<?xml version="1.0" encoding="UTF-8"?><!DOCTYPE article  PUBLIC "-//NLM//DTD Journal Publishing DTD v3.0 20080202//EN" "http://dtd.nlm.nih.gov/publishing/3.0/journalpublishing3.dtd"><article xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink" dtd-version="3.0" xml:lang="en" article-type="research article"><front><journal-meta><journal-id journal-id-type="publisher-id">AM</journal-id><journal-title-group><journal-title>Applied Mathematics</journal-title></journal-title-group><issn pub-type="epub">2152-7385</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/am.2013.47A002</article-id><article-id pub-id-type="publisher-id">AM-33967</article-id><article-categories><subj-group subj-group-type="heading"><subject>Articles</subject></subj-group><subj-group subj-group-type="Discipline-v2"><subject>Physics&amp;Mathematics</subject></subj-group></article-categories><title-group><article-title>
 
 
  Study for System of Nonlinear Differential Equations with Riemann-Liouville Fractional Derivative
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>anping</surname><given-names>Zheng</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Wenxia</surname><given-names>Wang</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib></contrib-group><aff id="aff1"><addr-line>Department of Mathrmatics, Taiyuan Normal University, Taiyuan, China</addr-line></aff><author-notes><corresp id="cor1">* E-mail:<email>zhengyanping2003@126.com(AZ)</email>;</corresp></author-notes><pub-date pub-type="epub"><day>04</day><month>07</month><year>2013</year></pub-date><volume>04</volume><issue>07</issue><fpage>5</fpage><lpage>8</lpage><history><date date-type="received"><day>April</day>	<month>19,</month>	<year>2013</year></date><date date-type="rev-recd"><day>May</day>	<month>19,</month>	<year>2013</year>	</date><date date-type="accepted"><day>May</day>	<month>29,</month>	<year>2013</year></date></history><permissions><copyright-statement>&#169; Copyright  2014 by authors and Scientific Research Publishing Inc. </copyright-statement><copyright-year>2014</copyright-year><license><license-p>This work is licensed under the Creative Commons Attribution International License (CC BY). http://creativecommons.org/licenses/by/4.0/</license-p></license></permissions><abstract><p><html>
 <head></head>
 
   In this work, we study existence theorem of the initial value problem for the system of fractional differential equations <img alt="" src="Edit_6b0d0c37-cdc0-4ded-bdaf-e5367a040916.bmp" />where Dα denotes standard Riemann-Liouville fractional derivative, 0 &lt; α &lt; 1, <img alt="" src="Edit_6f4f81e2-9e10-44ae-a744-a7c17f2c5265.bmp" /> <img alt="" src="Edit_956b81d3-c88c-4d0e-922c-7e363f2452ca.bmp" />and A  is a square matrix. At the same time, power-type estimate for them has been given. 
 
