Vector subspaces of continuous functions












0














Let $V = C^0 [a, b]$ be the set of all real-valued continuous functions on the domain $[a, b]$. Which of the following subsets $W_1,W_2$ are subspaces of $V$?



$W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



$W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



Okay, I know to show that $W$ is a subspace of $V$:



a. $W$ is non-empty.



b. if $x_1, x_2 in W$ then $x_1 + x_2 in W$



c. for $k in R, kx_1 in W$










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  • Do you know the list of things that a subspace must satisfy?
    – Joe Johnson 126
    Oct 6 '13 at 22:11










  • yes I do, I'm just not sure how to go about showing it.
    – Zhoe
    Oct 6 '13 at 22:15












  • Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
    – Gerry Myerson
    Oct 6 '13 at 22:44










  • OK, good start. Now: can you show $W_1$ is non-empty?
    – Gerry Myerson
    Oct 6 '13 at 23:09






  • 2




    The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
    – egreg
    Oct 6 '13 at 23:41
















0














Let $V = C^0 [a, b]$ be the set of all real-valued continuous functions on the domain $[a, b]$. Which of the following subsets $W_1,W_2$ are subspaces of $V$?



$W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



$W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



Okay, I know to show that $W$ is a subspace of $V$:



a. $W$ is non-empty.



b. if $x_1, x_2 in W$ then $x_1 + x_2 in W$



c. for $k in R, kx_1 in W$










share|cite|improve this question
















bumped to the homepage by Community 18 hours ago


This question has answers that may be good or bad; the system has marked it active so that they can be reviewed.















  • Do you know the list of things that a subspace must satisfy?
    – Joe Johnson 126
    Oct 6 '13 at 22:11










  • yes I do, I'm just not sure how to go about showing it.
    – Zhoe
    Oct 6 '13 at 22:15












  • Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
    – Gerry Myerson
    Oct 6 '13 at 22:44










  • OK, good start. Now: can you show $W_1$ is non-empty?
    – Gerry Myerson
    Oct 6 '13 at 23:09






  • 2




    The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
    – egreg
    Oct 6 '13 at 23:41














0












0








0







Let $V = C^0 [a, b]$ be the set of all real-valued continuous functions on the domain $[a, b]$. Which of the following subsets $W_1,W_2$ are subspaces of $V$?



$W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



$W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



Okay, I know to show that $W$ is a subspace of $V$:



a. $W$ is non-empty.



b. if $x_1, x_2 in W$ then $x_1 + x_2 in W$



c. for $k in R, kx_1 in W$










share|cite|improve this question















Let $V = C^0 [a, b]$ be the set of all real-valued continuous functions on the domain $[a, b]$. Which of the following subsets $W_1,W_2$ are subspaces of $V$?



$W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



$W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



Okay, I know to show that $W$ is a subspace of $V$:



a. $W$ is non-empty.



b. if $x_1, x_2 in W$ then $x_1 + x_2 in W$



c. for $k in R, kx_1 in W$







vector-spaces






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share|cite|improve this question













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edited Oct 6 '13 at 23:04

























asked Oct 6 '13 at 22:08









Zhoe

2,1261812




2,1261812





bumped to the homepage by Community 18 hours ago


This question has answers that may be good or bad; the system has marked it active so that they can be reviewed.







bumped to the homepage by Community 18 hours ago


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  • Do you know the list of things that a subspace must satisfy?
    – Joe Johnson 126
    Oct 6 '13 at 22:11










  • yes I do, I'm just not sure how to go about showing it.
    – Zhoe
    Oct 6 '13 at 22:15












  • Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
    – Gerry Myerson
    Oct 6 '13 at 22:44










  • OK, good start. Now: can you show $W_1$ is non-empty?
    – Gerry Myerson
    Oct 6 '13 at 23:09






  • 2




    The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
    – egreg
    Oct 6 '13 at 23:41


















  • Do you know the list of things that a subspace must satisfy?
    – Joe Johnson 126
    Oct 6 '13 at 22:11










  • yes I do, I'm just not sure how to go about showing it.
    – Zhoe
    Oct 6 '13 at 22:15












  • Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
    – Gerry Myerson
    Oct 6 '13 at 22:44










  • OK, good start. Now: can you show $W_1$ is non-empty?
    – Gerry Myerson
    Oct 6 '13 at 23:09






  • 2




    The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
    – egreg
    Oct 6 '13 at 23:41
















Do you know the list of things that a subspace must satisfy?
– Joe Johnson 126
Oct 6 '13 at 22:11




Do you know the list of things that a subspace must satisfy?
– Joe Johnson 126
Oct 6 '13 at 22:11












yes I do, I'm just not sure how to go about showing it.
– Zhoe
Oct 6 '13 at 22:15






yes I do, I'm just not sure how to go about showing it.
– Zhoe
Oct 6 '13 at 22:15














Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
– Gerry Myerson
Oct 6 '13 at 22:44




Well, since you know what you have to show, why not make a start on showing it, and we'll help you when you get stuck. Start by writing out what it is that you have to do to show something is a subspace.
– Gerry Myerson
Oct 6 '13 at 22:44












OK, good start. Now: can you show $W_1$ is non-empty?
– Gerry Myerson
Oct 6 '13 at 23:09




OK, good start. Now: can you show $W_1$ is non-empty?
– Gerry Myerson
Oct 6 '13 at 23:09




2




2




The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
– egreg
Oct 6 '13 at 23:41




The question is ill posed. What are the unbounded continuous functions on $[a,b]$? And what's the meaning of “$f(-x)=f(x)$ for all $x$” if $[a,b]=[1,2]$?
– egreg
Oct 6 '13 at 23:41










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$W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



a. $W_1$ is non- empty.



$f(x) = 0$



$|0| le M$



$0 le M$



since $M in R^+$ then $W_1$ is non-empty.



b. if $x_1, x_2 in W_1$ then $x_1 + x_2 in W_1$



$f(x), g(x) in W_1$



$f(x), g(x)$ are continuous and $|f(x)| le M, |g(x)| le N$



show that $h(x) in W_1$ is such that $h(x)$ is continuous and $|h(x)| le P$ for some $P in R^+$



if $f(x)$ and $g(x)$ are continuous at a, then $f(x) + g(x)$ are continuous at a.



$lim{xto_a} f(x) = f(a)$ and $lim{xto_a} g(x) = g(a)$



$lim{xto_a} f(x) + g(x) = lim{xto_a} f(x) + lim{xto_a} g(x) = f(a) + g(a)$, so $f(x) + g(x)$ is continuous.



let $h(x) = f(x) + g(x)$ and therefore $h(x)$ would be continuous.



if $|f(x)| le M, |g(x)| le N$ then $h(x) = |f(x) + g(x)| le M + N in R^+$



let $P = M + N$, therefore $|h(x)| = |f(x) + g(x)| le P in R^+$



since $h(x)$ is continuous and for some $P in R^+ |h(x)| le P, h(x) in W_1$ implies $f(x) + g(x) in W_1$



c. for $k in R, kx_1 in W_1$



similarly for $k in R$



$k cdot lim{xto_a} f(x) = k cdot f(a)$, is continuous at a.



thus, $k cdot f(x) le k cdot M in W_1$



by subspace test, $W_1$ is a subspace of $V$



$W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



a. $W_2$ is non-empty



$f(x) = 0$



$f(-0) = f(0)$
the condition holds, thus $W_2$ is non-empty.



b. if $x_1, x_2 in W_2$ then $x_1 + x_2 in W_2$



$f(x), g(x) in W_2$



they are continuous and $f(-x) = f(x), g(-x) = g(x)$ for all x



this result means that $f$ and $g$ are even functions



$(f + g)(-x) = f(-x) + g(-x) = f(x) + g(x) = (f + g)(x)$ for all x



hence, $f + g$ is also even. therefore $f + g in W_2$



c. for $k in R, kx_1 in W_2$



for $k in R$,



$(kf)(-x) = kf(-x) = k(f(-x)) = k(f(x)) = kf(x)$ for all x



hence $kf$ is even. therefore, $kf in W_2$






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    $W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



    a. $W_1$ is non- empty.



    $f(x) = 0$



    $|0| le M$



    $0 le M$



    since $M in R^+$ then $W_1$ is non-empty.



    b. if $x_1, x_2 in W_1$ then $x_1 + x_2 in W_1$



    $f(x), g(x) in W_1$



    $f(x), g(x)$ are continuous and $|f(x)| le M, |g(x)| le N$



    show that $h(x) in W_1$ is such that $h(x)$ is continuous and $|h(x)| le P$ for some $P in R^+$



    if $f(x)$ and $g(x)$ are continuous at a, then $f(x) + g(x)$ are continuous at a.



    $lim{xto_a} f(x) = f(a)$ and $lim{xto_a} g(x) = g(a)$



    $lim{xto_a} f(x) + g(x) = lim{xto_a} f(x) + lim{xto_a} g(x) = f(a) + g(a)$, so $f(x) + g(x)$ is continuous.



    let $h(x) = f(x) + g(x)$ and therefore $h(x)$ would be continuous.



    if $|f(x)| le M, |g(x)| le N$ then $h(x) = |f(x) + g(x)| le M + N in R^+$



    let $P = M + N$, therefore $|h(x)| = |f(x) + g(x)| le P in R^+$



    since $h(x)$ is continuous and for some $P in R^+ |h(x)| le P, h(x) in W_1$ implies $f(x) + g(x) in W_1$



    c. for $k in R, kx_1 in W_1$



    similarly for $k in R$



    $k cdot lim{xto_a} f(x) = k cdot f(a)$, is continuous at a.



