • Type 1: The student handed up an empty file.
  • Type 2: The student’s work showed no evidence of a plan.
  • Type 3: The student appeared to have a plan but didn’t carry it out.

Why did the students do something without a plan? The authors hypothesise that the student may have been following a heuristic approach, doing what they could, until they could go no further. Type 3 was further subdivided into 3a (the student had a good plan or structure) and 3b (the student had a poor plan or structure). All of these, however, have one thing in common and that is that they can indicate a lack of resource organisation, which may be identified as a shortfall in metacognition. On reflection, however, many of these students blamed external factors for their problems. The Type 1 students blamed the time that they had to undertake the task, the lab machines, their lack of familiarity with the language. The DoC 5 students (from the same school) described their difficulties in terms of the process of creating a solution. Other comments from DoC 1 and 2 students included information such as insufficient time, students “not being good” at whatever this question was asking and, in one case, “Too cold environment, problem was too hard.” The most frequent complaint among the low performing students was that they had not had enough time, the presumption being that, had enough time been available, a solution was possible. Combine this with the students who handed up nothing or had no plan and we must start to question this assertion. (It is worth noting that some low-performing students had taken this test as their first ever solo lab-based examination so we cannot just dismiss all of these comments!)

The paper discusses a lot more and is rather critical of its own procedure (perhaps the time pressure was too high, the specifications a little cluttered, highly procedural rather than OO) and I would not argue with the authors on any of this but, from my perspective, I am zooming in on the issue of time because, if you’ve read any of my stuff before, you’ll know that I am working in self-regulation and time management. I look at the Types of DoC 1 students and I can see exactly what I saw in my own student timeliness data and reflection reports: a lack of ability to organise resources. This is now, apparently, combined with a persistent belief that fixing this was beyond the student’s control. It’s unsurprising that handing up nothing suddenly became a valid option.

The null submission could be a clear indicator of organisational ability, where the student can’t muster any kind of solution to the problem at all. Not one line of code or approximate solution. What is puzzling about this is that the activity was, in fact, heavily scheduled. Students sat in a lab and undertook it. There was no other task for them to perform except to do this code in either 1 or 1.5 hours. To not do anything at all may be a reaction to time pressure (as the authors raised) or it could be complete ignorance of how to solve the problem. There’s too much uncertainty here for me to say much more about this.

The “no plan” solution can likely be explained by the heuristic focus and I’ve certainly seen evidence of it. One of the most unforgiving aspects of the heuristic solution is that, without a design, it is easy to end up in a place where you are running out of time and have no idea of where to go to solve unforeseen problems that have arisen. These students are the ones who I would expect to start the last day that something is due and throw together a solution, working later and panicking more as they realised that their code wasn’t working. Having done a bit here and a piece there, they may cobble something together and hand it up but it is unlikely to work and is never robust.

The “I planned it but I couldn’t do it” group fall heavily into the problem space of self-regulation, because they had managed to organise their resources – so why didn’t anything come out? Did they procrastinate? Was their meta-planning process deficient, in that they spent most of their time perfecting a plan and not leaving enough time to make it happen? I have a number of students who have a tendency to go down the rabbit hole when chasing design issues and I sometimes have to reach down, grab them by the ears and haul them out. The reality of time constraints is that you have to work out what you can do and then do as much as you can with that time.

This is fascinating because I’m really trying to work out at which point students will give up and DoC 1 basically amounts to an “I didn’t manage it” mark in my local system. I have data that shows the marks students get from automated marking (immediate assessment) so I can look to see how long people will try to get above what (effectively) would be above DoC 1, and probably up around DoC 3. (The paper defines DoC 3 as “In reading the source code, the outline of a viable solution was apparent, including meaningful comments, stub code, or a good start on the code.” This would be enough to meet our assessment requirements although the mark wouldn’t be great.) DoC 1 would, I suspect, amount to “no submission” in many cases so my DoC 1 students are those who stayed enrolled (and sat the exam) but never created a repository or submission. (There are so many degrees of disengagement!)

I, of course, now have to move further forward along this paper line and I will hopefully intersect with my ‘contemporary’ reading into student programming activity. I will be reading pretty solidly on all of this for the upcoming months as we try to refine the time management and self-regulation strategies that we’ll be employing next year.

Sources of Knowledge: Stickiness and the Chasm Between Theory and Practice.

Posted: October 21, 2012 | Author: | Filed under: Education | Tags: , , , , , , , , , , , , , , , , | Leave a comment

Like all sources, it helps to know the origin and the purity.

