字幕列表 影片播放 列印英文字幕 The connection between philosophy and the mathematical sciences has always been very close. Plato had written over the door of his academy the words, "Let no one enter here who is ignorant of geometry." It was Aristotle who codified the basic sciences into the categories and gave them the names that we use to this day. Some of the greatest philosophers have been themselves great mathematicians who invented new branches of mathematics. Descartes is an obvious example, and so is Leibniz and Pascal. In fact, most of the great philosophers, not all but most, came to philosophy from mathematics or the sciences. And this tendency is continued into our present century. Bertrand Russell was trained first as a mathematician, Wittgenstein was trained first as an engineer. The reason for this persisting connection is, I think, obvious. And that is that the basic urge, which has driven most of the greatest philosophers, has been the urge to deepen our understanding of the world and of its structure. And this is also what creative scientists are doing. For most of the past, too, people thought that mathematics was the most indubitable knowledge, as well as being utterly precise and clear, that human beings possessed. So there have always been plenty of philosophers examining mathematics to try and find out what was so special about it, and whether this was something that could be applied to the acquisition of other sorts of knowledge. Ditto with the sciences, which were also thought to yield a very specially safe and certain kind of knowledge. What was it about science that made its results so reliable, people ask themselves. And could its methods, whatever these were, be used in other fields? These investigations into the concepts, and methods, and procedures, and models that are involved in mathematics and in science have come to be known as the philosophy of mathematics and the philosophy of science. And it's with these that we're going to be concerned in this program. Chiefly with the philosophy of science, though, in fact, we have someone taking part who is expert in both-- Professor Hilary Putnam of Harvard University Professor Putnam, I'd like to start our discussion from a standpoint which I think a very large number of our viewers occupy anyway. And it's really this-- since the 17th century, I suppose, there's been a spectacular decline in religious belief, especially in the West, and especially among educated people. And for millions, the role that used to be taken in life by a world view based on religion has been increasingly supplanting by a world view based on science or, at least, purporting to be derived from science, anyway. And this is still enormously powerful, and the hold that it has on people's minds throughout the West probably affects all of us. So I think I'd like to start this discussion by getting you to pin down that scientific world outlook which is so influential in the modern world and which will be underlying a lot of what we're going to have to talk about. Let me dodge the question a little bit by talking not about what scientists think now but what many scientists thought 100 years ago, or 75 years ago. Think of doing a crossword puzzle. You might have to change a few things as you go along. But towards the end everything fits, and things get added on one step at a time. That's the way the progress of science looked for 300 years. In 1900, a famous mathematician, David Hilbert, gave a list of 50 mathematical problems to a world congress of mathematicians, which are still very famous. And it's very interesting that he included one problem which we would not call a mathematical problem, very early in the list. I think it's problem three, which was to put the foundations of physics on a satisfactory basis. Just a small task. And that was for mathematicians. That was for mathematicians, not for physicists. The ideas-- Tidy it up. That's right. The ideas is, Newton, Maxwell, Dalton, and so on had all put in all the parts of the story. And now it was just for mathematicians to, basically, clean up the logic, as it were. I think, in a conversation we had a couple of days ago, you described this as a treasure chest to you. And I like that picture. Here's this big chest that we're just filling up. It's an accumulation, and you don't have to subtract, you don't have to take out. Occasionally you make a little mistake, but basically the idea is-- when you shift the metaphor, like building a pyramid. You put down the ground floor, then the next floor, then the next floor. It just goes up. That's part of it. The view of knowledge as growing by accumulation. The other part of it is the idea that the special success of the sciences-- and obviously what we're impressed by is success. This culture values success and science is a successful institution. But there is the idea that science owes its success to using a special method. And that comes probably from history of science. From the fact that Newton, for example, lived after Bacon, was influenced by Bacon. And the idea that empirical science has grown up together with something called inductive logic. And this idea that there's a method, the inductive method, and that the sciences can be characterized by the fact that they use this method and use it explicitly and consciously as it were-- not, unconsciously as maybe someone who's learning cooking might be using it. But pretty deliberately and