6.3 Root-mean-square amplitude One drawback of the amplitude as I have defined it is that although it allows the relative sizes of sine waves to be compared, it does not give a good idea of what a sine wave can deliver in absolute terms. For instance, a sine wave with an amplitude of 10 volts has twice the amplitude of one with an amplitude of 5 volts. But is a power source that delivers a sine wave with an amplitude of 10 volts as powerful as, say, a 10 volt battery? Could you use it to drive a bulb and get the same illum
4.2 Frequency, wavelength and the speed of sound The speed of sound has a joint relationship with both the wavelength and the frequency of the sound. To see why, recall that at the end of Section 2.5, in connection with the wave produced by a tuning fork, I said ‘in the time it has taken for the source to go through one cycle of oscillation, the wave h
5.9 Developing other systems methods There are many more methods that are regarded as systems approaches for managing complexity (e.g. Rosenhead, 1989a; Flood and Carson, 1988; Flood and Jackson, 1991; Mingers and Gill, 1997; Francois, 1997; Flood, 1999; Jackson, 2000). The systems practitioners responsible for developing these come from a varied background, but in the main their experiences are similar to those described for Checkland, Beer, Espejo and the T301 team. All wanted to be able either to take action that stakeholders
5.5 Experiences that motivated the development of systems methods I have already introduced various systems methods. Behind all of these methods, there has generally been a champion, a promoter aided by countless co-workers, students, etc. To paraphrase the French sociologist of technology, Bruno Latour: we are never confronted with a systems method, but with a gamut of weaker and stronger associations; thus understanding what a method is, is the same task as understanding who the people are. A method, like any social technology, depends on many peopl
4.2 Articulating your appreciation of complexity Initially, I would like you to notice whether and how your appreciation of the phrase ‘managing complexity’ has changed since you started the unit. As you work through Section 4 you will encounter a number of ways of thinking about complexity that may be new to you, so it becomes important to record your developing understanding. To help you with this, return to your notes on Author(s):
3.7 Being ethical As outlined in Table 3, ethics within systemic practice are perceived as operating on multiple levels. Like the systems concept of hierarchy, what we perceive to be good at one level might be bad at another. Because an epistemological position must be chosen, rather than taken as a g
7.1 Introduction The last activity was a demanding task. People I asked to do it during the writing of this unit, found it took a lot of concentration but it brought up lots of ideas, feelings and suggestions for action. Most of them were also concerned their rich picture might not be good enough. I imagine you will share some of these reactions. If you share any of these concerns, remember there are lots of ways of drawing a good rich picture and almost all rich pictures can be improved. Improving your rich
2.3 Taking responsibility for your own learning Not much of this unit conforms to the traditional pattern I mentioned earlier – the theory-example-exercise pattern. In particular, you will find you are expected to discover much of it for yourself. Why is this? This is a legitimate question and deserves a full answer. One year, a student at a residential summer school complained I had not taught him properly. I was, he told me, an expert and so why did I not demonstrate how to tackle the problem he was working on and pass my expertise on
18.2.2 Compatibility An innovation that is compatible with the experiences, values and needs of its potential buyers will be adopted more rapidly than one that isn't compatible. For example mobile phones have spread rapidly because they are compatible with social and cultural trends towards faster communications, increased personal mobility and the desirability of high-tech gadgets. However the car seat belt, patented in 1903, wasn't adopted on any significant scale until the 1970s (Author(s):
Introduction This unit aims to provide an understanding of invention, design, innovation and diffusion as ongoing processes with a range of factors affecting success at each stage. You will gain an understanding of the factors that motivate individuals and organisations to invent, and the creative process by which individuals come up with ideas for new inventions and designs, and you will gain an understanding of the obstacles that have to be overcome to bring an invention to market and the factors that i
Module team Andy Lane, course team chair and author (1999) Karen Shipp, course team chair (2002) Rosalind Armson, author and critical reader Jake Chapman, author Eion Farmer, author and critical reader John Hamwee, author John Martin, author Laurence Newman, course manager Wendy Fisher, author John Hudson, author Graham Paton, author Roberts, author Christine Bla
The T552 course team
Acknowledgements All materials included in this unit are derived from content originated at the Open University. Andy Capp cartoon: “The Boss wants us at the ground early” © Mirrorpix
1.3.1 Systems thinking and concept Much can be said about systems thinking. However it is worth reiterating some key points here as they are central to understanding the purpose of the diagrams discussed later in this section. The word system is one that is in regular everyday use. People talk, for example, about ‘the social security system’ and the ‘telephone system’. Gamblers boast about ‘having a system’ for winning at roulette. Young people talk about being ‘against the system’. The trouble with
1.2.8 Working with other people's diagrams – reading diagrams Reading diagrams is an equally useful skill to that of drawing diagrams. Not only does it help you understand what other people are trying to convey, it also helps you be critical of the diagrams you draw yourself. In some cases diagrams are used to make the text look pretty or appealing and do not add to the understanding of the reader (hopefully not the case with the diagrams here!). Even when they are used more effectively there is a need to be critical of what information is being conveye
12.1.1 Survey questionnaires Questionnaires are lists of questions that enable information to be gathered efficiently from a relatively large number of respondents. Most questionnaires require a fixed type of response, such as a choice between available answers, or along a scale of response. For example, a product design questionnaire might suggest, ‘I found the product easy to use’ and provide a five-point scale of response from ‘agree strongly’ to ‘disagree strongly’. Or a question might be, ‘how often do
9.1 User trip This section introduces a simple method of investigating product use. Even such simple methods can provide useful information to guide product redesign and new product development. The essential idea of user trips is simple: you just take a ‘trip’ through the whole process of using a particular product or system, making yourself a critical observant user. The only way to learn how to make these user trips is to try one or two for yourself. You will be surprised how much you fi
8.1.2 Feedback A second important principle is providing feedback to the user – for example, when you press a button it moves and clicks, or you hear some other sound or you see a light to indicate the action has been registered by the machine. Here's another short video clip from Phillip Joe at IDEO, this time on feedback. 5.1 Introduction Water for public supply can be obtained from underground sources by wells sunk into aquifers, or from surface sources such as purpose-built reservoirs or lakes (collecting rainwater run-off or water from streams) and rivers. The safety of the water is of utmost concern – several million people die each year after consuming contaminated water. The primary aim in water treatment is the elimination of any pathogenic micro-organisms present. All the above-mentioned sources can be subject to pol 2.5 Corrosion processes: galvanic series A similar concept to the electrochemical series that has been used by engineers for many years is the galvanic series (one example of which is shown in Table 2: here the list should be read down the columns rather than across the rows). It ranks metals and alloys in order of reactivity or 2.4 Corrosion processes: galvanic corrosion When two dissimilar metals are in contact, or in close proximity with a conducting fluid in between, an electrochemical cell can be formed that leads to the more reactive metal becoming an anode and the less reactive metal a cathode. This kind of corrosion is known as galvanic corrosion. It is not uncommon, since metals are often coated with others of different E0, and different metals are often in close contact with a common electrolyte. One of the earlie
