I don't know about Starbucks, but the tuberculosis question is not as simple as it sounds.

For a start, sheep and goats, much like other ungulates are susceptible to various strains of TB, but perhaps a bit less to the worst of the cattle strains than cattle are. There are many strains of many species, all of them more pathogenic to some species than others, and most of them pathogenic to more than one.

The importance of badgers as reservoirs and vectors of bovine diseases has been argued for years. I refuse to get into the details of that discussion.Another question, assuming that badgers are indeed important vectors, there is the question of how relevant they are to sheep and goats. To what extent do their paths cross? Are the same routes for infection equally active between badgers and sheep, as compared to badgers and cattle?

It would be nice to get some authoritative, unbiased information on such questions.

In everyday activity we rely on elementary mechanics in more ways than most people guess. Stiffs and planks are easier to manhandle than drunks firstly because rigid bodies present certain advantages of leverage, eg we can raise a plank by one end or swing it by its middle; slack structures mainly require vertical lifting without mechanical advantage. Rigid objects permit us to store work, economising, say by resting raised mass on the structure beneath, whereas a body slumping in every direction collapses wherever it is unsupported, with all the lifting to do again; and flaccid mass passively consumes energy with every change in shape. Himalayan porters who carry visitors or VIPs in litters understand this; they talk loudly to keep their burdens awake – a body slumped in sleep dissipates the forces it absorbs, making it harder to carry than a passenger who reacts dynamically to bumps and jerks.

A static burden’s rigidity is irrelevant – mass is mass. It is as easy to stand with a jouncy flaccid bag straddling your neck as with a firm body of equal mass, but hump it any distance and the flabby energy dissipation saps your stamina.

Frame rucksack design takes account of this.

Exactly how you define time "flowing" I am uncertain. If you mean "how fast we move through time", whatever that means, then the maximum rate would be if you were stationary in free fall in a zero resultant gravitational field. You should then be "travelling" through time at precisely the speed of light, c. Any acceleration in any other direction would leave your speed unchanged, but the components in your motion in any "space" directions would be at right angles to the time direction, and the combined vectors would add up to c, meaning that you would be travelling less rapidly through time.  As your space travel velocity approached c, your time travel vector would approach zero.

Got it?

 

Cheers,

 

Jon

 

 

When you have to do with a question of this type, the first thing to ask yourself what is meant by one thing being better (or bigger, or cleverer, or prettier, or ...) than another.  You see, when you speak of say, one piece of a fine thread being longer or heavier than another piece, everything is simple. You either weigh the thing or stretch and measure the length, and the bigger the number you get, the longer (or heavier or hotter...) the thing is that you are measuring.

 

We say that such measurements are SCALARS. One number is all you need, and there is not much doubt about what it is that you are measuring.

 

But there are other things that cannot usefully be described with a single number; where numbers come into the matter, you need several numbers. Suppose I want to measure the prettiness of girls (a disgusting idea if you ask me; some things are better not measured, something the Miss World people just don’t understand. And the same applies to dog breeders and judges at Crufts and their opposite numbers at the Supreme Cat Show.) then I could measure their height, and their “vital statistics” and the colour of their hair and eyes and... whatever they measure. And I get a LOT of numbers. We say that I get a VECTOR. If they measure say, twenty numbers, we say that it is a twenty-dimensional vector. If the score for hair is the third number in one girl’s vector, then hair score must be the third number in every girl’s vector.

 

Right?

 

Now, if you have not yet studied vectors at school, then you probably soon will, but it is important to understand that there really is a way to measure the “size” of a vector. It is not even a very complicated business to do so (leaving out ideas such as the scaling and weighting of values). This gives you a single number whose size in fact amounts to a scalar. And as you have seen, we CAN compare scalars!

 

These are real and important subjects, and very interesting, and I hope you get on to them and understand them and enjoy them when you do, or alternatively, that you already have and did and did.

 

The trouble is that to replace those vectors with those scalars for the purposes of comparison means that you have lost something. For instance, if the third and fourth numbers in the beauty contest vectors were for hair and eyes,  and one girl got a three and a four, whereas another got a four and a three, their vectors would have the same size (for that part of the vector anyway).

 

BUT THE TWO GIRLS WOULD LOOK DIFFERENT!

 

One’s eyes would look better and the other’s hair would look better (if you happened to agree with the judges of course). It would be as if one could measure beauty by adding components of beauty, as you could measure weight by adding components of weight. (allowing for the fact that adding vectors is not quite the same as adding scalars like weight).

 

And could you? Of course you could. People do it all the time, usually rather badly.

 

The catch is that the results are not very useful unless you know what it is that you really are trying to establish. It works pretty well if a navigator wants to know how far currents and fuel will take his boat or plane, but not if you want to know whether one camera is better than another, or than the human eye. Professional photographers with experience say that the best camera is...

 

The camera you have with you...

You can't have much success with any other camera!

Which camera do you have with you all the time?

 

Apart from your eye, do you want a camera with a good resolution? Well, does that mean you are using a digital camera or a film? Do you want automatic adjustment? None rivals the eye. Do you want versatility? I can show you umpteen cameras that do the most fantastic things, but they could not rival the versatility of the eye. How about the range of contrast that the eye can manage?

 

Sure the eye’s receptor is small, and its area of highest acuity is smaller. Yes, just as one girl’s hair beat the other girl’s. But what are you comparing? As long as there are things one can do with the eye that you cannot do with an SLR or vice versa, one can argue that the eye (or the SLR) is better. But if you cannot say why you are right and no one else’s opinion matters, then you demonstrate that you don’t understand the difference between comparing vectors and comparing scalars.

 

In comparing cameras one would have to talk about not just the field of focus, or its depth, or its resolution, or its contrast, or its weight, or cost, or size, or speed, or memory etc etc, but about which is the better optic recording and interpreting system.

 

And for every system you could mention, some would be better for something, and some other for other things. And that goes for eyes and SLRs too.

 

Your other question is very important and thoughtful.

 

“...if anything really was better than the human eye, how on earth would we be able to tell that it is better?”  

 

Well, to begin with, there is the problem of comparing vectors at all. But that is not really what you wanted to know.

 

When Galileo Galilei told people that through his telescope he could see moons around Jupiter, some disbelieved him.  He offered to let them see for themselves.

 

What do you suppose they said?

 

Some of them refused to look. (You will find all sorts of arguments about this, but Galileo did explicitly mention the refusal in a letter to Kepler (I think it was) for one.) Some people pointed out that there was some merit to their refusal because there was at the time a caution against believing what you could only see, whereas even in those days a lot of optical illusions were known.

 

But back to your question. What one can do is to compare things under a lot of conditions. Suppose I said that my camera was better than your eyes because it could show smaller objects. First I could photograph a lot of objects at a lot of different magnifications. Some would be big, some smaller, and so on down to really invisibly small objects.  By measuring how much the camera enlarged the large objects, and the smaller ones, checking each example with my eyes, I could work out how the camera magnifies things. From that I could predict how small an object it could make visible for me. If my prediction works, then I have given at least one kind of evidence that in that respect the camera is better.

 

And this principle we can follow in many such matters. Start with things that we can check directly, then use those to check the things that we can only check indirectly.

 

At one time I had to do some work based on such principles, and good fun it was too!

 

Again,

 

Tell me if I have not dealt with what it was that you wanted to know.

 

Go well, Jon