explicitly. So I think that these two things-- the idea of knowledge as growing by accumulation and growing by the use of a special method, the inductive method, are the key elements of the old view. Yes and if I were going to put the same thing, I suppose, slightly differently I think I'd say this. For 200 or 300 years, educated Western man thought of the universe, and everything in it as consisting of matter in motion. And that was all there was, whether from the outermost galaxies of the stars into ourselves, and our bodies, and the cells of which we made up, and so on. And that science was finding out more and more about this matter, and its structure, and its motion by a method which you just characterized-- the scientific method. And the idea was that, if we went on long enough, we'd simply-- as you said we do a crossword puzzle metaphor-- we'd find out everything there was to fine out. We could, eventually, by scientific methods completely explain and understand the world. Now that has been abandoned by scientists, hasn't it, though in fact this hasn't got through yet to the non-scientists. There are still large numbers of non-scientists who go on thinking that that's how scientists think. But of course they no longer do, do they. I mean this is starting to break down. I think it's started to break down. I think it started to break down with Einstein. If I can drag in a bit of history of philosophy, screaming, by the hair-- Kant did something in philosophy which I think has begun to happen now in science. He challenged a certain view of truth. Before Kant, no philosopher really doubted that truth was simply correspondence to reality. I mean, there are different words, some philosophers spoke of agreement. But the idea is a mirror theory of knowledge. Today, I think-- well, Kant said it isn't so simple. There's a contribution of the thinking mind. Sure, it isn't made up by the mind. Kant was no idealist. It isn't all a fiction. It isn't something we make up. But it isn't just a copy, either. What we call truth depends both on what there is, on the way things are, and on the contribution of the thinker, the mind. I think that, today, scientists have come to a somewhat similar view. That since the beginning of the 20th century, the idea that there's a human contribution, a mental contribution, to what we call truth, that theories aren't simply dictated to us by the facts, as it were. I'd like to ask you to unpack that a little because I think that some of our viewers will find idea a little puzzling. "How can be," some people will ask themselves, that "what is and is not true can depend not only on what the facts are but on the human mind. How can that be." Well, let me use an analogy with vision. We tend to think that's what we see just depends on what's out there. But the more one studies vision, either as a scientist or as a painter, one discovers that what's called vision involves an enormous amount of interpretation. The color we see as red is not the same color, in terms of wavelengths, at different times of the day. So that even in what we think of as our simplest transaction with the world, just looking at it, we are interpreting. You know-- In other words we bring a whole number of things to the world that we're not directly conscious of, usually, unless we turn inwards and start examining them. That's right. I think the world must've looked different in the Middle Ages to someone who looked up and thought of the stars as up and us at the bottom, for example. Today, when we look out into space, I think we have a different experience than somebody with the medieval world view. And what you're saying is that the very categories in which we see the world and interpret our experience, and the ideas within which we organize our observations and the facts around us and such, are provided by us. So that the world as conceived by science is partly contributed by external facts but also partly contributed by categories and ways of seeing things which come from the human observer. That's right. And an example of that in science-- I'll oversimplify, but it's not basically falsified-- is this wave/particle business. It's not that there's something, an electron, which is somehow half a wave and half a particle-- that would be meaningless-- but that there are many experiments which can be described two ways. You can either think of the electron as a wave, or you can think of it as a particle. And both descriptions are, in some crazy way, true and adequate. They're alternative ways of describing the same fact, and both descriptions are accurate. That's right. Philosophies have started talking of equivalent descriptions. It's a term used in philosophy of science. But now, for a couple of hundred years after Newton, educated Weston man thought that what Newton had produced was objective fact. That he had discovered laws which governed the workings of the world and the workings of the universe. And this was just objectively true independently of us. That Newton and other scientists had read these facts off of nature by observing it, and looking at it, and so on. And these statements, which made up science, were simply true. Now, there came, didn't there, a period in the development of science, beginning in the late 19th century, when people began to realize that these statements were not entirely true, that this wasn't just a body of objective fact which had been read off from the