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Electronics (F.5 & C.3) Mr. Jean April 16 th, 2014
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The plan: Analog to Digital Storage Devices and systems Amplifiers Input / Output Gain Comparator Schmitt Trigger
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Analogue Signals
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Analogue Use Sound transmission is an example of an analogue signal – When you speak into a microphone the change in pressure causes the inside of the microphone to vibrate and change the potential difference – This signal can be fed through an amplifier which will increase the strength of the signal reproducing the signal but louder
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Analogue Storage Vinyl Records – A record is made of plastic that has a thin groove cut into it by a needle that moves at the same frequency as the sound it is recording – Playback involves a needle connected to a circuit that follows the grooves
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Analogue Storage Audio Tape – A tape also uses an analogue signal to store data. Instead of varying grooves however, the tape, which is made out of magnetic material, has varying magnetic fields. – To record, the tape is run through an electromagnet which varies the field at the same rate as the sound signal
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Digital Signals A digital signal does not vary over time but rather changes from one discrete value to another. – In a circuit with a switch and a light bulb, the bulb is on when the switch is closed and off when the switch is open
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Digital Signals
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Binary Number Systems “There are 10 kinds of people in the world, those who understand binary and those who don’t” Digital Signals are encoded/stored using the binary number system – This is a system of 1’s and 0’s – Our normal numbering system uses a base- 10 system while the binary system uses a base-2 system
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Binary Number System Base 103210 1000100101 Base 23210 8421 DecimalBinary 100000001 200000010 300000011 400000100 500000101 ASCII Code A01000001 B01000010 C01000011 D01000101
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Binary Number System In the binary number system, each 1 or 0 is called a bit – There are 8 bits in a byte An 8 bit system has 8 places 00000000 A 128-bit encryption has 128 places With the 8-bit system all western characters can be coded Each symbol (letter, number, etc.) takes up 1 byte of memory
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LSB and MSB Least significant bit – bit that is farthest to the right – Determines whether the number will be even or odd. – Changes with any small number change Most significant bit – bits farthest to the left – Don’t change unless there is a large number change – Often 000 0000101 LSB is 1 and MSB is 0
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Converting to Binary Find the largest power of 2 that is less that the decimal Subtract that number from the initial Repeat until you reach 2 0 Convert 67 to binary – 01000011
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Analogue to Digital Conversion Analogue signals can be converted to digital by breaking the analogue signal into discrete values (generally pd) – The more values that are used, the more accurate the digital signal will be, but more storage space will be required
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Analogue to Digital Conversion The quantized values (pd) can then be converted into binary – If the quantized values range from -6V to +6V this can be represented most easily by the numbers 0 – 12 – A 4-bit system can be used to represent these numbers (0000 – 1100) – As long as the bit rate is known, the signal can then be converted back to a pd.
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Sampling Rate The sampling rate is how often the pd is measured and recorded – The higher the sampling rate, the more accurate the digital conversion will be – Nyquist theory states that to record a certain frequency the sample rate needs to be at least 2x the frequency This is so at least 1 peak value and 1 trough value can be recorded
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Sample Rate Here there are 22 samples taken for every cycle. What if there were only 2? 4? Etc.?
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Storage on a CD Basic structure of a CD – Information is stored on the CD as a series of bumps and flats pressed into the aluminum
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Storage on a CD The data is ‘read’ by a laser that shines along the tracks – The light reflected off of the flat sections will be read as a ‘1’, – If the pit/bump is just the right depth the light reflected off will destructively interfere with itself and the lack of light will be read as a ‘0’
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Storage on a CD Destructive Interference Review: – The reflected wave must be a ½ λ (π) out of phase
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Storage on a CD How deep do the pits need to be? – If light with a wavelength of 780nm is used to read a CD, what is the minimum depth the pits need to be? The light that hits the pit travels 2d farther than the light reflected from the flat portions.
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Reading a CD So ‘0’s are actually read every time depth changes – Both the start of a pit and the end
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CD vs. DVD CDs can hold about 650MB of info while DVDs can hold about 4.7 GB – DVDs use light with a wavelength of about 640 nm which means that smaller (thinner) pits can be read – This is because of the resolution of the light, shorter wavelengths can be resolved (separated) more clearly
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Analogue vs. Digital Storage Benefits of Digital – Quality and Corruption Digital data is far less likely to be corrupted – On a tape the magnetic fields can fade, on an LP the tracks will wear – Even if a CD wears, the distinction between a 1 and a 0 is still apparent – Accurate Reproducibility Data can be stored and retrieved with much more accuracy in digital form – Greater Portability and Capacity – Easier to Manipulate
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Analogue vs. Digital Storage Benefits of Analogue Storage – With analogue there is the potential for infinite signal variation Digital is constrained by the number of bits – Processing and retrieving equipment is simpler (not necessarily easier to use)
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Implications of digital data storage What possible negative could all this cool technology have?