My head is still full of my current crop of research papers and, while I can’t go into details, I can discuss something that I’m noticing more and more as I read into the area of Computer Science Education. Firstly, how much I have left to learn and, secondly, how difficult it is sometimes to track down ideas and establish novelty, provenance and worth. I read Mark Guzdial’s blog a lot because Mark has spent a lot of time being very clever in this area (Sorry, Mark, it’s true) but he is also an excellent connecter of the reader to good sources of information, as well as reminding us when something pops up that is effectively a rehash of an old idea. This level of knowledge and ability to discuss ideas is handy when we keep seeing some of the same old ideas pop up, from one source or another, over time. I’ve spoken before about how the development of the mass-accessible library didn’t end the importance of the University or school, and Mark makes a similar note in a recent post on MOOCs when he points us to an article on mail delivery lessons from a hundred years before and how this didn’t lead to the dissolution of the education system. Face-to-face continues to be important, as do bricks and mortar, so while the MOOC is a fascinating new tool and methodology with great promise, the predicted demise of the school and college may (once again) turn out to be premature.

If you’ve read Malcolm Gladwell’s “The Tipping Point”, you’ll be familiar with the notion that ideas need to have certain characteristics, and certain human agents, before they become truly persuasive and widely adopted. If you’ve read Dawkin’s “Selfish Gene” (published over a decade before) then you’ll understand that Gladwell’s book would be stronger if it recognised a debt to Dawkins’ coining of the term meme, for self-replicating beliefs and behaviours. Gladwell’s book, as a source, is a fairly unscientific restatement of some existing ideas with a useful narrative structure, despite depending on some now questionable case studies. In many ways, it is an example of itself because Gladwell turned existing published information into a form where, with his own additions, he has identified a useful way to discuss certain systems of behaviour. Better still, people do (still) read it.

(A quick use of Google Trends shows me that people search for “The Tipping Point” roughly twice as much as “The Selfish Gene” but for “Richard Dawkins” twice as much as “Malcolm Gladwell”. Given Dawkins’ very high profile in belligerent atheism, this is not overly surprising.)

Gladwell identified the following three rules of epidemics (in terms of the spread of ideas):

  1. The Law of the Few: There are a small group of people who make a big difference to the proliferation of an idea. The mavens accumulate knowledge and know a lot about the area. The connectors are the gregarious and sociable people who know a lot of other people and, in Gladwell’s words, “have a gift for bringing the word together”. The final type of people are salespeople or (more palatably) persuaders, the people who convince us that something is a good idea. Gladwell’s thesis is that it is not just about the message, but that the messenger matters.
  2. The Stickiness Factor: Ideas have to be memorable in order to spread effectively so there is something about the specific content of the message that will determine its impact. Content matters.
  3. The Power of Context: We are all heavily influenced by and sensitive to our environment. Context matters.

Dawkins’ meme is a very sticky idea and, while there’s a lot of discussion about the Selfish Gene, we now have the field of memetics and the fact that the word ‘meme’ is used (almost correctly) thousands, if not millions, of times a day. Every time that you’ve seen a prawn running on a treadmill while Yakity Sax plays, you can think of Richard Dawkins and thank him for giving you a word to describe this.

My early impressions of some of the problem with the representation of earlier ideas in CS Ed, as if they are new, makes me wonder if there is a fundamental problem with the stickiness of some of these ideas. I would argue that the most successful educational researchers, and I’ve had the privilege to see some of them, are in fact strong combinations of Gladwell’s few. Academics must be, by definition, mavens, information specialists in our domains. We must be able to reach out to our communities and spread our knowledge – is this enough for us to be called connectors? We have to survive peer review, formal discussions and criticism and we have to be able to argue our ideas, on the reasonable understanding that it is our ideas and not ourselves that is potentially at fault. Does this also make us persuaders? If we can find all of these “few” in our community, and we already a community of the few, where does it leave us in terms of explaining why we, in at least some areas, keep rehashing the same old ideas. Do we fail to appreciate the context of those colleagues we seek to reach or are our ideas just not sticky enough? (Context is crucial here, in my opinion, because it is very easy to to explain a new idea in a way that effectively says “You’ve been doing it wrong all these years. Now fix it or you’re a bad person.” This is going to create a hostile environment. Once again, context matters but this time it is in terms of establishing context.)

I wonder if this is compounded in Computer Science by the ability to separate theory from practice, and to draw in new practice from both an educational research focus and an industrial focus? To explain why teamwork actually works, we move into social constructivism and to Vygotsky, via Ben-Ari in many cases, Bandura, cognitive apprenticeship – that’s an educational research focus. To say that teamwork works, because we’ve got some good results from industry and we’re supported by figures such as Brooks, Boehm and Humphrey and their case studies in large-scale development – that’s an industrial focus. The practice of teamwork is sticky, that ship has sailed in software development, but does the stickiness of the practice transfer to the stickiness of the underlying why? The answer, I believe, is ‘no’ and I’m beginning to wonder if a very sticky “what” is actually acting against the stickiness of the “why”. Why ask “why?” when you know that it works? This seems to be a running together of the importance of stickiness and the environment of the CS Ed researcher as a theoretical educationalist, working in a field that has a strong industrial focus, with practitioner feedback and accreditation demands pushing a large stream of “what do to”.

It has been a thoughtful week and, once again, I admit my novice status here. Is this the real problem? If so, how can we fix it?

 

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