    thus, $k cdot f(x) le k cdot M in W_1$



    by subspace test, $W_1$ is a subspace of $V$



    $W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



    a. $W_2$ is non-empty



    $f(x) = 0$



    $f(-0) = f(0)$
    the condition holds, thus $W_2$ is non-empty.



    b. if $x_1, x_2 in W_2$ then $x_1 + x_2 in W_2$



    $f(x), g(x) in W_2$



    they are continuous and $f(-x) = f(x), g(-x) = g(x)$ for all x



    this result means that $f$ and $g$ are even functions



    $(f + g)(-x) = f(-x) + g(-x) = f(x) + g(x) = (f + g)(x)$ for all x



    hence, $f + g$ is also even. therefore $f + g in W_2$



    c. for $k in R, kx_1 in W_2$



    for $k in R$,



    $(kf)(-x) = kf(-x) = k(f(-x)) = k(f(x)) = kf(x)$ for all x



    hence $kf$ is even. therefore, $kf in W_2$






    share|cite|improve this answer




























      0














      $W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



      a. $W_1$ is non- empty.



      $f(x) = 0$



      $|0| le M$



      $0 le M$



      since $M in R^+$ then $W_1$ is non-empty.



      b. if $x_1, x_2 in W_1$ then $x_1 + x_2 in W_1$



      $f(x), g(x) in W_1$



      $f(x), g(x)$ are continuous and $|f(x)| le M, |g(x)| le N$



      show that $h(x) in W_1$ is such that $h(x)$ is continuous and $|h(x)| le P$ for some $P in R^+$



      if $f(x)$ and $g(x)$ are continuous at a, then $f(x) + g(x)$ are continuous at a.



      $lim{xto_a} f(x) = f(a)$ and $lim{xto_a} g(x) = g(a)$



      $lim{xto_a} f(x) + g(x) = lim{xto_a} f(x) + lim{xto_a} g(x) = f(a) + g(a)$, so $f(x) + g(x)$ is continuous.



      let $h(x) = f(x) + g(x)$ and therefore $h(x)$ would be continuous.



      if $|f(x)| le M, |g(x)| le N$ then $h(x) = |f(x) + g(x)| le M + N in R^+$



      let $P = M + N$, therefore $|h(x)| = |f(x) + g(x)| le P in R^+$



      since $h(x)$ is continuous and for some $P in R^+ |h(x)| le P, h(x) in W_1$ implies $f(x) + g(x) in W_1$



      c. for $k in R, kx_1 in W_1$



      similarly for $k in R$



      $k cdot lim{xto_a} f(x) = k cdot f(a)$, is continuous at a.



      thus, $k cdot f(x) le k cdot M in W_1$



      by subspace test, $W_1$ is a subspace of $V$



      $W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



      a. $W_2$ is non-empty



      $f(x) = 0$



      $f(-0) = f(0)$
      the condition holds, thus $W_2$ is non-empty.



      b. if $x_1, x_2 in W_2$ then $x_1 + x_2 in W_2$



      $f(x), g(x) in W_2$



      they are continuous and $f(-x) = f(x), g(-x) = g(x)$ for all x



      this result means that $f$ and $g$ are even functions



      $(f + g)(-x) = f(-x) + g(-x) = f(x) + g(x) = (f + g)(x)$ for all x



      hence, $f + g$ is also even. therefore $f + g in W_2$



      c. for $k in R, kx_1 in W_2$



      for $k in R$,



      $(kf)(-x) = kf(-x) = k(f(-x)) = k(f(x)) = kf(x)$ for all x



      hence $kf$ is even. therefore, $kf in W_2$






      share|cite|improve this answer


























        0












        0








        0






        $W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



        a. $W_1$ is non- empty.



        $f(x) = 0$



        $|0| le M$



        $0 le M$



        since $M in R^+$ then $W_1$ is non-empty.



        b. if $x_1, x_2 in W_1$ then $x_1 + x_2 in W_1$



        $f(x), g(x) in W_1$



        $f(x), g(x)$ are continuous and $|f(x)| le M, |g(x)| le N$



        show that $h(x) in W_1$ is such that $h(x)$ is continuous and $|h(x)| le P$ for some $P in R^+$



        if $f(x)$ and $g(x)$ are continuous at a, then $f(x) + g(x)$ are continuous at a.



