MIT 6.061 Introduction to Electric Power Systems Class Notes PDF
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Massachusetts Institute of Technology
2011
J.L. Kirtley Jr.
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These are class notes from MIT's 6.061 Introduction to Power Systems course, Spring 2011, focusing on network theory. The notes cover topics such as network primitives, Kirchhoff's laws, and voltage and current dividers.
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Massachusetts Institute of Technology Department of Electrical Engineering and Computer Science 6.061 Introduction to Power Systems Class Notes Chapter 1: Review of Network Theory∗...
Massachusetts Institute of Technology Department of Electrical Engineering and Computer Science 6.061 Introduction to Power Systems Class Notes Chapter 1: Review of Network Theory∗ J.L. Kirtley Jr. 1 Introduction This note is a review of some of the most salient points of electric network theory. In it we do not prove any of the assertions that are made. We deal only with passive, linear network elements. 2 Network Primitives Electric network theory deals with two primitive quantities, which we will refer to as: 1. Potential (or voltage), and 2. Current. Current is the actual flow of charged carriers, while difference in potential is the force that causes that flow. As we will see, potential is a single- valued function that may be uniquely defined over the nodes of a network. Current, on the other hand, flows through the branches of the network. Figure 1 shows the basic notion of a branch, in which a voltage is defined across the branch and a current is defined to flow through the branch. A network is a collection of such elements, connected together by wires. i + v − Figure 1: Basic Circuit Element Network topology is the interconnection of its elements. That, plus the constraints on voltage and current imposed by the elements themselves, determines the performance of the network, described by the distribution of voltages and currents throughout the network. Two important concepts must be described initially. These are of “loop” and “node”. ∗ c 2007 James L. Kirtley Jr. 1 1. A loop in the network is any closed path through two or more elements of the network. Any non-trivial network will have at least one such loop. + v − i2 2 i3 − + v1 v3 + − i1 Figure 2: This is a loop 2. a node is a point at which two or more elements are interconnected. + v1 − − v2 + i1 i2 − v3 + i3 Figure 3: This is a node The two fundamental laws of network theory are known as Kirchoff ’s Voltage Law (KVL), and Kirchoff ’s Current Law (KCL). These laws describe the topology of the network, and arise directly from the fundmantal laws of electromagnetics. They are simply stated as: Kirchoff’s Voltage Law states that, around any loop of a network, the sum of all voltages, taken in the same direction, is zero: vk = 0 (1) loop Kirchoff’s Current Law states that, at any node of a network, the sum of all currents entering the node is zero: ik = 0 (2) node 1Note that KVL is a discrete version of Faraday’s Law, valid to the extent that no time-varying flux links the loop. KCL is just conservation of current, allowing for no accumulation of charge at the node. 2 Network elements affect voltages and currents in one of three ways: 1. Voltage sources constrain the potential difference across their terminals to be of some fixed value (the value of the source). 2. Current sources constrain the current through the branch to be of some fixed value. 3. All other elements impose some sort of relationship, either linear or nonlinear, between voltage across and current through the branch. + v i − Voltage Current Source Source Figure 4: Notation for voltage and current sources Voltage and current sources can be either independent or dependent. Independent sources have values which are, as the name implies, independent of other variables in a circuit. Dependent sources have values which depend on some other variable in a circuit. A common example of a dependent source is the equivalent current source used for modeling the collector junction in a transistor. Typically, this is modeled as a current dependent current source, in which collector current is taken to be directly dependent on emitter current. Such dependent sources must be handled with some care, for certain tricks we will be discussing below do not work with them. For the present time, we will consider, in addition to voltage and current sources, only impedance elements, which impose a linear relationship between voltage and current. The most common of these is the resistance, which imposes the relationship which is often referred to as Ohm’s law: vr = Rir (3) ir + R vr − Figure 5: Resistance Circuit Element A bit later on in this note, we will extend this notion of impedance to other elements, but for the moment the resistance will serve our purposes. 