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ECE493-F21

Syllabus: pdf-2018, pdf-2009; Listing: ECE-493, (Math-487) Campus (Official): ECE, Math
Calendars:\A Campus;
Time/place: Zoom: ID: 965 0165 0571, PW: 146870;
360 recordings of all classes No logins required; Videos by course number: PUBLIC ACCESS to all ECE410 Lectures (videos): 2021, 2022
Video Lectures ECE 493 Video
- Office Hours: F 11-11:59AM; Location TBD; Zoom: ID: 965 0165 0571, PW: 146870;
Text: An Invitation to Mathematical Physics pdf, Greenberg: supplementary text
Gradescope code: D5G555
FAQ: 360 Documentation
Instructor: Prof. Jont Allen (217)_369_7711c; (netID: jontalle@; Office 3062-ECEB); TA: Billy Walters [wcw5 @ illinois.edu]
Extra hour credit ISUR mentoring includes $600 overhead
Fantastic math videos, such as James Clerk Maxwell
Matlab Tutorial pdf
Homework must be submitted to gradescope Entry Code: D5G555
How to electronically edit pdf files (homework and exams): xournalpp (PC-based pdf-editing) OR xodo.com: Web-based pdf-editing AND an incomplete Review of 8 pdf editors
University guidlines
- COVID-19 on-campus testing twice per week is required for ALL students and 1 per week for staff, for those who are on-campus for any length of time.
  Mandatory testing begins on August 10 for faculty and staff and on August 16 for students. See a list of on-campus testing sites here.
This week's Reading schedule; Final

ECE-493/MATH-487 Daily Schedule Fall 2021: An Introduction to Mathematical Physics and its History

Part I: Reading assignments and videos: Complex algebra (14 Lecs)
Week	M	W	F
34	L1: $\S$1, 3.1 (Read p. 1-17) Intro + history; L1.F21@5:00 min; (L1-Z.F20@8:27 min) The size of things;	L2: $\S$3.1,.1,.2 (p. 69-84) Roots of polynomials; Newton's method. L2.F21@11:30 min; (L2-360.F20@3:25 min)	L3: $\S$3.1.3,.4 (p.84-88) Companion matrix L4-Z.F20@0:30 (Eigen-analysis); @1:04 (Companion Matrix) L3.F21-360 (Audio died after 2 sec; (L3-Z.F20@10:35 min)
35	L4: Eigenanalysis: $\S$3.2,.1,.2; Pell & Fibonocci sol.; $\S$B1,B3 L4.F21-360; (L4-Z.F20@0:38)	L5: $\S$3.2.3 Taylor series L5-360.F21 @9:00, (L5-Z.F20) (L5@14:50)	L6: Impedance; residue expansions $\S$3.4.2 L6-360.F21; (L6-360.F20)
36	Labor day	L7: $\S$3.5, Anal Geom, Generalized scalar products (p. 112-121) L7-360.F21@5:15, (L7-360.F20@2:20 min)	L8: $\S$3.5.1-.4 $\cdot, \times, \wedge $ scalar products (L8-360.F20,
37	L9: $\S$3.5.5, $\S$3.6,.1-.5 Gauss Elim; Matrix algebra (systems) L9-360.F21@3:30-Not Zoomed, (L9-360.F20@4:30min)	L10: $\S$3.8,.1-.4 Thevenin parameters; Transmission lines; impedance matrix, Screen_Shot-1, Screen_Shot-2, L10-360.F21@6:10, (L10-360.F20 No audio),	L11: $\S$3.9,.1 ${\cal FT}$ of signals L11-360.F21@13:05 min, (L11-360.F20@8:20 min)
38	L12: $\S$3.10,.1-.3 $\cal LT$ of systems + postulates L12-360.F21@1:30m, (L12-360.F20), L12-Z.F20	L13: $\S$3.11,.1,.2 Complex analytic color maps; Riemann sphere (pdf); Bilinear transform, L13-360.21, No Audio (L13-360.F20%red$@13min), L12-Z.F20	L14: Review for Exam I; L14-360.F21; L14-360.F21, L14-360.F20@25min, L14-Z, L14-Z.F20 Exam_Review
39	Exam I; zoom+Gradescope (Code: D5G555)