        $lim{xto_a} f(x) = f(a)$ and $lim{xto_a} g(x) = g(a)$



        $lim{xto_a} f(x) + g(x) = lim{xto_a} f(x) + lim{xto_a} g(x) = f(a) + g(a)$, so $f(x) + g(x)$ is continuous.



        let $h(x) = f(x) + g(x)$ and therefore $h(x)$ would be continuous.



        if $|f(x)| le M, |g(x)| le N$ then $h(x) = |f(x) + g(x)| le M + N in R^+$



        let $P = M + N$, therefore $|h(x)| = |f(x) + g(x)| le P in R^+$



        since $h(x)$ is continuous and for some $P in R^+ |h(x)| le P, h(x) in W_1$ implies $f(x) + g(x) in W_1$



        c. for $k in R, kx_1 in W_1$



        similarly for $k in R$



        $k cdot lim{xto_a} f(x) = k cdot f(a)$, is continuous at a.



        thus, $k cdot f(x) le k cdot M in W_1$



        by subspace test, $W_1$ is a subspace of $V$



        $W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



        a. $W_2$ is non-empty



        $f(x) = 0$



        $f(-0) = f(0)$
        the condition holds, thus $W_2$ is non-empty.



        b. if $x_1, x_2 in W_2$ then $x_1 + x_2 in W_2$



        $f(x), g(x) in W_2$



        they are continuous and $f(-x) = f(x), g(-x) = g(x)$ for all x



        this result means that $f$ and $g$ are even functions



        $(f + g)(-x) = f(-x) + g(-x) = f(x) + g(x) = (f + g)(x)$ for all x



        hence, $f + g$ is also even. therefore $f + g in W_2$



        c. for $k in R, kx_1 in W_2$



        for $k in R$,



        $(kf)(-x) = kf(-x) = k(f(-x)) = k(f(x)) = kf(x)$ for all x



        hence $kf$ is even. therefore, $kf in W_2$






        share|cite|improve this answer














        $W_1 ={f in C^0 [a, b] : |f(x)| le M,, text{for some},, M in R^+}$, the set of bounded continuous functions on $[a, b]$



        a. $W_1$ is non- empty.



        $f(x) = 0$



        $|0| le M$



        $0 le M$



        since $M in R^+$ then $W_1$ is non-empty.



        b. if $x_1, x_2 in W_1$ then $x_1 + x_2 in W_1$



        $f(x), g(x) in W_1$



        $f(x), g(x)$ are continuous and $|f(x)| le M, |g(x)| le N$



        show that $h(x) in W_1$ is such that $h(x)$ is continuous and $|h(x)| le P$ for some $P in R^+$



        if $f(x)$ and $g(x)$ are continuous at a, then $f(x) + g(x)$ are continuous at a.



        $lim{xto_a} f(x) = f(a)$ and $lim{xto_a} g(x) = g(a)$



        $lim{xto_a} f(x) + g(x) = lim{xto_a} f(x) + lim{xto_a} g(x) = f(a) + g(a)$, so $f(x) + g(x)$ is continuous.



        let $h(x) = f(x) + g(x)$ and therefore $h(x)$ would be continuous.



        if $|f(x)| le M, |g(x)| le N$ then $h(x) = |f(x) + g(x)| le M + N in R^+$



        let $P = M + N$, therefore $|h(x)| = |f(x) + g(x)| le P in R^+$



        since $h(x)$ is continuous and for some $P in R^+ |h(x)| le P, h(x) in W_1$ implies $f(x) + g(x) in W_1$



        c. for $k in R, kx_1 in W_1$



        similarly for $k in R$



        $k cdot lim{xto_a} f(x) = k cdot f(a)$, is continuous at a.



        thus, $k cdot f(x) le k cdot M in W_1$



        by subspace test, $W_1$ is a subspace of $V$



        $W_2 = {f in C^0 [a, b] : f(-x) = f(x),, text{for all},, x}$, the set of even continuous functions on $[a, b]$



        a. $W_2$ is non-empty



        $f(x) = 0$



        $f(-0) = f(0)$
        the condition holds, thus $W_2$ is non-empty.



        b. if $x_1, x_2 in W_2$ then $x_1 + x_2 in W_2$



        $f(x), g(x) in W_2$



        they are continuous and $f(-x) = f(x), g(-x) = g(x)$ for all x



        this result means that $f$ and $g$ are even functions



        $(f + g)(-x) = f(-x) + g(-x) = f(x) + g(x) = (f + g)(x)$ for all x



        hence, $f + g$ is also even. therefore $f + g in W_2$



        c. for $k in R, kx_1 in W_2$



        for $k in R$,



        $(kf)(-x) = kf(-x) = k(f(-x)) = k(f(x)) = kf(x)$ for all x



        hence $kf$ is even. therefore, $kf in W_2$







        share|cite|improve this answer














        share|cite|improve this answer



        share|cite|improve this answer








        edited Oct 8 '13 at 6:41

























        answered Oct 8 '13 at 6:35









        Zhoe

        2,1261812




        2,1261812






























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