3 3 Examples: Voltage and Current Dividers Figure 6 may be used as an example to show how we use all of this. See that it has one loop and three nodes. Around the loop, KVL is: Vs − v1 − v2 = 0 At the upper right- hand node, we have, by KCL: i1 − i2 = 0 The constitutive relations imposed by the resistances are: v1 = R1 i1 v2 = R2 i2 Combining these, we find that: Vs = (R1 + R2 )i1 We may solve for the voltage across, say, R2 , to obtain the so-called voltage divider relationship: R2 v2 = Vs (4) R1 + R2 i1 v1 + − + + v R1 R2 v2 s − − i2 Figure 6: Voltage Divider A second example is illustrated by Figure 7. Here, KCL at the top node yields: Is − i1 − i2 = 0 And KVL, written around the loop that has the two resistances, is: R1 i1 − R2 i2 = 0 Combining these together, we have the current divider relationship: R1 i2 = Is (5) R1 + R2 Once we have derived the voltage and current divider relationships, we can use them as part of our “intellectual toolkit”, because they will always be true. 4 i1 i2 + + I R1 v1 R2 v2 s − − Figure 7: Current Divider 4 Node Voltages and Reference One of the consequences of KVL is that every node in a network will have a potential which is uniquely specified with respect to some other node. Thus, if we take one of the nodes in the network to be a reference, or datum, each of the other nodes will have a unique potential. The voltage across any network branch is then the difference between the potentials at the nodes to which the element is connected. The potential of a node is the sum of voltages encountered when traversing some path between that node and the datum node. Note that any path will do. If KVL is satisfied, all paths between each pair of nodes will yield the same potential. A commonly used electric circuit is the Wheatstone Bridge, shown in its simplest form in Figure 8. The output voltage is found simply from the input voltage as just the difference between two voltage dividers: R2 R4 vo = vs − R1 + R2 R3 + R4 This circuit is used in situations in which one or more resistors varies with, say temperature or mechanical strain. The bridge can be balanced so that the output voltage is zero by adjusting one of the other resistors. Then relatively small variations in the sensing element can result in relatively big differences in the output voltage. If, for example R2 is the sensing element, R4 can be adjusted to balance the bridge. 5 Serial and Parallel Combinations There are a number of techniques for handling network problems, and we will not be able to investigate each of them in depth. We will, however, look into a few techniques for analysis which involve progressive simplification of the network. To start, we consider how one might handle series and parallel combinations of elements. A pair of elements is in series if the same current flows through both of them. If these elements are resistors and if the detail of voltage division between them is not required, it is possible to lump the two together as a single resistance. This is illustrated in Figure 9. The voltage across the current source is: vs = v1 + v2 = is R1 + is R2 = is (R1 + R2 ) The equivalent resistance for the series combination is then: Rseries = R1 + R2 (6) 5 + + R1 v1 R3 v3 + − − v vo s − + + R2 v3 R4 v4 − − Figure 8: Wheatstone Bridge v1 + − + + is vs R1 R2 v2 − − i2 Figure 9: Series Resistance Combination Similarly, resistance elements connected in parallel can be lumped if it is not necessary to know the details of division of current between them. Figure 10 shows this combination. Here, current i is simply: v v 1 1 i= + =v + R1 R2 R1 R2 The equivalent resistance for the parallel combination is then: 1 R1 R2 Rpar = 1 1 = (7) R1 + R2 R1 + R2 Because of the importance of parallel connection of resistances (and of other impedances), a special symbolic form is used for parallel construction. This is: R1 R2 R1 ||R2 = (8) R1 + R2 As an example, consider the circuit shown in Figure 11, part (a). Here, we have four, resistors arranged in an odd way to form a two- terminal network. To find the equivalent resistance of this thing, we can do a series of series-parallel combinations. The two resistors on the right can be combined as a series combination to form a single, two ohm resistor as shown in part (b). Then the equivalent resistor, which is in parallel with one of the 6 I + i1 i2 + + v R1 v1 R2 