world. In other words, that science was corrigible. Scientific theories could be wrong. And that raises some very profound questions. I mean, if science isn't just an objectively true description of the way things are, what is it? And if we don't get it from observing the world, where do we get it from? Well, I don't want to say we don't get it from observing the world at all. Obviously, part of this Kantian image is that there is a contribution which is not us. There's something out there. But that also there's a contribution from us. And even Kant, by the way, thought that Newtonian science was indubitable. in fact we thought we contributed its indubitability. The step beyond Kant is the idea that not only is reality partly mind dependent, but that there are alternatives. And that the concepts we impose on the world may not be the right ones, and we may have to change them. That there's an interaction between what we contribute and what we find out. Now what was it that made people begin to realize that this basic conception of science as objective truth was wrong. That science was corrigible. That science was fallible. I think it's that the older science turned out to be wrong where no one expected it to be wrong. Not in detail, but in the big picture. It's not that we find out that, say, the sun isn't 93 million miles from the earth but only 20 million miles from the earth. That's not going to happen. I mean sometimes one makes blunders even about things like that. But that's like making a blunder about whether there's a chair in the room. Wholesale skepticism about whether numerical values are right in science would be as unjustified as wholesale skepticism about anything. But where the newer theories don't agree with Newton is not over the approximate truth of the mathematical expressions in Newton's theory. Those are still perfectly good for calculation. It's over the big picture. We've replaced the picture of an absolute space and an absolute time by the picture of a four dimensional space time. We replaced a picture of a Euclidean world by a picture of a world which obeys a geometry Euclid never dreamed of. We've swung back to the picture of the word as having a beginning in time, which is really a shocker. It's not even that things once refuted stay refuted forever. So it means, really, that a whole conception of science has been superseded. Instead of thinking of science as a body of knowledge which is being added to all the time by further scientific work, that whole conception of science has in dispensed with, really, hasn't it? And we now think of it as a set of theories which are themselves constantly being replaced by better theories, by more accurate theories, by richer, more explanatory theories. And even the theories we now have, like those of Einstein and his successors, will probably be replaced, in the course of time, by other, better theories by scientists yet unknown. Isn't that so? That's exactly right in fact scientists themselves make this prediction. That is that the main theories of the 20th century-- relativity and quantum mechanics-- will give way to some other theory which will interpret both of them, and so on forever. Now this raises a very fundamental question-- namely, the question, what is truth? I mean, when we say that this or that scientific statement is true, or this or that scientific theory is true, what, in these newly understood circumstances of ours, can we mean by truth? There's still two views that have been since Kant. One is that this old correspondence view still has its adherents. But I think the view that's coming in more and more is that one cannot make a total separation between what's true and what our standards of assertibility are. That the way in which the-- what I call using the Kantian picture-- the mind-dependence of truth comes in is the fact that what's true and what's false is in part a function of what our standards of truth and falsity are. And that depends on our interests, which, again, change over time, of course. That's right I'd like you to say a little more about this question of truth because this again, I think, is puzzling to the layman. I think that people who are not trained in science or philosophy are apt to think that there are a certain set of facts, and a true statement is a statement that accurately describes those facts. I'd like to talk a little about some of the difficulties that are actually involved in this. I think the biggest difficulty in science itself comes from the fact that, even within one scientific theory, you often find different accounts can be given the so-called facts. This came in with the special theory of relativity, when it turned out that facts about simultaneity, where the two things happen at the same time, could be described differently by different observers. One could say "Boy Scout A fired a starter's pistol before Boy Scout B," the other could say, "No, Boy Scout B fired a starter's pistol before Boy Scout A," and if the distance is sufficiently large, so that a light signal can't travel from one to the other without exceeding the speed of light, then it may be both descriptions are correct. Both are admissible. Of course, this leads to profound conceptual difficulties in understanding some modern scientific theories. And this prompts the thought that a scientific theory can be useful, and meaningful, and can work even if nobody really quite understands what it