</html></p></abstract><kwd-group><kwd>Riemann-Liouville Fractional Derivative; Weighted Cauchy-Type Problem; Fractional Differential Equations</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>Let <img src="2-7401502\c32e98f5-2afd-46a1-a805-a78e63fa2a29.jpg" /> denote the <img src="2-7401502\fe3cfcb6-1f5e-45d2-99ee-d3f8935f64ce.jpg" /> matrix over real fields <img src="2-7401502\5062a50d-703a-4808-8915-7fa5f76ebc1d.jpg" /> or complex fields<img src="2-7401502\d8b97e75-488d-496b-82cd-3732d5c51b50.jpg" />. For <img src="2-7401502\4dcb1ee3-1b0b-4d42-bea6-1b5c10172d0f.jpg" /></p><p><img src="2-7401502\4ce1d14c-0242-464d-ae3f-6052dc2c48c5.jpg" /></p><p>here <img src="2-7401502\ffad5b0a-e9a7-41e2-b488-427eecc0cda7.jpg" /> is the usual space of continuous functions on <img src="2-7401502\9d03287b-c25a-41ee-9b87-b86bd0479b64.jpg" /> which is a Banach space with the norm</p><p><img src="2-7401502\ce1517a1-8add-499d-a358-cb609374b268.jpg" /></p><p>The space <img src="2-7401502\53cfb0dd-b248-4abc-a0f6-1e6999be4e91.jpg" /> is defined by</p><p><img src="2-7401502\028b276f-08e0-4255-bdbf-6bc40c86ede7.jpg" /></p><p>(see [<xref ref-type="bibr" rid="scirp.33967-ref1">1</xref>]).</p><p>The existence of solution of initial value problems for fractional order differential equations have been studied in many literatures such as [1-4]. In this paper, we present the analysis of the system of fractional differential equations</p><disp-formula id="scirp.33967-formula62240"><label>(*)</label><graphic position="anchor" xlink:href="2-7401502\9d7dd8e8-4b2f-41e0-b8c5-90fa250228d5.jpg"  xlink:type="simple"/></disp-formula><p>&#160;</p><p>where <img src="2-7401502\a20794c7-41dd-4a61-b428-861635727fe6.jpg" /> denotes standard Riemann-Liouville fractional derivative, where</p><p><img src="2-7401502\841bd2e7-2973-4537-b60c-70c8fa9787f6.jpg" /></p><p><img src="2-7401502\dad1b83b-7007-47b5-bb3b-0f52d42dfcc9.jpg" /></p><p><img src="2-7401502\df993e7d-3ceb-4c77-8b8d-ab2c7271ec00.jpg" />and <img src="2-7401502\27f46a90-accb-4c33-b4b0-27aa20b8a86c.jpg" /> is a square.</p><p>To prove the main result, we begin with some definitions and lemmas. For details, see [1-5].</p><p>Definition 1.1 Let <img src="2-7401502\d8396062-2dc8-473c-9aee-0fc6813f9153.jpg" /> be a continuous function defined on <img src="2-7401502\a041be8a-a08c-4b1c-8236-17cf1567497f.jpg" /> and<img src="2-7401502\40fdd6db-d6ea-46e2-9965-c2583926609e.jpg" />. Then the expression</p><p><img src="2-7401502\6aacc275-a49d-41e1-a46a-8daeaf85cf0d.jpg" /></p><p>is called left-sided fractional derivatives of order <img src="2-7401502\e67a7a61-82f8-438e-ae94-ec22d4369f76.jpg" /></p><p>Definition 1.2 Let <img src="2-7401502\5f45b6e5-3b33-4833-984e-a8f3d899f8df.jpg" /> be a continuous function defined on <img src="2-7401502\958e79d4-113c-4234-9feb-c9a60f84cd4b.jpg" /> and <img src="2-7401502\db80db89-8999-4dd1-a13f-b7c12dbc797b.jpg" /> Then the expression</p><p><img src="2-7401502\410a9569-c0be-4297-a02f-0fb9b3dfc714.jpg" /></p><p>is called left-sided fractional integral of order <img src="2-7401502\955d543a-7ad5-4ccb-939d-b4353f6d6dd2.jpg" /></p><p>Lemma 1.3 Given <img src="2-7401502\34e50071-5acc-4e60-8ee0-1a2e1c8dd64a.jpg" /> with eigenvalues</p><p><img src="2-7401502\bd7f4ec4-e73b-43c7-ada1-04c0db936519.jpg" />in any prescribed order, there is a unitary matrix <img src="2-7401502\1dfe5745-ba11-417d-8fb6-7fe0c699dd20.jpg" /> such that <img src="2-7401502\48ea9beb-e1b7-4b17-a951-bc8a36b53204.jpg" /> is upper triangular with diagonal entries <img src="2-7401502\4db278a8-27a3-4270-b0ff-e98f1bfe2e21.jpg" /> <img src="2-7401502\1de445de-d849-4637-916b-d586aa3235a4.jpg" /> That is, every square matrix <img src="2-7401502\f79a504d-30e3-41f4-9418-894a69869d5f.jpg" /> is unitarily equivalent to triangular matrix whose entries are the eigenvalues of <img src="2-7401502\642cba37-15b3-4ade-baef-8f8f2a18dab0.jpg" /> in a prescribed order. Further more, if <img src="2-7401502\5dc3fda1-1b75-4ce2-ab47-2ac7b4edc276.jpg" /> and if all the eigenvalues of <img src="2-7401502\1aefc4fc-2445-4965-b9ff-6099e1884851.jpg" /> are real, then <img src="2-7401502\80ba9e94-0d34-408a-a19e-bf993a8c708a.jpg" /> may be chosen to be real and orthogonal.</p><p>Lemma 1.4 Assume that <img src="2-7401502\195dc447-a54e-4927-8645-5e032d6b8097.jpg" /> with fractional derivative of order <img src="2-7401502\901e46e3-f6fc-43fd-b865-79e8929b231a.jpg" /> that belongs to<img src="2-7401502\552d5439-ec90-48d8-b3e7-003be0c591d5.jpg" />. Then</p><p><img src="2-7401502\9d577ba8-8417-4906-ae6a-0e0e98265b7c.jpg" /></p><p>for some <img src="2-7401502\69ce8266-72c0-4a83-ace6-f616626f543c.jpg" /> When the function <img src="2-7401502\64ebfedb-9a77-44c2-8c21-e08b814d856f.jpg" /> then</p><p><img src="2-7401502\a788819c-2935-4c85-8b9a-59aa30b04560.jpg" />where</p><p><img src="2-7401502\3a6869e0-f41d-4e4c-9a6e-215c76b62412.jpg" />and <img src="2-7401502\1f6913de-d1d7-4a15-90fc-2cbc25ffe621.jpg" /></p><p>Lemma 1.5 (Schauder’s fixed theorem) Assume <img src="2-7401502\9370682f-1a99-4669-bb0f-2ae203406290.jpg" /> is a relative subset of a convex set <img src="2-7401502\70736e80-0f5e-4bc4-bef9-d90bfb5b85b6.jpg" /> in a normed space <img src="2-7401502\b4af3d19-ab96-40bf-b7ec-c80d35a5d365.jpg" /> Let <img src="2-7401502\3a1f0d64-6efa-45a4-a5ef-ee5741372ce3.jpg" /> be a compact map with<img src="2-7401502\de0c09be-6621-4539-9a29-9691ef5d82c5.jpg" />. Then either</p><p>(A<sub>1</sub>) <img src="2-7401502\ed173787-1641-4a75-965b-ca0c70340578.jpg" />has a fixed point in<img src="2-7401502\4bf739fb-8203-44c8-8ee3-715c1a137f38.jpg" />, or</p><p>(A<sub>2</sub>) there is a <img src="2-7401502\5f71aedc-d5bd-4bd2-964d-d835eb1d70ba.jpg" /> and a <img src="2-7401502\c04b13a4-0fc5-43c2-ac82-4dd1a363b68b.jpg" /> such that <img src="2-7401502\852cf831-5a4e-4c5e-bb65-21d16b95bbd2.jpg" /></p><p>Now, let’s us give some hypotheses:</p><p>H1: <img src="2-7401502\eacfe4f3-52da-4527-9478-3f683406886b.jpg" />is continuous on <img src="2-7401502\7dbff750-5287-4404-b4f6-681636d54512.jpg" /> and is such that</p><disp-formula id="scirp.33967-formula62241"><label>(1)</label><graphic position="anchor" xlink:href="2-7401502\269c091a-dd5f-43ef-aa9d-d2452fb47bb8.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="2-7401502\eaf27c2f-3841-495b-a0ac-9e549e6a7eb3.jpg" /> is a continuous function on <img src="2-7401502\7cc988e6-f751-4eaa-8a1d-66dbc123b822.jpg" /></p><p>H2: <img src="2-7401502\1399f1ec-4e69-40ea-b74f-e1cdb764f970.jpg" />is continuous on <img src="2-7401502\2e97ac5b-d04f-4ad1-9280-1d6049120773.jpg" /> and is such that</p><disp-formula id="scirp.33967-formula62242"><label>(2)</label><graphic position="anchor" xlink:href="2-7401502\7b7a7977-3d28-42ef-ad5a-64dd3c7fea16.