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Operational Amplifier An amplifier is a device that takes a signal and makes its bigger. – An mp3 player gives out a very small pd that you can hear with your headphones – If you connect it to a pair of speakers the sound can be amplified with a power source An operation amplifier (op-amp) can be made to do more than just amplify signals, based on how it is wired
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Op-Amp An actual op amp is a small black rectangle called a chip – The chip has 8 ‘legs’ or connections but only 5 are used for our purposes – Inside the chip is a complicated circuit composed of transistors and resistors that we don’t need to be concerned with
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Op Amp In the top diagram (how an op amp is represented in a circuit diagram); – The inputs are where the signal is fed into the amp – The output is where the amplified signal comes out – The +/- V is where the supply (power is connected) This is the energy that is used to amplify the signal – In a circuit diagram the V+ and V- are often omitted
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The Ideal Op Amp An ideal operational amplifier has three primary characteristics – Infinite input impedance – Zero output impedance – Infinite gain
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Input impedance This is essentially the resistance that would be measured across the input terminals – This means that the input current to the amplifier is negligible – The amplifier measures the difference between the two inputs
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Output Impedance The output of an op amp is like a power source – It can be used to power loudspeakers, lightbulbs, etc. – The output impedance is equal to the internal resistance of the power source In an ideal op amp this is zero – To get a current to flow through a load resistor there must be a pd across it This is done by connecting the resistor to a wire at 0V. This is called an earth or ground
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Open Loop Gain If a very small pd is applied between the inputs, a large potential is created on the output – The ratio: is called the open loop gain of the amplifier This value is typically in the range of 10 6 This means that if the pd between the input terminals were 0.01V, then the output potential would be 10000 V In an ideal op amp this is infinite but it is controlled by the supply voltage
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Gain A lone op amp is not particularly useful for amplifying music – If the open loop gain is 10 6, once the signal goes above 0.000009 V, the output will be a constant 9V with a 9V supply – The amplifier must be able to produce a signal that is the same as the input but with a larger amplitude
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Inverting Op Amp An op amp is said to be inverting if the + (non- inverting) input is grounded and the – (inverting) input is connected to a resistor and an input signal – R in is the input resistor – R f is the feedback resistor since it is feeding the output voltage back to the input
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Inverting Op Amp When a voltage is applied to the inverting input (-) a voltage of the opposite polarity develops on the output – if V in is +, then V out is -; if V in is -, then V out is +
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Inverting Op Amp Finding the Gain – The difference between V+ and V- must be small so we can say they are equal Since + is connected to Earth, The potential at a point (P) between R1 and R2 is therefore also 0V Applying Ohm’s Law to R1 and R2
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Non-Inverting Op Amp An op amp is said to be non- inverting if the – (inverting) input is grounded and the + (non- inverting) input is connected to an input signal – The polarity of the voltage at the output is the same as that of the input (if V in is +, then V out is +; if V in is -, then V out is - )
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Non-Inverting Op Amp The input signal is applied to the non-inverting (+) lead The amount the signal is amplified is determined by the value of resistors R out and R f – If the difference between + and – is more than 9μV, the output will be a constant 9V so we can say the two inputs are about the same – This means that the potential at point P is also V input
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Non-Inverting Op Amp If the current through the resistors is I then we get To R out alone; The 2 currents are equal so
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Comparator A comparator compares two potentials – If the potential on the + input is higher, then the output is V+ and if the – input is higher, then the output is V-
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Comparator Fire Alarm – At normal room temp all resistances are equal so both inputs equal V and the output is 0 – If the temp increases then the resistance of the thermistor drops and the pd across it drops. This results in an increase in the potential at the – input which results in an output of 9 V and the bell will ring
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Schmitt Trigger A type of comparator that switches to a high output when the input is above a given value (upper threshold) – Only switches to a low output when the input gets lower than another low value (lower threshold) – Schmitt triggers are often used for reshaping digital signals to remove noise
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Schmitt Trigger
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