<oai_dc:dc xmlns:oai_dc="http://www.openarchives.org/OAI/2.0/oai_dc/" xmlns:dc="http://purl.org/dc/elements/1.1/" xmlns:xsi="http://www.w3.org/2001/XMLSchema-instance" xsi:schemaLocation="http://www.openarchives.org/OAI/2.0/oai_dc/ http://www.openarchives.org/OAI/2.0/oai_dc.xsd">
<dc:title>Uniform convergence for approximate traveling waves in linear reaction-hyperbolic systems</dc:title>
<dc:creator>Avner Friedman</dc:creator><dc:creator>B. Hu</dc:creator>
<dc:subject>35L45</dc:subject><dc:subject>92C20</dc:subject><dc:subject>92C40</dc:subject><dc:subject>traveling waves</dc:subject><dc:subject>reaction-hyperbolic systems</dc:subject><dc:subject>neurofilament</dc:subject>
<dc:description>In this paper we study a linear reaction-hyperbolic systems of the form $\epsilon (\partial_t  + v_i \partial_x) p_i = \sum_{j=1}^n k_{ij} p_j$ ($i = 1, 2, \dots, n$) for $x &gt; 0$, $t &gt; 0$ with &quot;near equilibrium&quot; initial and boundary data. This problem arises in a model of transport of neurofilaments in axons. The matrix $(k_{ij})$ is assumed to have a unique null vector $(\lambda_1, \dots, \lambda_n)$ with positive components summed to $1$ and the $v_j$ are arbitrary velocities such that $v \equiv sum_{j=1}^n \lambda_j v_j &gt; 0$. We prove that as $\epsilon \to 0$, the solution converges to a traveling wave with velocity $v$ and a spreading front, and that the convergence rate in the uniform norm is $O(\epsilon^{(1 - \alpha)/2})$, for any small positive $\alpha$.</dc:description>
<dc:publisher>Indiana University Mathematics Journal</dc:publisher>
<dc:date>2007</dc:date>
<dc:type>text</dc:type>
<dc:format>pdf</dc:format>
<dc:identifier>10.1512/iumj.2007.56.3044</dc:identifier>
<dc:source>10.1512/iumj.2007.56.3044</dc:source>
<dc:language>en</dc:language>
<dc:relation>Indiana Univ. Math. J. 56 (2007) 2133 - 2158</dc:relation>
<dc:coverage>state-of-the-art mathematics</dc:coverage>
<dc:rights>http://iumj.org/access/</dc:rights>
</oai_dc:dc>