L/W	D	Date	Part I: Complex algebra (15 Lectures)
			Instruction begins
1/34	M	8/23	L1: Introduction + History; Map of mathematics; Understanding size requires an imagination Assignment: HW0: (pdf); Evaluate your knowledge (not graded); Assignment: NS1; Due Lec 4: NS2; Due Lec 7: NS3; Due Lec 13
2	W	8/25	L2: Newton's method (p. 74) for finding roots of a polynomial $P_n(s_k)=0$ Newton's method; All m files: Allm.zip
3	F	8/27	L3: The companion matrix and its characteristic polynomial:Working with Octave/Matlab: $\S$3.1.4 (p. 86) zviz.m or zvizMay31V4.m 3.11 (p. 167) Introduction to the colorized plots of complex mappings
4/35	M	8/30	L4: Eigenanalysis I: Eigenvalues and vectors of a matrix Singular-value analysis; Assignment: AE1, (Due 1 wk);Solution: AE1-sol Solution: NS1-sol, NS1 due
5	W	9/1	L5: Taylor series
6	F	9/3	L6: Analytic functions; Complex analytic functions; Brune Impedance Residue expansions of ratios of polynomials: $ Z(s)=N(s)/D(s) $
-/36	M	9/6	Labor day: Holiday
7	W	9/8	L7: Analytic geomerty: Vectors and their dot $\cdot$, cross $\times$ and wedge $\wedge$ products. Residues. Colorized plots of complex mappings; View: Mobius/bilinear transform video, As geometry Assignment: AE2; NS2, AE1 due in 1 week; Sol: AE2-sol; Sol: NS2-sol
8	F	9/10	L8: Analytic geometry of two vectors (generalized scalar product) Inverse of 2x2 matrix
9/37	M	9/13	L9: Gaussian Elimination; Permutation matricies; Matrix Taxonomy
10	W	9/15	L10: Transmission and impedance matricies Assignment: AE3, Due in 1 week;AE2 dueSol: NS3-sol;Sol: AE3-sol
11	F	9/17	L11: Fourier transforms of signals; Predicting tides
12/38	M	9/20	L12: Laplace transforms of systems;System postulates
13	W	9/22	L13: Comparison of Laplace and Fourier transforms; Colorized plots; View: Mobius/bilinear transform video NS3, AE3 due
14	F	9/24	L14: Review for Exam I
-/39	M	9/27	Exam I; The exam will be in ECEB-3017 from 9-12, no online local attendance.A paper copy of the exam will be provided. One student in China will be online.

Part II: Reading assignments and videos: Complex algebra (10 Lecs)
Week	M	W	F
39	Exam I	L15: 4.1,4.2,.1 (p. 178) Fundmental Thms of calculus & complex $\mathbb R, \mathbb C$ scalar calculus (FTCC) (LEC-15-360.S20@8:00min), (LEC-15-zoom.S20)	L16: 4.2.2 Cauchy-Riemann Eqs. CR-1, CR-2, CR-3, CR-4 Lec16-360.F21; (LEC-16-360.S20)
40	L17: 4.4 Brune impedance/admittance LEC-17-360.F21, (LEC-17-360.S20)	L18: 4.4,.1,.2 Complex analytic Impedance; Lec-18-360.F21@0:25, (LEC-18-360.S20@2:50,, zoom)	L19: 4.4.3 Multi-valued functions, Branch cuts; LEC-19-360.S21@0:10, (LEC-19-360.S20@0:40,, zoom)
41	L20: 4.5,.1,.2 Cauchy's complex integration thms CT1, CT2, CT3; Lec-20-360.F21, (LEC-20-360.S20 @2:30, @15:45, @22:00)	L21: 4.7,.1,.2 Inv ${\cal LT} (t<0, t=0)$ Lec21-360-S21 @00:30, (LEC-21-360.S20,, zoom)	L22: 4.7.3 Inv ${\cal LT} (t > 0) $ LEC-22-360-S21@0:45, (LEC-22-360.S20)
42	L23: 4.7.4 Properties of the $\cal LT$; Lec-23-360.F21@00:40, (LEC-23-360.S20,, zoom)	L24: 4.7.5 Solving LTI (simple) Diff. Eqs. with the $\cal LT$ Lec-24-360.F21, Lec-24-360.S20 (LEC-24-360.S20, start @5:00 PM, zoom)

