1. (2020高三上·四川期末) 阅读理解

    At one time or another in your life you have probably done origami even if it was just making a paper airplane or something more complicated like a paper crane. The chances are that as you did it, you reflected on how inventive this traditional art is. Animals, boxes, flowers, boats: it all can be created from a single square or rectangular sheet of paper simply by folding it. No cutting, no pasting.

    But did you ever stop to think how the same techniques might be applied to engineering? Equipment that could be of real practical use? Origami meets the demand for things that need to be small when transported and large when they arrive, like the everyday umbrella. In fact, origami-inspired creations have already flown in space; in 1995, Japanese engineers launched a satellite with solar panels that folded like a map.

    "It's now mathematically proven that you can pretty much fold anything," says physicist Robert J. Lang, who quit his engineering job eight years ago to fold things full time. Lang, an origami enthusiast since age six, advised a advised well-known ear manufacturer the best way to fold an airbag into a dashboard. He is currently working on a space telescope lens that, if all goes according to plan, should be able to unfold to the size of a football field.

    At the other end of the scale, researchers are also working on tiny folding devices that could lead to breakthroughs in medicine and computing. There's no doubt that computers of the future may contain tiny, folded motors or capacitors for faster processing and better memory.

    Applications for origami engineering go further than many of us might imagine. "Some day," says MIT's Erik Demaine, "we'll build reconfigurable (可重构的) robots that can fold on their own from one thing into another, like Transformers. Too much like science fiction to be true? Maybe—though you certainly wouldn't want to bet against it."

1. （1） What do we know about origami?

   A . It consumes lots of time. B . It involves interesting ideas. C . It requires complex techniques. D . It has to do with cutting and pasting.
3. （2） Which of the following is an application of origami?

   A . A space telescope lens can be folded to the size of an umbrella. B . A satellite is equipped with solar panels and a folded map. C . An airbag can be better folded into a dashboard of a car. D . A future computer contains many huge folded motors.
5. （3） What is Erik Demaine's attitude towards origami engineering?

   A . Hopeful B . Doubtful. C . Disapproving. D . Ambiguous.
7. （4） In which section of a newspaper may this text appear?

   A . Entertainment. B . Culture. C . Education. D . Pop-science.