The Infrared Scanning Technology

      Even plant can run a fever, especially when they are under attack by insects or disease. But unlike humans, plants can have their temperature taken from 3,000 feet away --straight up. A decade ago, adopting the infrared (红外线的) scanning (扫描) technology developed for military purposes and other satellites, physicist Stephen Paley came up with

a quick way to take the temperature of crops to determine which ones are under stress. The goal was to let farmers precisely target pesticide (杀虫剂) spraying rather than rain poison on a whole field, which invariably includes plants that don't have pest problems.

      Even better, Paley's Remote Scanning Services Company could detect crop problems before they became visible to the eye. Mounted on a plane flown at 3,000 feet at night, an infrared scanner measured the heat given out by crops. The data were transformed into a color-coded map showing where plants were running "fevers". Farmers could then spot-spray, using 50 to 70 percent less pesticide than they otherwise would.

     The bad news is that Paley's company closed down in 1984, after only three years. Farmers resisted the new technology and tong-term backers were hard to find. But with the renewed concern about pesticides on produce, and refinements in infrared scanning, Paley hopes to get back into operation. Agriculture experts have no doubt the technology works. "This technique can be used on 75 percent of agricultural land in the United States," says George Oerther of Texas A & M. Ray Jackson, who recently retired from the Department of Agriculture, thinks remote infrared crop scanning could be adopted by the end of the decade. But only if Paley finds the financial backing which he failed to obtain 10 years ago.

1. Plants will give out an increased amount of heat when they are ________.

    A. sprayed with pesticides

    B. facing an infrared scanner

    C. in poor physical condition

    D. exposed to more-than-enough sun rays

2. In order to apply pesticide spraying precisely, we can use infrared scanning to________.

    A. estimate the damage to the crops

    B. measure the size of the affected area

    C. draw a color-coded map

    D. determine the problem area

3. Farmers can save a considerable amount of pesticide by ________.

    A. using rain-like spraying

    B. ask advice from infrared scanning experts

    C. transforming poisoned rain

    D. knowing crop problems at an early stage

4. The application of infrared scanning technology to agriculture met with some difficulties in ________.

    A. the lack of official support

    B. its high cost

    C. the lack of financial support

    D. its failure to help increase production

5. Infrared scanning technology may be brought back into operation because of ________.

    A. the desire of farmers to improve the quality of their produce

    B. growing concern about the much use of pesticides on crops

    C. the forceful promotion by the Department of Agriculture

D. full support from agricultural experts

Even plants can run a fever, especially when they're under attack by insects or disease. But unlike human, plants can have their temperature taken from 3,000 feet away—straight up. A decade ago, adopting the infrared(红外线)scanning technology developed for military purposes and other satellites, physicist Stephen Paley came up with a quick way to take the temperature of crops to determine which ones are under stress. The goal was to let farmers precisely target pesticide(杀虫剂)spraying rather than rain poison on a whole field, which invariably includes plants that don't have pest problems.
Even better, Paley's Remote Scanning Services Company could detect crop problems before they became visible to the eye. Mounted on a plane flown at 3,000 feet at night, an infrared scanner measured the heat emitted by crops. The data were transformed into a colour­coded map showing where plants were running “fevers”. Farmers could then spot­spray, using 50 to 70 percent less pesticide than they otherwise would.
The bad news is that Paley's company closed down in 1984, after only three years. Farmers resisted the new technology and long­term backers were hard to find. But with the renewed concern about pesticides on produce, and refinements in infrared scanning, Paley hopes to get back into operation. Agriculture experts have no doubt the technology works. “This technique can be used on 75 percent of agricultural land in the United States, ” says George Oerther of Texas A & M. Ray Jackson, who recently retired from the Department of Agriculture, thinks remote infrared crop scanning could be adopted by the end of the decade. But only if Paley finds the financial backing which he failed to obtain 10 years ago.
【小题1】Plants will send out an increased amount of heat when they are________.