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="2-7401502\a3fa0fe8-40e9-46c4-adf0-79976d608e53.jpg" /> is a continuous function on <img src="2-7401502\a3092f6d-a196-4edc-970d-f1d7de669e96.jpg" /></p><p>Lemma 1.6 Let <img src="2-7401502\3645631f-be1a-40a3-a2f4-c30701b22c5e.jpg" /> If we assume that <img src="2-7401502\7d3860a4-9508-40e9-86bc-e6db0a78c9fd.jpg" /> then the initial value problem</p><disp-formula id="scirp.33967-formula62243"><label>(3)</label><graphic position="anchor" xlink:href="2-7401502\eaf10d55-fcd2-4d38-8580-ae6bc9d6da08.jpg"  xlink:type="simple"/></disp-formula><p>where</p><p><img src="2-7401502\3af104c9-2e7e-4109-82bf-ddd4c469da45.jpg" /></p><p><img src="2-7401502\e6541c59-479c-4c80-9a7e-7446234aa0b2.jpg" /></p><p>has at least a solution <img src="2-7401502\cf29698c-bab8-4778-8764-2090f4f11cca.jpg" /> for <img src="2-7401502\eb0955f7-a05d-4d73-9325-db940392483f.jpg" /> sufficiently small.</p><p>Proof. If</p><p><img src="2-7401502\6c91f81d-1f2d-452f-930b-895241412c06.jpg" />then<img src="2-7401502\1d2146d8-90f3-4db8-9d43-7d779f80124b.jpg" />, by Lemma 1.4, We are therefore reduced the initial problem to the nonlinear integral equation</p><disp-formula id="scirp.33967-formula62244"><label>(4)</label><graphic position="anchor" xlink:href="2-7401502\c49c69d1-e172-4b7f-9184-1ab0889b26a1.jpg"  xlink:type="simple"/></disp-formula><p>The existence of a solution to Problem (3) can be formulated as a fixed point equation <img src="2-7401502\bbb4947c-58d1-4d8c-b06f-ef78a31429d7.jpg" /> where</p><disp-formula id="scirp.33967-formula62245"><label>(5)</label><graphic position="anchor" xlink:href="2-7401502\a52bfc24-e265-4f74-acdf-a25ff2e85f4b.jpg"  xlink:type="simple"/></disp-formula><p>in the space<img src="2-7401502\d166581f-32c0-432f-bcac-14c9b7103c91.jpg" />.</p><p>Define</p><p><img src="2-7401502\a270f0b3-5ba9-4596-8f90-0ef2b574dd80.jpg" /></p><p>Clearly, it is closed, convex and nonempty.</p><p>Step I. We shall prove that we note that <img src="2-7401502\7b69316a-43ab-4bee-ab1c-c254798718d3.jpg" /></p><p>We note that</p><p><img src="2-7401502\4a3c4e67-da22-40ea-ad26-afbc5e4cd3f6.jpg" /></p><p>Since <img src="2-7401502\7cbb5a22-0f64-470f-953f-2bede75e1316.jpg" /> it will be sufficient to impose</p><p><img src="2-7401502\381a97b8-1ada-458f-a13d-e0af87c28737.jpg" /></p><p>In view of the assumption <img src="2-7401502\bae3437b-51eb-4959-b8fe-0663be944a21.jpg" /> the second estimate is satisfied if say <img src="2-7401502\f314aace-e3f5-49d3-ad19-3e458806fe5c.jpg" /> and <img src="2-7401502\6246b64f-f944-4082-a851-ffc99c80a676.jpg" /> is chosen sufficiently small.</p><p>Step II. We shall prove that the operator <img src="2-7401502\7e085d71-b3be-4e76-99d6-6fa46b936a8c.jpg" /> is compact. To prove the compactness of</p><p><img src="2-7401502\9d921bbf-e995-4947-b3fa-abb555c43175.jpg" /></p><p>defined by (5), it will be sufficient to argue on the operator</p><p><img src="2-7401502\8644c8f6-ff97-4e22-8f35-45f6bb5949af.jpg" /></p><p>defined in this way:</p><p><img src="2-7401502\6298d221-e9cc-40e1-b85e-33f69b7d8680.jpg" /></p><p>We have <img src="2-7401502\c65328bb-f342-4a97-b8e8-9f2bcf495a4b.jpg" /> where the operator</p><p><img src="2-7401502\cfb6e5e8-dbc2-493a-84b2-bc70ebed4a46.jpg" /></p><p>Turn out to be compact from classical sufficient conditions, since<img src="2-7401502\5734576b-5882-4e1c-b36a-5919ed757751.jpg" />. By Lemma 1.5, we have that Problem (3) has least a solution.