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Moore’s Law By: Avery A, David D, David G, Donovan R and Katie F.

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1 Moore’s Law By: Avery A, David D, David G, Donovan R and Katie F

2 Integrated Circuits and Moore’s Law In April of 1965, an engineer named Gordon Moore noticed how quickly the size of electronics was shrinking. He predicted how the number of transistors that could fit on a 1-inch diameter circuit would increase over time. In 1965, 50 transistors could fit on the circuit. A decade later, about 65,000 transistors could fit on the circuit. Moore’s prediction was accurate and is now known as Moore’s Law. What was his prediction? How many transistors will be able to fit on a 1-inch circuit when you graduate from high school? 1. Using the given information and the regression feature on your graphing calculator, create a linear and an exponential model for Moore’s Law. Let 1965 represent the initial time, Round to the nearest hundredth, if necessary. a. linear model b. exponential model 2. In 1970, about 1800 transistors could fit on the semiconductor. Given this information, which model for Moore’s Law is correct? Explain. 3. Write a sequence of terms representing the number of transistors that could fit on a one-inch diameter circuit from 1965 to 1975. Is the sequence arithmetic or geometric? Why? 4. Write a rule for the nth term of the sequence. 5. This sequence is known as “Moore’s Law.” Summarize Moore’s Law in your own words. 6. In the 1970s, Moore revised his prediction to say that the number of transistors would double every two years. How does this affect the rule for your sequence? 7. Write a rule for a sequence that represents the number of transistors that could fit on a 1-inch diameter circuit from 1975 on using Moore’s revised prediction. Using that rule, predict how many transistors will be able to fit on a circuit in the year that you graduate.

3 Linear model: 649x + 50 =Y

4 Exponential model: Y=50(2.05) x

5 In 1970, about 1800 transistors could fit on the semiconductor. Given this information, which model for moore’s law is correct? Exponential

6 Write a sequence of terms representing the number of transistors that could fit on a one-inch diameter circuit from 1965 to 1975. Is the sequence arithmetic or geometric? Exponential model

7 Write a rule for the nth term of the sequence. A n =50+6495 (n-1)

8 The sequence in the last slide is known as “Moore’s Law.” Summarize Moore’s law in your own words. Moore’s law doubles every time and is predicted to trend continuously in the future.

9 In the 1970s, Moore revised his prediction to say that the number of transistors would double every two years. How does this affect the rule for your sequence?

10 Write a rule for a sequence that represents the number of transistors that could fit on a 1-inch diameter circuit from 1975 on using Moore’s revised prediction. From that, predict how many transistors will be able to fit on a circuit in the year you graduate.

11 Works Cited betanews.com http://www.mrpudaloff.com/

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