means. And this is the case with quantum mechanics, isn't it? I mean, nobody is really sure what quantum mechanics actually means, and yet it works. That's right and, again, I want to say one shouldn't push that too far. Because I think we don't want to give up our standards of intelligibility altogether. We want to say-- quantum mechanics works, and the very fact that it works means that there's something fundamentally right about it. And with respect to its intelligibility, we're willing to say, in part, that may be that we have the wrong standards of intelligibility, that we have to change our intuitions. But in part, there are real paradoxes in the theory. And I think that's more work has to be done to really get a satisfactory resolution of these paradoxes. Things are very ticklish now. Yes, I think somebody hearing our discussion to whom, perhaps, some of these ideas are new might find himself thinking-- well, if all this is so, how is it that science works? If traditional scientific theories are breaking down, if science is turning out not to be a body of reliable, permanent, firm, objective knowledge, if a significant portion of every scientific theory is subjective anyway, in the sense that it's contributed by the human mind, by the observed by the scientists, how is it, in these circumstances, that we can actually build bridges, fly airplanes, make rockets go to the moon, and actually make all this soft fuzzy changing partly subjective body of theory work for us. It must fit the world, in some very basic way, in spite of everything that we've been saying. That's true, but I think the contrast between being subjective and fitting the world isn't altogether right. I'm not saying that scientific knowledge is subjective, or that anything goes. I say we're in the difficult position that we often are in in life of thinking there is a difference we good and bad reasoning but we don't have a mechanical rule. In everyday life we use interest-loaded terms. We wouldn't say that there's a policeman on the corner if we didn't have a whole network of social institutions. Somebody coming from a primitive tribe which didn't have policemen might say there's a man in blue on the corner. But the fact that the notion of a policeman is shaped by our interest doesn't mean that it can't be objectively true that there's a policeman on the corner. Also, I think science works precisely because of this corrigibility, in large part, as Professor Poppers pointed out. The difference between science and previous ways of trying to find out truth is in large part that scientists are willing to test their ideas because they don't regard them as infallible. In a way, that was known at the beginning, and then in the success of Newtonian science, somewhat forgotten. And we've had to be reminded again of what Bacon knew-- that you have to put questions to nature and be willing to change your ideas if they don't work. In some respects, the traditional opposition between science and religion has-- the two parties have crossed places, haven't they? I mean, many religious people now believe they have certain knowledge about the world-- that it was created by called a god, that he made us in his own image, gave us immortal souls which will survive out there, and so on. Certain very fundamental propositions which they hold with absolute certainty. And it's the scientist who believes that everything is fallible, that the world is a mysterious place that we'll never get to the end of the mystery of, and so on and so forth. Isn't there something in that? Maybe. You say it maybe? I'm not sure. You're not sure. Well let's not pursue that. But one point I do want to take up with you, leaving even religion aside, is that now science is seen in this entirely different way that you've been describing, by virtually all scientists, doesn't it mean that the difference between science and non-science isn't what it was always thought of as being. In other words, since science is so subjective, indefinite, changing, and so on it's no longer a clearly-cut and different kind of human activity, and kind of human knowledge, from other sorts of human knowledge and other sorts of human activity. I think that's both true and culturally very important. I think the harm that the old picture of science does is that if there is this realm of absolute fact that scientists are gradually accumulating then everything else appears, somehow, as non-knowledge, something to which even words like true and false can't properly apply. I think that the so-called fact-value dichotomy is a very good example of this. It's hard to have a discussion, on politics for example, without someone very quickly say, at least in my country, is that a fact or a value judgment. As though it can't be a fact that Hitler was a bad man, for example, or a factory that Farah Fawcett Majors is a beautiful woman. And do you think that it is a fact that Hitler was a bad man? Oh yes, I do. I do too. But then, if this is so, if we're abandoning so many of these comfortable, clear-cut, distinctions of the past, what's the point of continuing to use the category, or the notion or the term "science" anyway? I mean, does it any longer clearly demarcate something differentiable from everything else. I don't think it does. I think that-- if you're going to distinguish science from non-science-- that makes a lot of sense if you still have this old view that there's this inductive