</p><p>The proof is complete.</p><p>Lemma 1.7 Suppose that <img src="2-7401502\457fa6f5-6984-422a-a25a-820296036409.jpg" /> satisfies H1,<sup></sup></p><p><img src="2-7401502\a4e18a4d-bc21-49bb-8a11-14d3518bda51.jpg" />and <img src="2-7401502\ca30f5e9-7836-49a2-aa6d-bd72f9d79a95.jpg" /> If <img src="2-7401502\5b1a92fb-12a1-410b-8d41-493de76a5783.jpg" /> for some <img src="2-7401502\c08ecb82-39e9-42f6-b295-b3b5c9aeeb19.jpg" /> then the problem</p><disp-formula id="scirp.33967-formula62246"><label>(6)</label><graphic position="anchor" xlink:href="2-7401502\6f980a18-502d-429d-a27d-575640e7dbe4.jpg"  xlink:type="simple"/></disp-formula><p>exists a positive constant <img src="2-7401502\dfdf25f1-9bb2-40af-b21c-db0da9712f64.jpg" /> such that <img src="2-7401502\e8978394-44c4-43ca-b546-d70e216d5e2e.jpg" /> <img src="2-7401502\ae73487e-1d9a-46af-9ebd-c25786e71726.jpg" /></p><p>Lemma 1.8<sup> </sup>Let <img src="2-7401502\24d03a04-5889-4735-8102-67e6f5a267c2.jpg" /> with <img src="2-7401502\9691b37a-0ce3-4016-a3f8-e3d4a538bba2.jpg" />Suppose further that<img src="2-7401502\e00956a5-48b6-4bc6-884c-979a83ed805e.jpg" />. Then Problem (6) and its associated integral equation</p><disp-formula id="scirp.33967-formula62247"><label>(7)</label><graphic position="anchor" xlink:href="2-7401502\cef70250-da3d-499b-8f7d-4ddd84c0a5e9.jpg"  xlink:type="simple"/></disp-formula><p>are equivalent.</p><p>Lemma 1.9 Assume that <img src="2-7401502\9efbf36c-0b62-4f29-aff9-96d162400aa2.jpg" /> <img src="2-7401502\6a28a7c9-611f-4bb5-82af-a2d20d26b208.jpg" /> satisfies H2, and <img src="2-7401502\25f90c34-1f7a-4af9-8f32-6d7414555ae1.jpg" /> for some <img src="2-7401502\9ca7f659-d8d6-453b-b12d-068f95d59e2c.jpg" /> Suppose further that <img src="2-7401502\7e03b04a-485f-44e6-983a-485e6fc186eb.jpg" /> then there exists <img src="2-7401502\2649a712-6f19-4644-8813-40fd8043e455.jpg" /> and <img src="2-7401502\334e7db1-586f-4e64-8c09-91bd890097a2.jpg" /> such that any solution of (6) exists globally and satisfies</p><disp-formula id="scirp.33967-formula62248"><label>(8)</label><graphic position="anchor" xlink:href="2-7401502\14694d31-bd96-415c-8e0f-b9a3b2618cda.jpg"  xlink:type="simple"/></disp-formula></sec><sec id="s2"><title>2. Main Results</title><p>Theorem 2.1 Let <img src="2-7401502\94101806-6cf1-458a-8550-a99cfe77b9ef.jpg" /> then initial problem (*) has a solution <img src="2-7401502\92c09437-729b-4b4b-b67f-2503a1c38386.jpg" />where</p><p><img src="2-7401502\e5bc0b8a-6ee6-4096-8b58-8ff1deec10d5.jpg" /></p><p><img src="2-7401502\f9be32b7-a885-4a62-b842-9cade70e26ac.jpg" /></p><p>for all <img src="2-7401502\ae758a0f-963b-4682-a3f2-100064494b12.jpg" /> and sufficiently small <img src="2-7401502\0528dc9a-5bbe-4dc0-80eb-26f5f229d135.jpg" /></p><p>Proof. Given <img src="2-7401502\b0570aaa-fbe8-45d8-bbd2-217cae6deb89.jpg" /> with eigenvalues <img src="2-7401502\8b512d66-d4b1-4ead-9073-03d4694c5c0f.jpg" /> by Lemma 1.3, there is a unitary matrix <img src="2-7401502\3055d211-40ae-4fe8-8b1a-bb6b1bcccf98.jpg" /> such that</p><p><img src="2-7401502\3d9eef47-5e16-4d0b-ae1a-dc03d4abd221.jpg" /></p><p>is upper triangular with diagonal entries <img src="2-7401502\87de5d61-e2bf-490e-8f91-6a36d4c74254.jpg" /></p><p>Let <img src="2-7401502\af8df816-41f9-45cd-bfc0-85c4297b4504.jpg" /> we have</p><p><img src="2-7401502\bf822c0d-b295-48db-87c6-c3a728657787.jpg" /></p><p>At the same time, the initial problem (*) changed into</p><disp-formula id="scirp.33967-formula62249"><label>(**)</label><graphic position="anchor" xlink:href="2-7401502\4a61bdbb-857b-4faa-8719-36dfd077465c.jpg"  xlink:type="simple"/></disp-formula><p>Now, let’s consider the problem (**).