Even plants can run a fever, especially when they're under attack by insects or disease. But unlike human, plants can have their temperature taken from 3,000 feet away—straight up. A decade ago, adopting the infrared(红外线)scanning technology developed for military purposes and other satellites, physicist Stephen Paley came up with a quick way to take the temperature of crops to determine which ones are under stress. The goal was to let farmers precisely target pesticide(杀虫剂)spraying rather than rain poison on a whole field, which invariably includes plants that don't have pest problems.
Even better, Paley's Remote Scanning Services Company could detect crop problems before they became visible to the eye. Mounted on a plane flown at 3,000 feet at night, an infrared scanner measured the heat emitted by crops. The data were transformed into a colour­coded map showing where plants were running “fevers”. Farmers could then spot­spray, using 50 to 70 percent less pesticide than they otherwise would.
The bad news is that Paley's company closed down in 1984, after only three years. Farmers resisted the new technology and long­term backers were hard to find. But with the renewed concern about pesticides on produce, and refinements in infrared scanning, Paley hopes to get back into operation. Agriculture experts have no doubt the technology works. “This technique can be used on 75 percent of agricultural land in the United States, ” says George Oerther of Texas A & M. Ray Jackson, who recently retired from the Department of Agriculture, thinks remote infrared crop scanning could be adopted by the end of the decade. But only if Paley finds the financial backing which he failed to obtain 10 years ago.

1. 1.

   Plants will send out an increased amount of heat when they are________.

   1. A.
      facing an infrared scanner
   2. B.
      sprayed with pesticides
   3. C.
      in poor physical condition
   4. D.
      exposed to excessive sun rays
2. 2.

   In order to apply pesticide spraying precisely, we can use infrared scanning to________.

   1. A.
      estimate the damage to the crops
   2. B.
      draw a colour­coded map
   3. C.
      measure the size of the affected area
   4. D.
      locate the problem area
3. 3.

   Farmers can save a considerable amount of pesticide by________.

   1. A.
      resorting to spot­spraying
   2. B.
      transforming poisoned rain
   3. C.
      consulting infrared scanning experts
   4. D.
      detecting crop problems at an early stage
4. 4.

   The application of infrared scanning technology to agriculture met with some difficulties—________.

   1. A.
      its high cost
   2. B.
      the lack of official support
   3. C.
      the lack of financial support
   4. D.
      its failure to help increase production

  Even plant can run a fever, especially when they’re under attack by insects or diseases. But unlike humans, plants can have their temperature taken from 3, 000 feet away - straight up. A decade ago, adopting the infrared（红外线）scanning technology developed for military purposes and other satellites, physicist Stephen Paley came up with a quick way to take the temperature of crops to determine which ones are under stress. The goal was to let farmers precisely target pesticide（杀虫剂）spraying rather than rain poison on a whole field, which invariably includes plants that don’t have pest（害虫）problems.
　　Even better, Paley’s Remote Scanning Services Company could detect crop problems before they became visible to the eye. Mounted on a plane flown at 3, 000 feet at night, an infrared scanner measured the heat emitted by crops. The data were transformed into a color-coded map showing where plants were running“fevers”. Farmers could then spot-spray, using 50 to 70 percent less pesticide than they otherwise would.
　　The bad news is that Paley’s company closed down in 1984, after only three years. Farmers resisted the new technology and long-term backers were hard to find. But with the renewed concern about pesticides on produce, and refinements in infrared scanning, Paley hopes to get back into operation. Agriculture experts have no doubt that technology works. “This technique can be used on 75 percent of agricultural land in the United States, ” says George Oerther of Texas A & M. Ray Jackson , who recently retired from the Department of Agriculture, thinks remote infrared crop scanning could be adopted by the end of the decade. But only if Paley finds the financial backing which he failed to obtain 10 years ago.
68. Plants will emit an increased amount of heat when they are________.
　 A. sprayed with pesticides
　 B. facing an infrared scanner
　 C. in poor physical condition
　 D. exposed to excessive sun rays
69. In order to apply pesticide spraying precisely, we can use infrared scanning   to____.
　 A. estimate the damage to the crops
　 B. measure the size of the affected area
　 C. draw a color -coded map
　 D. locate the problem area
69. Farmers can save a considerable amount of pesticide by________.
　 A. resorting to spot - spraying
　 B. consulting infrared scanning experts
　 C. transforming poisoned rain
　 D. detecting crop problems at an early stage
71. The application of infrared scanning technology to agriculture met with some     difficulties due to ________.,
　 A. the lack of official support
　 B. its high cost
　 C. the lack of financial support
　 D. its failure to help increase production