L/W	D	Date	Part II: Scalar (ordinary) differential equations (10 Lectures)
15	W	9/29	L15: The fundamental theorems of scalar and complex calculus Assignment: DE1-F21.pdf, (Due 1 wk); DE1-sol.pdf
16	F	10/1	L16: Complex differentiation and the Cauchy-Riemann conditions; Life of Cauchy Properties of complex analytic functions (Harmonic functions);Taylor series of complex analytic functions
17/40	M	10/4	L17: Brune impedance/admittance and complex analytic Ratio of polynomials of similar degree: $ Z(s) = {P_n(s)}/{P_m(s)} $ with $n,m \in {\mathbb N}$ Basic properties of impedance functions (postulates) (e.g., causal, positive real) Complex analytic impedance/admittance is conservative (P3) Colorized plots of Impedance/Admittance functions; View: Mobius/bilinear transform video
18	W	10/6	L18: Generalized impedance Brune vs. generalized impedance/admittance functions (ratio of polynomials; branch cuts) Examples of Colorized plots of Generalized Impedance/Admittance functions; Calculus on complex analytic functions Assignment: DE2-F21.pdf, (Due 1 wk); DE2-sol.pdf;
19	F	10/8	L19: Multi-valued complex analytic functions Branch cuts and their properties (e.g., moving the branch cut) Examples of multivalued function; Colorized plots of multivalued functions: e.g.: $ F(s) = \sqrt{s e^{jk2\pi}} $ where $k\in{\mathbb N}$ is the sheet index; Balakrishnan Lecture $F(s)=\sqrt{s}$
20/41	M	10/11	L20: Three Cauchy integral theorems: CT-1, CT-2, CT-3 How to calculate the residue
21	W	10/13	L21: Inverse Laplace transform ($t<0$), Application of CT-3 DE2 Due Assignment: DE3-F21.pdf, (Due 1 wk); DE3-sol.pdf
22	F	10/15	L22: Inverse Laplace transform ($t\ge0$) CT-3 Differences between the FT and LT; System postulates: P1, P2, P3, etc. $\S 3.10.2$, p. 162-164;
23/42	M	10/18	L23: Properties of the Laplace transform: Linearity, convolution, time-shift, modulation, derivative etc; Introduction to the Train problem and why it is important.
24	W	10/20	L24: Solving differential equations: Train problem (DE3, problem 2, p. 206) Fig. 4.11) DE3 Due

Part III: Reading assignments: Vector calculus (9 lectures)
Week	M	W	F
42			L25: 5.1.1 (p. 227) Fields and potentials (VC-1); LEC-26-360.F21 @2:00 min, (LEC-25-zoom.S20)
43	L26: 5.1,.2,.3 (p. 229): $\nabla()$, $\nabla \cdot()$, $\nabla \times()$, $\nabla \wedge()$, $\nabla^2() $: Differential and integral forms (LEC-26-360.S20@3:00), (zoom)	L27: 5.2 Field evolution $\S$ 5.2 (p. 242) Lec-27-360.F21; Cont of Lec 26, (LEC-27-360.S20@3:22), (zoom)	L28: 5.2: Field evolution $\S$5.2.1, 5.2.1.1, .2 (pp 242-246); & Scalar Wave Equation $\S$5.2.2 p. 246; Lec-28-360.F21@0:45, (LEC-28-360.S20@3:00min, Acoustics@24m)
44	L29: 5.2.2,.3,5.4.1-.3 (p. 248) Horns Lec29-360.F21 @0:15, (LEC-29-360.S20)	L30: 5.5.1 Solution methods; 5.6.1-.2 Integral forms of $\nabla()$, $\nabla \cdot()$, $\nabla \times() $ Lec 30-360-Review of HWs, Lec 30-360.F21 @0:15, (LEC-30-360.S20)	L31: 5.6.3-.4 Integral forms of $\nabla()$ $\nabla \cdot()$, $\nabla \times() $ (LEC-31-360.S20)
45	L32: 5.6.5 Helmholtz decomposition thm. $ \vec{E} = -\nabla\phi +\nabla \times \vec A $, ( $\S$ 5.6.5, p. 270 ); LEC-32-360.F21 @1.45, (LEC-32-360.S20 @1:30)	L33: 5.6.6 2d-order scalar operators: $ \nabla^2 = \nabla \cdot \nabla() $, Vector operators: $ {\mathbf\nabla}^2 = \nabla \cdot \mathbf\nabla()$, $\nabla \nabla \cdot()$, $\nabla \times \nabla() $; Null operators: $\nabla \cdot \nabla \times()=0$, $\nabla \times \nabla ()=0 $ Lec-33-360.F21 @0:45, (LEC-33-360.S20); DE1,2,3 solutions.zip	L34: Unification of E & M; terminology (Tbl 5.4, p. 288); View: Symmetry in physics (LEC-34-360.S20)