</p><p>Clearly, the problem (**) is equivalent to the following n problems</p><p><img src="2-7401502\95b7ac98-beed-42b0-bd18-18d56c9c9f69.jpg" /></p><p>for <img src="2-7401502\83c097a5-17b8-4e62-903c-d62f773429b9.jpg" /> where <img src="2-7401502\39085416-365d-4ced-9d9c-b7ce3abdf3c6.jpg" /> is the <img src="2-7401502\9a97305c-d82f-4fe4-bea6-9956cc763d16.jpg" />th entries of the vector <img src="2-7401502\8c6ab663-0373-44d1-b1b9-1eee58f1f3f6.jpg" /></p><p>Consider the weighed Cauchy-type problem</p><p><img src="2-7401502\27863b3d-5b55-4aca-99bc-5d2ab27ed32e.jpg" /></p><p>In Lemma 1.6, take <img src="2-7401502\3ba61faa-3497-41cc-ba20-aebadb7cb98d.jpg" /> Then by lemma 1.6, <img src="2-7401502\409e8ca4-21a8-449e-b3e7-4236a47661e7.jpg" />s.t. the above problem has at least a solution</p><p><img src="2-7401502\64687b34-3569-4267-86c3-48650eedccf3.jpg" /></p><p>Consider the following weighed Cauchy-type problem</p><p><img src="2-7401502\f00cbb80-c73d-4625-928c-c06f56dccf5f.jpg" /></p><p>In Lemma 1.6, take <img src="2-7401502\38c9b8ee-7829-4cec-bdab-3bf3a1330aa1.jpg" /> Then by Lemma 1.6, <img src="2-7401502\fa37f951-413a-4c75-ae55-41252a07fab8.jpg" />s.t. the above problem has at least a solution <img src="2-7401502\f52aedb8-eb2d-4746-983a-7a856738e961.jpg" /></p><p>Similarly, there has at least a solution in</p><p><img src="2-7401502\ecb1d5eb-a9b2-47cc-9d35-b65416109734.jpg" /></p><p>for the rest n-2 initial problem in (**), denote by <img src="2-7401502\9d978b15-d6f5-4710-a1a2-40660475aac7.jpg" /> respectively. And therefore, there has at least a solution</p><p><img src="2-7401502\44d5132e-82c0-4d5c-b9cc-6e03a50dbc90.jpg" /></p><p>of the problem (**). Let <img src="2-7401502\1194a351-63bb-49d6-976a-07effbc3319c.jpg" /> it is required for us.</p><p>The proof is completed.</p><p>Since the problem (**) is equivalent to the following n problems</p><disp-formula id="scirp.33967-formula62250"><label>(9)</label><graphic position="anchor" xlink:href="2-7401502\0c28a00f-7311-463c-a4f3-bc9783ca86fe.jpg"  xlink:type="simple"/></disp-formula><p>for <img src="2-7401502\394b2590-5bd9-4c7d-bf5d-7cde3547379a.jpg" /> where <img src="2-7401502\0e9195bb-efa0-4253-82e5-409aa233f022.jpg" /> is the <img src="2-7401502\6651c47a-b00a-4101-bb6b-4f289dfc5e7d.jpg" />th entries of the vector <img src="2-7401502\119eb73b-faf9-4459-8b21-bdd0ebc57dac.jpg" /> Next, we shall discuss these equations in (9).