method. What make something science is that it uses it and uses it pretty consciously and pretty deliberately. And that what makes something non-science is, either it uses it entirety unconsciously, as in learning how to cook-- you're not consciously thinking about inductive logic, or perhaps doesn't use it at all, as metaphysics was alleged not to use it all, I think unfairly. But both say that there's a sharp line between, say, practical knowledge and science. And to say that the method which is supposed to draw this line is rather fuzzy, something that we can state exactly-- and attempts to state it, by the way, have been very much a failure, still. Inductive logic cannot be, say, programmed on a computer the way deductive logic can be programmed on a computer. And I think the development of deductive logic in the last 100 years and the development of the computer have really brought very dramatically just what a different state we are in with respect to proof in the mathematical sciences, which we can state rigorous canons for, and proof in what used to be called the inductive sciences, where we can state general maxims, but you really have to use intuition, general know-how, and so on in applying them. One of the two categories that you described the old-fashioned way of looking at science in terms of was that there was a particular scientific method. That you observed the facts, and, on the basis of these observed instances, you generalized to form scientific theories which you then verified by experiment, and so on. That was the old view. Now that that has been abandoned, is there any longer any single method which is thought of as being scientific method? I don't think they should be. People talk of scientific method as a sort of fiction. But I think that, even in physics where you do get experiments and tests which pretty much fit the textbooks, there's a great deal that doesn't and a great deal that shouldn't. And I think, in fact, in the culture I don't really believe there's an agreement on what a science and what isn't. Any university will tell you in its catalog that there are things called social sciences and that sociology is as science, and that economics is a science. I bet if you ask anyone in the physics department whether sociology is a science, he'll say no. And why will he say no? That's interesting. I think the real reason is not that the sociologists don't use the inductive method. They probably use it more conscientiously, poor things, than the physicists do. I think it's because they're not as successful. So you know that science has become almost a name for successful pursuit of knowledge? That's right. Well now, I think you've given a very, very good description of the way in which these age-old view of what science was has broken down in our century and been replaced by something much more fluid and perhaps much more difficult to get hold of. But you have, I think, described it very clearly. Can we now come, against, this background to what philosophers of science are actually doing. You are a philosopher of science, what do you and your colleagues do. Well, part of what we do which I won't try to describe on this broadcast is fairly technical investigation of specific scientific theories. We look at quantum mechanics very closely. Both to learn what lessons we can from it for philosophy and to see what contributions we can make as philosophers to clarifying its foundations. We look at relativity theory very closely. We look at Darwinian evolution very closely, and so on. This is the part of philosophy of science which provides the data for the rest. But much philosophy of sciences shades over into general philosophy. And I think that the best way to describe it is in terms of what we've been talking about. That is, each of the issues we've been talking about divides philosophers of science. There are philosophers of science who have a correspondence view of truth and try to show that this can be made precise, that the objections can be overcome, you can still view science, somehow, in the old way. And there are others who try to sketch what another view of truth would come to. There are philosophers who still think there is an inductive method that can be rigorously stated and who work on inductive logic. And by the way, I think it's important there should be because we won't make progress to trying to state the inductive method if there aren't. And that there are others who view the development of science more culturally, more historically, and then people like myself who are have a sort of in-between position. That there's something to the notion of a scientific method, there are clear examples, but that it's more or less a continuum. That you mustn't think of it as a kind of mechanical rule, an algorithm, that you can apply to get scientific knowledge. So that I'd say each of these issues-- the nature of truth, the nature of the scientific method, whether there's any necessary truth in science, any conceptual contribution which is permanent and can't be subject to revision is a big question And who are you-- plural-- doing all this work for? I don't ask that in an irreverent way but what I have in mind is this. I've myself taken part in attempts to bring scientists and philosophers together for discussions of precisely the issues that you've raised. And these attempts have usually failed and failed to the same reason-- namely, that the scientists