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Tony Hyun Kim Spring 2008, 6.UAT. Objectives  Explain the basic physics of wireless control.  Focus on ELECTRO MAGNETIC WAVES  Demonstrate the physics.

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Presentation on theme: "Tony Hyun Kim Spring 2008, 6.UAT. Objectives  Explain the basic physics of wireless control.  Focus on ELECTRO MAGNETIC WAVES  Demonstrate the physics."— Presentation transcript:

1 Tony Hyun Kim Spring 2008, 6.UAT

2 Objectives  Explain the basic physics of wireless control.  Focus on ELECTRO MAGNETIC WAVES  Demonstrate the physics with early 20 th century technology.

3 Objectives  Explain the basic physics of wireless control.  Focus on ELECTRO MAGNETIC WAVES  Demonstrate the physics with early 20 th century technology.

4 The Basics: Electric field of a stationary charge +q

5 The Basics: Electric field of a stationary charge +q

6 The Basics: Electric field of a stationary charge +q  Boring: The field is static, and radial

7 The Basics: Electric field of a stationary charge +q

8 Two basic physical facts 1. “Information transfer” is NOT instantaneous. 1. For electric phenomena, the “transfer rate” is c = 300,000,000 m/s = 3 x 10 8 m/s 2. In “free space,” field lines don’t disappear.

9 E-Field of an ACCELERATED charge Y X t = 0 second

10 E-Field of an ACCELERATED charge Y X t = 1 second 1 cm

11 E-Field of an ACCELERATED charge Y X t = 0 second

12 E-Field of an ACCELERATED charge Y X t = 0 second

13 E-Field of an ACCELERATED charge Y X t = 1 second

14 E-Field of an ACCELERATED charge Y X Radius = c * (1 sec) = 3 x 10 8 m t = 1 second

15 E-Field of an ACCELERATED charge Y X t = 1 second Radius = c * (1 sec) = 3 x 10 8 m/s

16 E-Field of an ACCELERATED charge Y X t = 2 second

17 E-Field of an ACCELERATED charge Y X t = 2 second

18 E-Field of an ACCELERATED charge Y X t = 2 second

19 E-Field of an ACCELERATED charge Y X t = 2 second

20 E-Field of an ACCELERATED charge Y X t > 2 second

21 Let’s see that again

22 E-Field of an ACCELERATED charge Y X t = 2 second “Transverse” Electric field!

23 E-Field of an ACCELERATED charge Y X t > 2 second And it moves out!

24 That’s how electric fields are radiated!

25 Can we arrange for sudden charge motion?  Use a relic from the previous century:  A “spark gap transmitter”  Basic Idea: 1. High voltage 2. Build-up of charge 3. Breakdown: Sudden discharge across junction Focus here!

26 Spark gap transmitter: 1. High voltage

27 Spark gap transmitter: 2. Charge buildup

28 Spark gap transmitter: 3. Breakdown

29 Spark gap transmitter  The apparatus is a realization of the sudden charge motion we described earlier. Y X t > 0 second Top down view of the transmitter

30 Wireless control of LEDs  Want to take advantage of the basic physics to do something useful.  Use a device that responds to electric fields:  A “coherer”: a circuit with an antenna

31 Coherer

32 Conclusion  Accelerated charges radiate electro magnetic waves.  Described and demonstrated a simple experimental setup to accelerate charges.  Used this physics to control LEDs wirelessly.  Acknowledgements: Robert Moffatt (Physics ’09)

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