L/W	D	Date	Part III: Vector Calculus (10 Lectures)
25/42	F	10/22	L25: Properties of Fields and potentials Assignment: VC1.pdf, Due Lec-37; VC1-sol.pdf
26/43	M	10/25	L26: Gradient $\nabla$, Divergence $\nabla \cdot$, Curl $\nabla \times$, Laplacian $\nabla^2$; Integral vs differential definitions; Integral and conservation laws: Gauss, Green, Stokes, Divergence; Vector identies in various coordinate systems; Laplacian in $N$ dimensions
27	W	10/27	L27: Field evolution for partial differential equations $\S$ 5.2; bubbles of air in water; Vector fields; Poincare Conjucture: Proved
28	F	10/29	L28: Review Field evolution $\S$5.2.1,.2 & Scalar wave equation (e.g., Acoustics) $\S$5.2.3
29/44	M	11/1	L29: Webster Horn equation Three examples of finite length horns; Solution methods; Eigen-function solutions (Tesla acoustic valve)
30	W	11/3	L30: Solution methods; Integral forms of $\nabla()$, $\nabla\cdot()$ and $\nabla \times()$
31	F	11/5	L31: Integral form of curl: $\nabla \times()$ and Wedge-product (p. 269)
32/45	M	11/8	L32: Helmholtz decomposition theorem for scalar and vector potentials; (p. 270); Prandt Boundary Layers,
33	W	11/10	L33: Second order operators DoG, GoD, gOd, DoC, CoG, CoC
34	F	11/12	L34: Unification of E & M; terminology (Tbl 5.4); Review for Exam II

Part IV: Reading assignments: Maxwell's equations + solutions (7 lectures)
Week	M	W	F
46	Exam II @ 8-11 AM; Gradescope+Zoom + Room 3017 ECEB	L35: 5.7.1-.3 Maxwell's equations LEC-35-360.F21 @1&36 min, (LEC-35-360.S20 @00:30)	L36: Derivation of ME $\S$5.7.4,.8, p. 281-5; LEC-36-360.F21 @1, (LEC-36-360.S20 @2)
47	Thanksgiving Holiday
48	L37: 5.8 Use of Helmholtz' Thm on ME LEC-37-360.F21,, (LEC-37-360.S20)	L38: 5.8 Helmholtz solutions of ME Lec-38-360.F21; (LEC-38-360.S20) $\S5.6.5$ Tbl 5.3	L39: 5.8 Analysis of simple impedances (Inductors & capacitors) Lec-29-360.F21, (LEC-39-360.S20)
49	L40: Stokes's Curl theorem & Gauss's divergence theorem; LEC-40-360.F21 @3:30, (LEC-40-360.S20)	L41: Review (LEC-41-360.S20)	Thur: Optional Review for Final; Reading Day