lose interest. They go back to their laboratories and get on with doing more science. And the great bulk of scientists, it seems to me, don't, in fact, take very much of an interest in the issues that you've been talking about. I think it's conspicuous that the greatest of all scientists are exceptions. I mean, the really block-busting, the path-breaking scientists who've actually made the revolution in this century that you've been talking about-- people like Einstein, Max Planck, Neils Bohr, Max Born, Schrodinger, de Broglie, these people were enormously interested in the conceptual questions that's you've raise. But these were the pioneering geniuses. And the great mass of thousands of scientists, who follow on behind them and put their work to its practical application, they don't seem to care so who is listening to you, who is reading the stuff that you publish? Well, I'd say first of all I think we are basically writing for the philosophically-interested layman, for the reader of philosophy. I don't view philosophy of science as giving direct advice to scientists, just as I think more philosophers are ill-advised to think that they're giving, at least, immediately current contemporary advice on how to live your life or what bills to pass in parliament. On the other hand, I do think it's scientists tend to know the philosophy of science of 50 years ago. And perhaps this isn't a bad thing. That is, perhaps this time lag, this culture lag has some value in weeding out what they shouldn't pay attention to. And it's annoying to a philosopher to encounter a scientist who's both sure that he needn't listen to any philosophy of science, and then who produces verbatim ideas which you can recognize as coming from what was popular in 1928. Is there a direct parallel here between what you're saying about scientists and the economist Keynes' famous remark that nearly all businessman who thought they were indifferent to airy-fairy economic theory were in fact the slaves of the economic theorists of yesterday, of a previous generation. That's exactly true. I suppose another parallel one could make would be to say that the account that ordinary language-users give of language, and their use of language, would be extremely unsophisticated simply because they take it for granted and have never thought about it. That too would probably apply to the account that most scientists would give of what they were doing when they were doing their science. That's right. That is, it's a mistake to think that merely because one practices an activity one can give a theory of it. One criticism that's often been made about philosopher of science is that although they talk of science in this general way, what they're nearly always referring to, in fact, is one science namely physics. Now it's true, isn't it, that the science in which the most exciting developments have probably taken place in the last 20 years, anyway, has been not physics but biology. Are philosophers of science open, genuinely open, to the criticism of being too physics-based in their view of science and having ignored biology too much? I think I would defend us against that on the grounds that I don't-- although the theories in biology are of great scientific importance-- Darwin's theory of evolution, Crick/Watson on DNA, and so on they don't, by and large, pose big methodological problems of a kind of don't arise in physical science. I mean, I'm not sure whether you're going to agree with that. Well, I mean, you mentioned evolution just now. And it seems to me that here is a concept which originated in one of the sciences, namely biology, and which, over a comparatively short period of time, has spread throughout the whole of our culture. So the way almost everybody think is influenced by the notion of evolution. Not only about the origins of man but about institutions, or the arts, all kinds of other things. I mean, evolution has become a dimension of Western man's thinking about almost anything. Is that not so? That's right and perhaps there has not been enough attention to this theory. Though what strikes me as interesting is that the possibility of explanations of what we think of as the biological kind-- explanations in terms of function, rather than in terms of physics and chemistry, what you're made have come under more attention, recently, as a result of computer science. Now, this does raise something I'm particularly interested in when you talk of computer Science And that is the interaction between our technology, in the case of computers, and philosophy. Not just science and philosophy, but technology and philosophy. I mean, computers were originally constructed on the basis of a self-conscious analogy with the human mind. But as they became more and more sophisticated we began to learn things from them about the human mind. So our construction of computers and what they, then, tell us about ourselves seems to actually proceed by interactive growth. Isn't that so? That's right, and today this is one are, by the way, in which philosophers are in close contact with scientists. That is, the fields of linguistics, cognitive psychology, computer science, philosophy of language, today, interact constantly. People send papers to one another-- not because someone tells them to. There are conferences at which specialists needs to meet together-- again, not because someone decided there should be some cross-fertilization. The