</p><p>Theorem 2.2 Assume that the right hand of these equations in (9) satisfied H1, <img src="2-7401502\828584fd-a49d-4c44-94e9-ff960b63352f.jpg" /><img src="2-7401502\85183e5a-cee2-4d28-9da3-06964b616a5b.jpg" />and <img src="2-7401502\034648d4-6e02-4269-8002-bbf8e8377c18.jpg" /> for some <img src="2-7401502\e46a8b13-f9aa-4e8c-b153-bc18c401b5ec.jpg" /> If the solution of the problems (**) denoted by</p><p><img src="2-7401502\1b17bc1e-b1c2-449d-a935-2e20c4f6907e.jpg" />then there exists some constant <img src="2-7401502\63f8bea5-51e8-4cb5-b302-e3df6124bd03.jpg" /> such that</p><p><img src="2-7401502\5261c12d-553b-42a7-ae63-ab035f31f794.jpg" />for all <img src="2-7401502\6e07279e-3aad-41e3-a2f0-48ba2b629b6a.jpg" /></p><p>Proof. Similar to the proof of Theorem 2.1, now consider the following weighted Cauchy-type problem</p><p><img src="2-7401502\d643f217-e6d6-4a4e-9d32-a51066989fcc.jpg" /></p><p>Then by Lemma 1.7, there exists some constant <img src="2-7401502\27a3f5b9-2143-40ed-ab4a-4cde42feeb2c.jpg" /> such that <img src="2-7401502\34aea5d4-bafa-462c-a494-36b8d63cf319.jpg" /></p><p>Consider the following problem</p><p><img src="2-7401502\a369ec4b-7dcc-4fd5-9300-cfce0309ef33.jpg" /></p><p>Then by Lemma 1.7, there exists some constant <img src="2-7401502\793a2033-aa1d-4b83-b263-bcc82a4b3e09.jpg" /> such that <img src="2-7401502\cb468065-0fcd-4a8a-ba83-d0d9b88bb3d6.jpg" /></p><p>Similarly, there exist some positive constants <img src="2-7401502\6ab1a9c0-8460-43f7-abde-b77482ea0aad.jpg" /> such that</p><p><img src="2-7401502\4f6f82b0-6b9b-49cd-8c1e-0ee10c401563.jpg" /></p><p>for all <img src="2-7401502\2d0b0b25-486a-4f6a-afa1-3a0ac14601d4.jpg" /></p><p>Let <img src="2-7401502\983f825c-b768-4883-a52d-cfaeae0ddbe7.jpg" /> Then we have</p><p><img src="2-7401502\41dcdd25-0509-4041-b7df-f19e54ec4bf6.jpg" />for all <img src="2-7401502\bacad82d-0692-4c2c-9396-7ce5f1ab0326.jpg" /></p><p>The proof is completed.</p><p>Theorem 2.3 Assume that <img src="2-7401502\eef17e12-b419-408a-a256-0206af9d46bb.jpg" /> the right-hand of these equations in (9) satisfied H2, and <img src="2-7401502\3dd98e0a-0aad-41f2-9a97-4aff95f5aa6e.jpg" /></p><p>For some <img src="2-7401502\60666bc2-f649-444e-b579-b171162bd69e.jpg" /> Suppose further that</p><p><img src="2-7401502\2b84c4a2-7ffd-4340-a779-5f089fff2b75.jpg" /></p><p>If denote solution of the problems (**)<img src="2-7401502\267d8da2-5e58-420a-9846-5b6e1f8bb3c4.jpg" />by</p><p><img src="2-7401502\71223745-691e-44d3-8a3b-e5e4e46a3ea5.jpg" /></p><p>Then there exists some constant <img src="2-7401502\3894637e-718d-460d-92b2-07ad815792ac.jpg" /> and<img src="2-7401502\049e32bd-1ff4-4ec7-8b46-f722f1a2da25.jpg" />, such that</p><p><img src="2-7401502\03d93066-40c8-4cda-9d16-aee95e1c1069.jpg" /></p><p>for all <img src="2-7401502\eb36bf69-4e2d-4163-9dff-6cbd7cc34fb8.jpg" /></p><p>Using Lemmas 1.3 and 1.9, the proof is similar to Theorem 2.2. Therefore, it is omitted.</p></sec><sec id="s3"><title>3. Acknowledgements</title><p>This research was supported by the NNSF of China (10961020), the Science Foundation of Qinghai Province of China (2012-Z-910) and the University Natural Science Research Develop Foundation of Shanxi Province of China (20111021).</p></sec><sec id="s4"><title>REFERENCES</title></sec><sec id="s5"><title>NOTES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.33967-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">K. M. Furati and N.-E. Tatar, “Power-Type Estmates for a Nonlear Fractional Differential Equation,” Journal of Nonlinear Analysis, Vol. 62, No. 6, 2005, pp. 1025-1036. 
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