v2 − − − Figure 10: Parallel Resistance Combination 2 1 2 2 2 1 2 2 1 3 Parrallel Series (a) Series (b) (c) Comb (d) Comb Comb Figure 11: Series-Parallel Reduction two ohm resistors can be combined to form a single combination part(c). That is in series with the remaining resistor, leaving us with an equivalent input resistance of R = 3Ω. 6 Loop and Node Equations There are two well- developed formal ways of solving for the potentials and currents in networks, often referred to as loop and node equation methods. They are closely related, using KCL and KVL together with element constraints to build sets of equations which may then be solved for potentials and currents. In the node equation method, KCL is written at each node of the network, with currents expressed in terms of the node potentials. KVL is satisfied because the node potentials are unique. In the loop equation method, KVL is written about a collection of closed paths in the network. “Loop currents” are defined, and made to satisfy KCL, and the branch voltages are expressed in terms of them. The two methods are equivalent and a choice between them is usually a matter of personal prefer ence. The node equation method is probably more widely used, and lends itself well to computer analysis. To illustrate how these methods work, consider the network of Figure 12. This network has three nodes. We are going to write KCL for each of the nodes, but note that only two explicit equations are required. If KCL is satisfied at two of the nodes, it is automatically satisfied at the third. Usually the datum node is the one for which we do not write the expression. 7 i1 R2 + + V R1 I R v 3 2 − − Figure 12: Sample Network KCL written for the two upper nodes of the network is: V V − v2 −i1 + + = 0 (9) R1 R2 v2 − V v2 −I + + = 0 (10) R2 R3 These two expressions are easily solved for the two unknowns, i1 and v2 : R3 R2 R3 v2 = V + I R2 + R3 R2 + R3 R1 + R2 + R3 R3 i1 = V − I R1 (R2 + R3 ) R2 + R3 i1 R2 + + V R1 I R v 3 2 − ia ib − Figure 13: Sample Network Showing Loops The loop equation method is similar. We need the same number of independent expressions (two), so we need to take two independent loops. For this, take as the loops as is shown in Figure 13: 1. The loop that includes the voltage source and R1. 2. The loop that includes R1 , R2 , and R3. It is also necessary to define loop currents, which we will denote as ia and ib. These are the currents circulating around the two loops. Note that where the loops intersect, the actual branch current will be the sum of or difference between loop currents. For this example, assume the loop currents are defined to be circulating counter-clockwise in the two loops. The two loop equations are: V + R1 (ia − ib ) = 0 (11) R1 (ib − ia ) + R2 ib + R3 (ib − I) = 0 (12) These are equally easily solved for the two unknowns, in this case the two loop currents ia and ib. 8 7 Linearity and Superposition An extraordinarily powerful notion of network theory is linearity. This property has two essential elements, stated as follows: 1. For any single input x yielding output y, the response to an input kx is ky for any value of k. 2. If, in a multi-input network the input x1 by itself yields output y1 and a second input x2 by itself yields y2 , then the combination of inputs x1 and x2 yields the output y = y1 + y2. This is important to us at the present moment for two reasons: 1. It tells us that the solution to certain problems involving networks with multiple inputs is actually easier than we might expect: if a network is linear, we may solve for the output with each separate input, then add the outputs. This is called superposition. 2. It also tells us that, for networks that are linear, it is not necessary to actually consider the value of the inputs in calculating response. What is important is a system function, or a ratio of output to input. Superposition is an important principle when dealing with linear networks, and can be used to make analysis easier. If a network has multiple independent sources, it is possible to find the response to each source separately, then add up all of the responses to find total response. Note that this can only be done with independent sources! Consider, for example, the example circuit shown in Figure 12. If we are only interested in the output voltage v2 , we may find the response to the voltage source first, then the response to the current source, then the total response is the sum of the two. To find the response to the voltage source, we must “turn off” the current source. This is done by assuming that it is not there. (After all, a current source with