interesting thing about the computer case, if I can stick with it for a moment, is, one might have thought that the rise of the computer would encourage a certain kind of vulgar materialism. That is, "so, after all, we are machines. So, after all, everything about us can be explained in terms of physics and chemistry." Paradoxically the real effect of the computer on psychology on philosophy of mind has been a decrease in that kind of reductionism. See the thing about the computer is that when you work with computers you very rarely have to think about their physics and chemistry. There's a distinction that people draw between their software-- meaning their program, their instructions, their rules, the way they do things-- and their hardware. And generally, you ignore their hardware. You talk about computers at the software level. And you wouldn't really be able to explain what they do, in a way that would be if any use to anyone, in terms at the hardware level. There is a kind of emergence here-- although it's not a mystical kind of emergence, it's not that they're violating the laws of physics-- it's just that the level of organization, that higher-level facts about organization have a kind of autonomy. You'd say this, the fact that it's following this program explains why does this, and I don't need to know how it's built. I only need to know it can be built in such a way that will follow this program. This is a return to view and-- if you apply this to the mind-- it suggests a return to view of mind that I associate with Aristotle. It's the view that we are not ghosts in a machine, not spirits which only temporarily in bodies, but that the relation between the mind in the body is a relation of function to what has that function. Aristotle said, "if you use the word soul in connection with an axe-- and of course," he said, "you don't-- you'd say the soul of an axe is cutting." And he said, "the soul of the eye is seeing." And he thought of man as "a thing that thinks." You're talking, now, of the alternative to materialism and, say, a religious view that this gives us. Puts me in mind, instantly, of the most significant of all the materialist philosophers in the modern world-- namely Marxism. Which, after all, is the official state philosophy of about a third of mankind as we sit here discussing this. Marxism claims to be scientific, and this is a very important thing about it. Is there a significant Marxist contribution to the philosophy of science? I don't think there's a significant Marxist contribution. But I don't think that the Marxist were all wrong either. I think Engles was one of the most scientifically learned men of his century. He got a number of things wrong. But he had an immense general scientific knowledge. And Anti-Duhring, his big book on philosophy of science-- although it contains some rather strange ideas, some of which he gets from Hegel, by the way-- is, on the whole, a sensible book on philosophy of science, among other things. On the other hand, it's not specifically Marxist. I'd say that Engles views on philosophy of science are, in large part, influenced by the standard philosophy of science of the time. They're a fairly sophisticated inductive account. And what about subsequent Marxist thinkers who also had some pretension to be philosophers. Like Lenin, for example. Well, I think they're uneven. Lenin, I think, is one of the worst. He says, for example, that theories are copies of motion. And there you have the copy theory, of science just copying off the reality, in its crudest view. Mao is more sophisticated. Mao is very influenced by John Dewey, who was widely read in China in the 1920s. Do you think it's actually made contribution to the subject as it is today, or not really? I think that it anticipated-- it perhaps might have made a contribution if people have been less ideologically divided. Because I think non-Marx's could have learned-- the Marxists were among the first people to try to, somehow, combine a realist view with a stress on practice, with the stress on corrigibility. And they were very hostile to the notion a priori truth. And today many mainline philosophers of science are very hostile to a priori truth. As it is, they play some of the role in philosophy of science, I think, that Keynes said they play in economics. He described Marx as one of his, sort of, underground predecessors. [LAUGHTER] When I was introducing this program I mentioned not only the philosophy of science but also the philosophy of mathematics. And before we close, I would like us to say something about that anyway. I suppose one can really say that the central problem in the philosophy of mathematics is a direct parallel to the central problem in the philosophy of science-- namely, how long does it fit the world? With science it's-- how does science fit the world? In mathematics it's how does mathematics fit the world. is that right? That's right. And it's even worse. Because if you're trying to defend a copy view, a correspondence of view , of truth in empirical science, you can answer the question-- well how do we build up this picture in such a way that it corresponds by saying we have sense organs. As I mentioned before that's not a total answer because there's a tremendous amount of interpretation involved in simple seeing and simple hearing. But if you are talking about numbers and sets, and somebody says, OK, if mathematical knowledge is simply