Search

Processing math: 100%

Filter Results
Location
- Bookshelves (99)
- Campus Bookshelves (22)
Classification
- Article type
  - Book or Unit
  - Chapter
  - Section or Page
  - N/A
  - N/A
- Stage
  - Stub
  - Draft
  - Review
  - Final
  - Outdated
  - Obsolete
- Author
  - Jiří Lebl
  - David Guichard
  - Larry Green
  - Isaiah Lankham, Bruno Nachtergaele, & Anne Schilling
  - David Cherney, Tom Denton, & Andrew Waldron
  - Tom Denton
  - Faraz Hussain
  - Carl Stitz & Jeff Zeager
  - OpenStax
  - Pamini Thangarajah
  - Michael Corral
  - Kenneth Bogart
  - Gregory Hartman (Apex)
  - Paul Seeburger
  - Hiroki Sayama
  - Robert Hanneman & Mark Riddle
  - Eugene Boman & Robert Rogers
  - Harris Kwong
  - Wissam Raji
  - Niels Walet
  - Michelle Manes
  - Christopher Leary & Lars Kristiansen
  - Active Calculus
  - David Lippman & Melonie Rasmussen
  - Ted Sundstrom & Steven Schlicker
  - Henri Feiner
  - Oscar Levin
  - William F. Trench
  - Jay Abramson
  - Gilbert Strang & Edwin “Jed” Herman
  - Ted Sundstrom
  - Victor Shoup
  - Kyle Siegrist
  - Ken Kuttler
  - David Arnold
  - Elias Zakon
  - Kristin Kuter
  - Stephen Wiggins
  - Jean-Paul Olivier
  - Leo Moser
  - Richard Hammack
  - Dan Sloughter
  - Paul Pfeiffer
  - Joe Fields
  - Dave Witte Morris & Joy Morris
  - Jonathan A. Poritz
  - Inigo et al.
  - Illustrative Mathematics
  - Henry Africk
  - Mary Cameron
  - David Lippman
  - Richard W. Beveridge
  - Rupinder Sekhon and Roberta Bloom
  - James L. Cornette & Ralph A. Ackerman
  - Darlene Diaz
  - ElHitti, Bonanome, Carley, Tradler, & Zhou
  - Jeremy Orloff
  - Jens Høyrup
  - Lafferriere, Lafferriere, and Nguyen
  - Amy Lagusker
  - Denny Burzynski & Wade Ellis, Jr.
  - Steve Cox
  - Peter Staab
  - Brendan Fong & David I. Spivak
  - Morgan Chase
  - Peter L. Moore
  - Anton Petrunin
  - W. Keith Nicholson
  - Sanjoy Mahajan
  - Joy Morris
  - J. J. P. Veerman
  - Julie Harland
  - The NROC Project
  - Amy Givler Chapman, Meagan Herald, Jessica Libertini
  - Dirk Colbry
  - CK12
  - Randy Robertson
  - Shana Calaway, Dale Hoffman, David Lippman
  - Dan Margalit & Joseph Rabinoff
  - Juan Carlos Ponce Campuzano
  - Sarah Adams
  - Michael P. Hitchman
  - Al Doerr & Ken Levasseur
  - W. Edwin Clark
  - Alexandre Borovik & Tony Gardiner
  - David Austin
  - Thomas W. Judson
  - Jennifer Firkins Nordstrom
  - Victoria Dominguez, Cristian Martinez, & Sanaa Saykali
  - Michael Janssen & Melissa Lindsey
  - László Tisza