L/W	D	Date	Part IV: Maxwell's equation with solutions
-/46	M	11/15	Exam II; No Class Assignment: VC-1 Due Lec 37
35	W	11/17	L35: Derivation of the wave equation from Eqs: EF and MF; Webster Horn equation: vs separation of variables method + integration by parts;
36	F	11/19	L36: Derivation of Maxwell's Equations $\S$ 5.7.4 (p. 280),Transmission line theory: Lumped parameter approximation: 1D & 2D vs. 3D: $\S 5.7.4 (p. 280)$ d'Alembert solution of wave Equation; Poynting vector; Problem of light bulb in series with a very long pair of wires (e.g., to the moon, or sun & further); Telegraph equation, Wave equation (Parabolic, hyperbolic, elliptical); Diffusion,, Role of the Mobius Transformation
-/47	S	11/22	Thanksgiving Break
37/48	M	11/29	L37: Helmholtz' Thm: The fundamental thm of vector calculus $\mathbf{F}(x,y,z) = \nabla{\phi(x,y,z)} + \nabla \times \mathbf{A}(x,y,z)$; As applied to Maxwell's Equations. Recall: incompressible: $\nabla \cdot \mathbf{u} =0$ and irrotational: $\nabla \times \mathbf{w} =0$ VC-1 Due; VC2.pdf VC-2: due Lec: 41; VC2-sol
38	W	12/1	L38: Properties of 2d-order operators; $\S5.6.5$ Table 5.3 p. 270; OliverHeaviside, Nyquist proof of 4ktB noise floor (Add a HW problem on Thermal Noise in resistors), L10: Summary,
39	F	12/3	L39: Derivation of the vector wave equation
40/49	M	12/6	L40: Physics and Applications; ME vs quantum mechanics; Video demos re ME
41	W	12/8	L41: Review of entire course (very brief) VC-2 due; VC2-sol

-	R	12/9	Reading Day
-	R	12/9	Optional Q&A Review for Final (no lec): 9-11 Room: 3017 ECEB + Zoom + Gradescope
-	M	12/13	Final Exam: Zoom + Room: 3017 ECEB; UIUC Official Final Exam Schedule: If the class starts on Monday at 10:00 AM: The exam is scheduled for Dec 13, Monday, 1:00-5:00 PM
-/50	F	12/17	Finals End
		12/24	Final grade analysis

Edits 2 here Block-comments

 ||- ||F||5/50||  Backup: Exam III 7:00-10:00+ PM on HW1-HW11atest>><<

L= Lecture #
T= Topic #
W=week of the year, starting from Jan 1
D=day: T is Tue, W Wed, R Thur, S Sat, etc.
The somewhat random-ordered numbers in front of many (not all) topics are the topic numbers defined in 2009 Syllabus Δ:
ECE-493 is divided into 4 basic sections (I-IV), divided into 40 topics, delivered as 24=4*6 lectures. There are two mid-term exams and one final. There are 12 homework assignments, with a HW0 that does not count toward your final grade. Each exam (I, II and Final) will count as 30% of your final grade, while the Assignments (HW1-12) plus class participation (Prof's Discuression), count for 10%.

Week	M	W	F
34	L1: \(\S\)1, 3.1 (Read p. 1-17) Intro + history; L1.F21@5:00 min; (L1-Z.F20@8:27 min) The size of things;	L2: \(\S\)3.1,.1,.2 (p. 69-84) Roots of polynomials; Newton's method. L2.F21@11:30 min; (L2-360.F20@3:25 min)	L3: \(\S\)3.1.3,.4 (p.84-88) Companion matrix L4-Z.F20@0:30 (Eigen-analysis); @1:04 (Companion Matrix) L3.F21-360 (Audio died after 2 sec; (L3-Z.F20@10:35 min)
35	L4: Eigenanalysis: \(\S\)3.2,.1,.2; Pell & Fibonocci sol.; \(\S\)B1,B3 L4.F21-360; (L4-Z.F20@0:38)	L5: \(\S\)3.2.3 Taylor series L5-360.F21 @9:00, (L5-Z.F20) (L5@14:50)	L6: Impedance; residue expansions \(\S\)3.4.2 L6-360.F21; (L6-360.F20)
36	Labor day	L7: \(\S\)3.5, Anal Geom, Generalized scalar products (p. 112-121) L7-360.F21@5:15, (L7-360.F20@2:20 min)	L8: \(\S\)3.5.1-.4 \(\cdot, \times, \wedge \) scalar products (L8-360.F20,
37	L9: \(\S\)3.5.5, \(\S\)3.6,.1-.5 Gauss Elim; Matrix algebra (systems) L9-360.F21@3:30-Not Zoomed, (L9-360.F20@4:30min)	L10: \(\S\)3.8,.1-.4 Thevenin parameters; Transmission lines; impedance matrix, Screen_Shot-1, Screen_Shot-2, L10-360.F21@6:10, (L10-360.F20 No audio),	L11: \(\S\)3.9,.1 \({\cal FT}\) of signals L11-360.F21@13:05 min, (L11-360.F20@8:20 min)
38	L12: \(\S\)3.10,.1-.3 \(\cal LT\) of systems + postulates L12-360.F21@1:30m, (L12-360.F20), L12-Z.F20	L13: \(\S\)3.11,.1,.2 Complex analytic color maps; Riemann sphere (pdf); Bilinear transform, L13-360.21, No Audio (L13-360.F20%red$@13min), L12-Z.F20	L14: Review for Exam I; L14-360.F21; L14-360.F21, L14-360.F20@25min, L14-Z, L14-Z.F20 Exam_Review
39	Exam I; zoom+Gradescope (Code: D5G555)