zero current is just an open circuit!). The resulting network is as in Figure 14. R2 + + V R v 3 2v − − Figure 14: Superposition Fragment: Voltage Source Note that the resistance R1 does not appear here. This is because a resistance in parallel with a voltage source is just a voltage source, unless one is interested in current in the resistance. The output voltage is just: R3 v2v = V R2 + R3 Next, we “turn off” the voltage source and “turn on” the current source. Note that a voltage source that has been turned off is a short circuit, because that implies zero voltage. The network is as shown in Figure 15 9 R2 + I R v 3 2i − Figure 15: Superposition Fragment: Current Source The response to this is: v2i = IR2 ||R3 The total response is then just: R3 R2 R3 v2 = v2v + v2i = V +I R2 + R3 R2 + R3 8 Thevenin and Norton Equivalent Circuits A particularly important ramification of the property of linearity is expressed in the notion of equivalent circuits. To wit: if we are considering the response of a network at any given terminal pair, that is a pair of nodes that have been brought out to the outside world, it follows from the properties of linearity that, if the network is linear, the output at a single terminal pair (either voltage or current) is the sum of two components: 1. The response that would exist if the excitation at the terminal pair were zero and 2. The response forced at the terminal pair by the exciting voltage or current. This notion may be expressed with either voltage or current as the response. These yield the Thevenin and Norton equivalent networks, which are exactly equivalent. At any terminal pair, the properties of a linear network may be expressed in terms of either Thevenin or Norton equivalents. The Thevenin equivalent circuit is shown in Figure 16, while the Norton equivalent circuit is shown in Figure 17. i + R th + v V th − − Figure 16: Thevenin Equivalent Network 10 i + v R In eq − Figure 17: Norton Equivalent Network The Thevenin and Norton equivalent networks have the same impedance. Further, the equiva lent sources are related by the simple relationship: VT h = Req IN (13) The Thevenin Equivalent Voltage, the source internal to the Thevenin equivalent network, is the same as the open circuit voltage, which is the voltage that would appear at the terminals of the equivalent circuit were it to be open circuited. Similarly, the Norton Equivalent Current is the same as minus the short circuit current. To consider how we might use these equivalent networks, consider what would happen if the Wheatstone bridge were connected by some resistance across its output, as shown in Figure 18 + + R1 v1 R3 v3 + − − vo − + v s R5 − + + R2 v3 R4 v4 − − Figure 18: Wheatstone Bridge With Output Resistance The analysis of this situation is simplified substantially if one recognizes that each side of the bridge can be expressed as either a Thevenin or Norton equivalent network. We may proceed to solve the problem by finding the equivalent networks for each side, then paste them together to form the whole solution. So: consider the equivalent network for the left-hand side of the network, formed by the elements V , R1 and R2. This is shown in Figure 19. 11 + R1 RTh l V + − R2 V Th l − Figure 19: Construction of Equivalent Circuit Where, here, the components of the equivalent circuit are: R2 vT hl = V R1 + R2 Reql = R1 ||R2 Similarly, the right side of the network is found to have an equivalent source and resistance: R4 vT hr = V R3 + R4 Reqr = R3 ||R4 And the whole thing behaves as the equivalent circuit shown in Figure 20 RTh l R5 R Th r + + V Th l V Th r − − Figure 20: Equivalent Circuit This is, of course, easily solved for the current through, and hence the voltage across, the resistance R5 , which was desired in the first place: R5 R2 R5 v5 = (vT hl − vT hr ) =V − f racR4 R3 + R4 R5 + reql + reqr R1 + R2 R5 + R1 ||R2 + R3 ||R4 9 Two Port Networks So far, we have dealt with a number of networks which may be said to be one port or single-terminal pair circuits. That is, the important action occurs at a single terminal pair, and is characterized by an impedance and by either a open circuit voltage or a short circuit current, thus forming either a Thevenin or Norton equivalent circuit. A second, and for us very important, class of electrical network has two (or sometimes more) terminal pairs. We will consider formally here the two port network, illustrated schematically in Figure 21. There are a number of ways of characterizing this type of network. For the time being, consider that it is passive, so that there is no output without some input and there are no dependent sources. 