  - Jeremy Sylvestre
  - Jenny Freidenreich
  - Jessica K. Sklar
  - Mike May, S.J. & Anneke Bart
  - Leah Griffith, Veronica Holbrook, Johnny Johnson & Nancy Garcia
  - David W. Lyons
  - Thomas Tradler and Holly Carley
  - Tyler Seacrest
  - Matthew Salomone
  - CLP Calculus Textbooks
  - Jeffrey R. Chasnov
  - Erich Miersemann
  - Russell Herman
  - Mark A. Fitch
  - Joaquín López Herraiz
  - Kelly Brooks
  - Mike Barrus & W. Edwin Clark
  - Stephen Davies
  - Anonymous
  - Katherine Skelton
  - Dana Ernst
  - Mitchel T. Keller & William T. Trotter
  - Wendy Tagami & Liz Girard
  - Bob Dumas and John E. McCarthy
  - Evgeny Demidov
  - Autar Kaw
  - Allen B. Downey
  - Wayne Bishop
  - Katherine Yoshiwara
  - Stuart Brorson
  - Roy Simpson
  - Leah Edelstein-Keshet
  - Luis R. Izquierdo, Segismundo S. Izquierdo and William H. Sandholm
  - Eunice Graham
  - Denny Burzynski
  - Chau D Tran
  - Stanislav A. Trunov and Elizabeth J. Hale
  - Leanne Merrill
  - Silvanus P. Thompson
  - Carnegie Math Pathways/WestEd
  - Zoya Kravets
  - Isabel K. Darcy
  - Holly Carley and Ariane Masuda
  - Karen Cliffe
  - Anurag Pande, Peyton Ratto, and Ahmed Farid
  - H. Jerome Keisler
  - Leif Jordan
  - Jim Hefferon
  - James Milne
  - Lydia de Wolf
  - Anton Butenko
  - Hung Dinh
  - Ken Huber
- Embed Hypothes.is?
  - yes
- Cover Page
  - yes
  - TOC Only
  - Compile but don't publish
- License
  - Public Domain
  - CC BY
  - CC BY-SA
  - CC BY-NC-SA
  - CC BY-ND
  - CC BY-NC-ND
  - GNU GPL
  - All Rights Reserved
  - CC BY-NC
  - GNU FDL
  - CK-12
- Show Page TOC
  - yes
  - no
- Transcluded
  - yes
- PrintOptions
  - No Header/Footer
  - No Title
  - No Header/Footer/Title
- OER program or Publisher
  - College of the Canyons - Zero Textbook Cost Program
  - ASCCC OERI Program
  - CK-12
  - OpenStax
  - GALILEO
  - OpenSUNY
  - MIT OpenCourseWare
  - Virginia Tech Libraries' Open Education Initiative
  - The Publisher Who Must Not Be Named
  - eCampusOntario
  - WAC Clearinghouse
  - BC Campus
  - Lumen
  - Open Oregon
  - OpenStax CNX
  - PDXOpen
  - Evergreen Valley College
- Autonumber Section Headings
  - title with space delimiters
  - title with colon delimiters
  - title with dash delimiters
- License Version
  - 1.0
  - 2.0
  - 2.5
  - 3.0
  - 4.0
  - 1.3
  - 1.2
- Print CSS
  - Default
  - Dense
  - Virginia Tech
- Screen CSS
  - Default
  - Virginia Tech
  - Cosmology
Include attachments
- Content Type
  - Document
  - Image
  - Other