Week	M	W	F
42			L25: 5.1.1 (p. 227) Fields and potentials (VC-1); LEC-26-360.F21 @2:00 min, (LEC-25-zoom.S20)
43	L26: 5.1,.2,.3 (p. 229): \(\nabla()\), \(\nabla \cdot()\), \(\nabla \times()\), \(\nabla \wedge()\), \(\nabla^2() \): Differential and integral forms (LEC-26-360.S20@3:00), (zoom)	L27: 5.2 Field evolution \(\S\) 5.2 (p. 242) Lec-27-360.F21; Cont of Lec 26, (LEC-27-360.S20@3:22), (zoom)	L28: 5.2: Field evolution \(\S\)5.2.1, 5.2.1.1, .2 (pp 242-246); & Scalar Wave Equation \(\S\)5.2.2 p. 246; Lec-28-360.F21@0:45, (LEC-28-360.S20@3:00min, Acoustics@24m)
44	L29: 5.2.2,.3,5.4.1-.3 (p. 248) Horns Lec29-360.F21 @0:15, (LEC-29-360.S20)	L30: 5.5.1 Solution methods; 5.6.1-.2 Integral forms of \(\nabla()\), \(\nabla \cdot()\), \(\nabla \times() \) Lec 30-360-Review of HWs, Lec 30-360.F21 @0:15, (LEC-30-360.S20)	L31: 5.6.3-.4 Integral forms of \(\nabla()\) \(\nabla \cdot()\), \(\nabla \times() \) (LEC-31-360.S20)
45	L32: 5.6.5 Helmholtz decomposition thm. \( \vec{E} = -\nabla\phi +\nabla \times \vec A \), ( \(\S\) 5.6.5, p. 270 ); LEC-32-360.F21 @1.45, (LEC-32-360.S20 @1:30)	L33: 5.6.6 2d-order scalar operators: \( \nabla^2 = \nabla \cdot \nabla() \), Vector operators: \( {\mathbf\nabla}^2 = \nabla \cdot \mathbf\nabla()\), \(\nabla \nabla \cdot()\), \(\nabla \times \nabla() \); Null operators: \(\nabla \cdot \nabla \times()=0\), \(\nabla \times \nabla ()=0 \) Lec-33-360.F21 @0:45, (LEC-33-360.S20); DE1,2,3 solutions.zip	L34: Unification of E & M; terminology (Tbl 5.4, p. 288); View: Symmetry in physics (LEC-34-360.S20)

Week	M	W	F
46	Exam II @ 8-11 AM; Gradescope+Zoom + Room 3017 ECEB	L35: 5.7.1-.3 Maxwell's equations LEC-35-360.F21 @1&36 min, (LEC-35-360.S20 @00:30)	L36: Derivation of ME \(\S\)5.7.4,.8, p. 281-5; LEC-36-360.F21 @1, (LEC-36-360.S20 @2)
47	Thanksgiving Holiday
48	L37: 5.8 Use of Helmholtz' Thm on ME LEC-37-360.F21,, (LEC-37-360.S20)	L38: 5.8 Helmholtz solutions of ME Lec-38-360.F21; (LEC-38-360.S20) \(\S5.6.5\) Tbl 5.3	L39: 5.8 Analysis of simple impedances (Inductors & capacitors) Lec-29-360.F21, (LEC-39-360.S20)
49	L40: Stokes's Curl theorem & Gauss's divergence theorem; LEC-40-360.F21 @3:30, (LEC-40-360.S20)	L41: Review (LEC-41-360.S20)	Thur: Optional Review for Final; Reading Day