12 i1 i2 + + v1 v2 − − Figure 21: Two-Port Network Then we may characterize the network in terms of the currents at its terminals in terms of the voltages, or, conversely, we may describe the voltages in terms of the currents at the terminals. These two ways of describing the network are said to be the admittance or impedance parameters. These may be written in the following way: The impedance parameter point of view would yield, for a resistive network, the following relationship between voltages and currents: v1 R11 R12 i1 = (14) v2 R21 R22 i2 Similarly, the admittance parameter point of view would yield a similar relationship: i1 G11 G12 v1 = (15) i2 G21 G22 v2 These two relationships are, of course, the inverses of each other. That is: −1 G11 G12 R11 R12 = (16) G21 G22 R21 R22 If the networks are linear and passive (i.e. there are no dependent sources inside), they also exhibit the property of reciprocity. In a reciprocal network, the transfer impedance or transfer admittance is the same in both directions. That is: R12 = R21 G12 = G21 (17) It is often useful to express two- port networks in terms of T or Π networks, shown in Figures 22 and 23. Sometimes it is useful to cascade two-port networks, as is shown in Figure 24. The resulting combination is itself a two-port. Suppose we have a pair of networks characterized by impedance parameters: v1 R11 R12 i1 = v2 R12 R22 i2 13 R11− R12 R22− R12 R12 Figure 22: T- Equivalent Network G12 G11 − G12 G22 − G12 Figure 23: Π-Equivalent Network v3 R33 R34 i3 = v4 R34 R44 i4 By noting that v2 = v3 and i3 = −i2 , it is possible to show, with a little manipulation, that: v1 R11 R14 i1 = v4 R14 R44 i4 where 2 R12 R11 = R11 − R22 + R33 2 R34 R44 = R44 − R22 + R33 R12 R34 R14 = R22 + R33 10 Inductive and Capacitive Circuit Elements So far, we have dealt with circuit elements which have no memory and which, therefore, are characterized by instantaneous behavior. The expressions which are used to calculate what these elements are doing are algebraic (and for most elements are linear too). As it turns out, much of the circuitry we will be studying can be so characterized, with complex parameters. However, we take a quick diversion to discuss briefly the transient behavior of circuits containing capacitors and inductors. 14 i1 i2 i3 i4 + + + + v1 1 v2 v3 2 v4 − − − − Figure 24: Cascade of Two-Port Networks ic vc il v l C L Figure 25: Capacitance and Inductance Symbols for capacitive and inductive circuit elements are shown in Figure 25. They are char acterized by the relationships between voltage and current: dvc di ic = C v = L (18) dt dt Note that, while these elements are linear, since time derivatives are involved in their char acterization, expressions describing their behavior in networks will become ordinary differential equations. 10.1 Simple Case: R-C ic + ir C v R − Figure 26: Simple Case: R-C Figure 26 shows a simple connection of a resistance and a capacitance. This circuit has only two nodes, so there is a single voltage v across both elements. The two elements produce the constraints: v ir = R dv ic = dt 15 and, since ir = −ic , dv 1 + v=0 dt RC Now, we know that this sort of first-order, linear equation is solved by: t v ∼ e− RC (To confirm this, just substitute the exponential into the differential equation.) Then, if we have some initial condition, say v(t = 0) = V0 , then t v = V0 e− RC This was a trivial case, since we don’t describe how that initial condition might have taken place. But consider a closely related problem, illustrated in Figure 27. 10.2 Simple Case with Drive R + + v C vc s − − Figure 27: RC Circuit with Drive The analysis of this circuit is accomplished by noting that it contains a single loop, and adding up the voltages around the loop we find: dvc RC + vc = vs dt Now, assume that the voltage source is a step: vs = Vs u−1 (t) We should define the step function with some care, since it is of quite a lot of use. The step is one of a hierarchy of singularity functions. It is defined as: 0 t0 Now, remembering that differential equations have particular and homogeneous solutions, and that for t > 0 a particular solution which solves the differential equation is: vcp = V 16 Of course this does not satisfy the initial condition which is that the capacitance be uncharged: vc (t = 0+) = 0. Again, remember that the whole solution is the sum of the particular and a homogeneous solution, and that the homogeneous solution is the un-driven case. To satisfy the initial condition, the homogeneous solution must be: t cch = −V e− RC So that the total solution is simply: t vc = V 1 − e− RC Next, suppose