4: Vector Geometry
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/04%3A_Vector_Geometry
12.2: Proofs
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/12%3A_Appendices/12.02%3A_Proofs
We must show that $p \Rightarrow q$ where $p$ is the statement “ $2^n - 1$ is a prime”, and $q$ is the statement “ $n$ is a prime.” Suppose that $p$ is true but $q$ is false so that $n$ ...We must show that $p \Rightarrow q$ where $p$ is the statement “ $2^n - 1$ is a prime”, and $q$ is the statement “ $n$ is a prime.” Suppose that $p$ is true but $q$ is false so that $n$ is not a prime, say $n = ab$ where $a \geq 2$ and $b \geq 2$ are integers.
Front Matter
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/00%3A_Front_Matter
2: Matrix Algebra
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/02%3A_Matrix_Algebra
In the study of systems of linear equations in Chapter [chap:1], we found it convenient to manipulate the augmented matrix of the system. In addition to originating matrix theory and the theory of det...In the study of systems of linear equations in Chapter [chap:1], we found it convenient to manipulate the augmented matrix of the system. In addition to originating matrix theory and the theory of determinants, he did fundamental work in group theory, in higher-dimensional geometry, and in the theory of invariants.
10: Inner Product Spaces
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/10%3A_Inner_Product_Spaces
6.5: An Application to Polynomials
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/06%3A_Vector_Spaces/6.05%3A_An_Application_to_Polynomials
Here the numerator is the product of all the terms $(x - a_{0}), (x - a_{1}), \dots, (x - a_{n})$ with $(x - a_{k})$ omitted, and a similar remark applies to the denominator. \[\begin{aligned} \de...Here the numerator is the product of all the terms $(x - a_{0}), (x - a_{1}), \dots, (x - a_{n})$ with $(x - a_{k})$ omitted, and a similar remark applies to the denominator. $\begin{aligned} \delta_0 & = \frac{(x - 0)(x - 1)}{(-1 - 0)(-1 - 1)} = \frac{1}{2}(x^2 - x) \\ \delta_1 & = \frac{(x + 1)(x - 1)}{( 0 + 1)( 0 - 1)} = -(x^2 - 1) \\ \delta_2 & = \frac{(x + 1)(x - 0)}{( 1 + 1)( 1 - 0)} = \frac{1}{2}(x^2 + x)\end{aligned} \nonumber$
5.5: Similarity and Diagonalization
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/05%3A_Vector_Space_R/5.05%3A_Similarity_and_Diagonalization
Hence the eigenvalues are $\lambda_{1} = i$ and $\lambda_{2} = -i$ , with corresponding eigenvectors $\mathbf{x}_1 = \left[ \begin{array}{r} 1 \\ -i \end{array} \right]$ and \(\mathbf{x}_2 = \lef...Hence the eigenvalues are $\lambda_{1} = i$ and $\lambda_{2} = -i$ , with corresponding eigenvectors $\mathbf{x}_1 = \left[ \begin{array}{r} 1 \\ -i \end{array} \right]$ and $\mathbf{x}_2 = \left[ \begin{array}{r} 1 \\ i \end{array} \right].$ Hence $A$ is diagonalizable by the complex version of Theorem [thm:016145], and the complex version of Theorem [thm:016068] shows that \(P = \left[ $\begin{array}{cc} \mathbf{x}_1\ & \mathbf{x}_2 \end{array}$ \right]= \left[ \begin{array}{rr} 1 & 1 …
5.2: Independence and Dimension
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/05%3A_Vector_Space_R/5.02%3A_Independence_and_Dimension
Some spanning sets are better than others. Our interest here is in spanning sets where each vector in U has exactly one representation as a linear combination of these vectors.
4.5: An Application to Computer Graphics
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/04%3A_Vector_Geometry/4.05%3A_An_Application_to_Computer_Graphics
On the other hand, we can rotate the letter about the origin through $\frac{\pi}{6}$ (or $30^\circ$ ) by multiplying by the matrix \(R_{\frac{\pi}{2}} = \left[ \def\arraystretch{1.5}\begin{array}{r...On the other hand, we can rotate the letter about the origin through $\frac{\pi}{6}$ (or $30^\circ$ ) by multiplying by the matrix $R_{\frac{\pi}{2}} = \left[ \def\arraystretch{1.5}\begin{array}{rr} \cos(\frac{\pi}{6}) & -\sin(\frac{\pi}{6})\\ \sin(\frac{\pi}{6}) & \cos(\frac{\pi}{6}) \end{array} \right] = \left[ \begin{array}{ll} 0.866 & -0.5\\ 0.5 & 0.866 \end{array} \right]$ .
4.2: Projections and Planes
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/04%3A_Vector_Geometry/4.02%3A_Projections_and_Planes
Any student of geometry soon realizes that the notion of perpendicular lines is fundamental.
2.8: An Application to Input-Output Economic Models
https://math.libretexts.org/Bookshelves/Linear_Algebra/Linear_Algebra_with_Applications_(Nicholson)/02%3A_Matrix_Algebra/2.08%3A_An_Application_to_Input-Output_Economic_Models
Thus, the pricing must be such that the total output of the farming industry has the same value as the total output of the garment industry, whereas the total value of the housing industry must be \(\...Thus, the pricing must be such that the total output of the farming industry has the same value as the total output of the garment industry, whereas the total value of the housing industry must be $\frac{3}{2}$ as much. If $p_{i}$ and $e_{ij}$ are as before, the value of the annual demand for product $i$ by the producing industries themselves is $e_{i1}p_{1} + e_{i2}p_{2} + \cdots + e_{in}p_{n}$ , so the total annual revenue $p_{i}$ of industry $i$ breaks down as follows:

Search

Text Color

Text Size

Margin Size

Font Type

Support Center

How can we help?