some kind of a copy of the way numbers are, and the way sets are, and the way other abstract objects that mathematicians study are, the question then, what sense enables us to see how they-- Yes, what is a number. Yes, yes. A deeply problematic question but still an important one. That's right. And on the other hand, I don't want to say that the anti-correspondence has it very easy either. It seems to me that mathematical knowledge is a real puzzle. And I think that philosophers should concentrate more on philosophy of mathematics than they do now because it seems to be an area where no theory works very well. Isn't there another very important parallel between mathematics and science. I mean, throughout the history of science one of the conflicts has been between one camp who thought that it was all about objects in the world which existed independent of human experience and another camp which thought, no, it's human beings and observers who actually contribute most of this. And as you pointed out much earlier discussion, the truth is almost certainly a combination of both. There is a longstanding dispute in mathematics, isn't there, between one body of people who think that mathematical knowledge is something that's, so to speak, inherent in the structure of the world, and we derive it from the world by experience and observation, and another body of mathematical thought that says-- no, no, no, mathematics is a creation of the human mind which we then try to impose on reality like a grid, as it was, on a landscape. Isn't that so? That's right. The latter story's attractive because of the sense organ problem but it doesn't seem to work either because it seems that we're not free to impose any mathematics or any logic we want. Almost anyone would admit that, at least, you have to be consistent. And what's consistent and what isn't somehow something we can just make up or decide. When we try to stress conventionalist accounts, subjective accounts, we come up against the objectivity of mathematics. When we try to stress the objectivity of mathematics we come up against another set of problems. I think we can learn a lot more than we now know about human knowledge and about scientific knowledge by going further into this area. Talking of where we're going from where we are, so to speak, I think the most interesting way in which you could end this discussion, Professor Putnam, would be by talking about what you regard as the most interesting problem areas of the moment. And therefore, I take it, the most-likely growth area for the immediate future in both of the subjects we've been discussing-- philosophy of science and philosophy of mathematics. OK, I think that if I'm allowed to confine my prediction to the immediate future-- because we know that long-run predictions are always false. But in the immediate future, I would expect philosophy of mathematics to be a growth area, and philosophy of logic. I would expect philosophy of physics, I think, to decline somewhat from its central place in philosophy of science. Although I think that part of it touches philosophy of logic. The astounding suggestion has actually come forward in connection with quantum mechanics that we may have to change our logic, our view of what the true logical laws are in order to really understand how the world can be quantum mechanical. I think this side a philosophy of quantum mechanics that touches philosophy of logic will be a hot discussion area. But more generally, I think areas which we almost don't think of this philosophy of science, that become philosophy of language and philosophy of mind, like these questions about computer models of the mind, computer models of language, and these more general questions about theories of truth, the nature of truth, the nature of verification, how science can be objective even though there's not a rigorous scientific method-- I think these questions will continue to be the staples of the field. One thing that worries me about this whole area is its relationship to the educated layman which, in a sense, is the person our discussion has been for. After all, it's not over the 70 years since the 25-year-old Einstein published the theory of relativity. And I'm sure you agree with me that it's true to say now that the great majority of educating people with higher education, university degrees and so on, still have scarcely any idea of what this is all about. And it's done very little to actually influence their view of the world. Isn't there a danger that now science and mathematics are simply racing ahead. And the whole new range and world of insight that is giving us into the universe in which we live simply isn't filtering through to the non-specialist or not filtering through anything like fast enough. That is a danger, but it's one that something can be done about. There's now, for example, a text of special relativity, called space time physics, which is designed for the first month of the first freshman college physics course. And the authors say, at the beginning, that they look forward to the time when it will be taught in high schools. And do think that time will, in fact, come, and quite soon? Oh, I'm sure of it. Yes, well I think you're right. And indeed, I hope you are. Thank you very much Professor Putnam. Thank you.
B1 中級 希拉里-普特南論科學哲學(1977年)。 (Hilary Putnam on the Philosophy of Science (1977)) 53 7 songwen8778 發佈於 2021 年 01 月 14 日 更多分享 分享 收藏 回報 影片單字