vs = u−1 (t)V cos ωt. We know the homogeneous solution must be of the same form, but the particular solution is a bit more complicated. In later chapters we will learn how to make the process of extracting the particular solution easier, but for the time being, let’s assume that with a sinusoidal drive we will get a sinusoidal response of the same frequency. Thus we will guess vcp = Vcp cos (ωt − φ) The time derivative is dvcp = ωVcp sin (ωt − φ) dt so that we can find an algebraic equation for the particular solution: V cos ωt = Vcp (cos (ωt − φ) + ωRC sin (ωt − φ)) Note the trigonometric identities: cos (ωt − φ) = cos φ cos ωt + sin φ sin ωt sin (ωt − φ) = − sin φ cos ωt + cos φ sin ωt Since the sine and cosine terms are orthogonal, we can equate coefficients of sine and cosine to get: V = Vcp [cos φ + ωRC sin φ] 0 = Vcp [sin φ + ωRC cos φ] The second of these can be solved for the phase angle: φ = tan−1 ωRC and squaring both equations and adding: V 2 = Vcp 2 1 + (ωRC)2 so that the particular solution is: V vcp = cos (ωt − φ) 2 1 + (ωRC) Finally, if the capacitor is initially uncharged (vc (t = 0+) = 0), we can add in the homogeneous solution (we already know the form of this), and find the total solution to be: V t vc p = cos (ωt − φ) − cos φe− RC 1 + (ωRC)2 This is shown in Figure 28 17 R=1, C=1, OM = 10 0.8 0.6 0.4 0.2 0 Vcp −0.2 −0.4 −0.6 −0.8 −1 −1.2 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 t Figure 28: Output Voltage for RC Example 10.3 Second-Order System Example R1 R2 + + v L i1 L vo s i − 2 − Figure 29: Two-Inductor Circuit Figure 29 shows a network with two inductances and two resistances. Assume that this is driven by a voltage step: vs = Vs u−1 (t). Note that, with two inductances, we will require two initial conditions to complete the solution. The steady state (particular) solution is vo = 0. There will, of course, be current flowing in each of the inductances, but if excitation is constant there will be no time derivative of current so that voltage across each of the inductances will eventually fall to zero. The initial conditions may be found by inspection. Right after t = 0 (note we use t = 0+ for this), output voltage must be: vo (t = 0+) = Vs This must be so since current cannot be made to flow instantaneously in either inductance, so that there is no current in either resistance. 18 The second initial condition is the rate of change of voltage right after the instant of the voltage step. To find this, note that output voltage is equal to the source voltage minus the voltage drops across each of the two resistances. vo = vs − R2 i2 − R1 (i1 + i2 ) If we differentiate this with respect to time and note that the time derivative of a constant (after the step the input voltage is constant) is zero: dvo di2 di1 (t = 0+) = −(R1 + R2 ) − R1 dt dt dt Now, since right after the instant of the step both inductances have the source voltage Vs across them: di1 di2 Vs |t=0+ = |t=0+ = dt dt L the rate of change of voltage at t = 0+ is: dvo 2R1 + R2 |t=0+ = − Vs dt L Now, we can find the homogeneous solution using the loop method. Setting the source to zero, assume a current ia in the left-hand loop and ib in the right-hand loop. KVL around these two loops yields: d R1 ia + L (ia − ib ) = 0 dt dib dia R2 ib + 2L −L = 0 dt dt With a little manipulation, these become: dia L + 2R1 ia + R2 ib = 0 dt dib L + R1 i a + R2 i b = 0 dt Assume that solutions are of the form Iest , and this set of simultaneous equations becomes: (sL + 2R1 ) R2 Ia 0 = R1 (sL + R2 ) Ib 0 We need to solve this for s (to find values of s for which this set is true, and that is simply the solution of the “characteristic equation” (sL + 2R1 ) (sL + R2 ) − R1 R2 = 0 which is the same as: 2R1 + R2 R1 R2 s2 + s+ =0 L L L 19 Now, for the sake of “nice numbers”, assume that R1 = 2R, R2 = 3R. The characteristic equation is: 2 R R s2 + 7 s + 6 =0 L L which factors nicely into (s + R R R R L )(s + 6 L ) = 0, or the two values of s are s = − L and s = −6 L. Since the particular solution to this one is zero, we have a total solution which is: R R vo = Ae− L t + Be−6 L t The initial conditions are: vo |t=0+ = A + B = Vs dvo R R |t=0+ = − (A + 6B) = −7 Vs dt L L The solution to that pair of expressions is: Vs 6Vs A=− B= 5 5 and this is shown in Figure 30. Two Inductor Example 1.2 1 0.8 0.6 Vo 0.4 0.2 0 −0.2 0 0.5 1 1.5 2 2.5 3 3.5 4 4.5 5 t Figure 30: Output Voltage for Two Inductor Example 20 MIT OpenCourseWare http://ocw.mit.edu 6.061 / 6.690 Introduction to Electric Power Systems Spring 2011 For information about citing these materials or our Terms of Use, visit: http://ocw.mit.edu/terms.