<?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.2013.48148</article-id><article-id pub-id-type="publisher-id">AM-35091</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>
 
 
  Global Analysis of Beddington-DeAngelis Type Chemostat Model with Nutrient Recycling and Impulsive Input
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>ehbuba</surname><given-names>Rehim</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Lingling</surname><given-names>Sun</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref></contrib><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>Ahmadjan</surname><given-names>Muhammadhaji</given-names></name><xref ref-type="aff" rid="aff1"><sup>1</sup></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib></contrib-group><aff id="aff1"><addr-line>College of Mathematics and System Sciences, Xinjiang University, Urumqi, China</addr-line></aff><author-notes><corresp id="cor1">* E-mail:<email>ahmadjanm@gmail.com(AM)</email>;</corresp></author-notes><pub-date pub-type="epub"><day>23</day><month>07</month><year>2013</year></pub-date><volume>04</volume><issue>08</issue><fpage>1097</fpage><lpage>1105</lpage><history><date date-type="received"><day>June</day>	<month>6,</month>	<year>2013</year></date><date date-type="rev-recd"><day>July</day>	<month>6,</month>	<year>2013</year>	</date><date date-type="accepted"><day>July</day>	<month>13,</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>
 
 
   In this paper, a Beddington-DeAngelis type chemostat model with nutrient recycling and impulsive input is considered. Except using Floquet theorem, introducing a new method combining with comparison theorem of impulse differential equation and by using the Liapunov function method, the sufficient and necessary conditions on the permanence and extinction of the microorganism are obtained. Two examples are given in the last section to verify our mathematical results. The numerical analysis shows that if only the system is permanent, then it also is globally attractive. 
 
</p></abstract><kwd-group><kwd>Beddington-DeAngelis Model; Chemostat Model; Nutrient Recycling; Global Attractivity</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>The chemostat is an important and basic laboratory apparatus for culturing microorganisms. It can be used to investigate microbial growth and has the advantage that parameters are easily measurable. The chemostat plays an important role in bioprocessing, hence the model has been studied by more and more people. Chemostats with periodic inputs were studied [1,2], those with periodic washout rate [3,4], and those with periodic input and washout [<xref ref-type="bibr" rid="scirp.35091-ref5">5</xref>]. In recent years, those with nutrient recycling [6-10] have been investigated and some investing results were obtained. Now many scholars pointed out that it was necessary to consider models with periodic perturbations, since those phenomena might be exposed in many real words. However, there are some other perturbations such as floods, fires and drainaye of sewage which are not suitable to be considered continually. Those perturbations bring sudden changes to the system. Systems with sudden changes are involving in impulsive differential equations which have been studied intensively and systematically [11-13]. Impulsive differential equations are found in almost every domain of applied sciences.</p><p>Recently, many papers studied chemostat model with impulsive effect the Lotka-Volterra type or Monod type functional response. But there are few papers which study a chemostat model with Beddington-DeAngelis functional response, especially a Beddinton-DeAngelis type chemostat with nutrient recycling. The BeddingtonDeAngelis functional response is introduced by Beddington and DeAngelis [14,15]. It is similar to the wellknown Holling II functional response but has an extra term <img src="1-7401639---16\5953cf47-a8dc-4fb7-b557-77899c3d18fd.jpg" /> in the denominator that models mutual interference in species. The model, we consider in this paper, takes the form:</p><disp-formula id="scirp.35091-formula12833"><label>(1)</label><graphic position="anchor" xlink:href="1-7401639---16\74d9f9ed-1276-4169-b45d-f4be98ebf2f4.jpg"  xlink:type="simple"/></disp-formula><p>where S(t), <img src="1-7401639---16\ddb0bcd4-5622-4c7f-a6aa-138c5f90789c.jpg" />represent the concentration of limiting substrate and the microorganism respectively, D is the dilution rate, a is the uptake constant of the microorganism, k is the yield of the microorganism <img src="1-7401639---16\7a2cfa9a-bf88-413b-bf24-fe100b818b9d.jpg" /> per unit mass of substrate, r is the death rate of microorganism, b is the fraction of the nutrient recycled by bacterial decomposition of the dead microorganism, p is the amount of limiting substrate pulsed each T, T is the period of pulsing. Obviously, we have <img src="1-7401639---16\805c142b-907e-4061-a435-846a45c0f997.jpg" /> and<img src="1-7401639---16\7db76cb6-49d7-4093-8b4a-23674ea77c07.jpg" />. D, A, B, k, a, p are all positive constants.</p><p>The organization of this paper is as the following. In Section 2, we introduce some useful notations and lemmas. In Section 3, we will state and prove the main results on the global asymptotic stability and permanence. In Section 4, we give a brief discussion and the numerical analysis.</p></sec><sec id="s2"><title>2. Preliminaries</title><p>In this section, we will give some notations and lemmas which will be used for our main results. Firstly, for convenience, we set <img src="1-7401639---16\fa96054f-194b-4c5e-b474-21b370439775.jpg" /> , then system (1) becomes</p><disp-formula id="scirp.35091-formula12834"><label>(2)</label><graphic position="anchor" xlink:href="1-7401639---16\8b2c0d73-67df-4533-b2e9-1611b59ef10e.jpg"  xlink:type="simple"/></disp-formula><p>Let<img src="1-7401639---16\8b65fe9b-b235-4954-bcf1-11d6ddece9bd.jpg" />. <img src="1-7401639---16\205f1682-27d4-49e1-84dc-d3de7b15a50e.jpg" />, <img src="1-7401639---16\175be4db-e557-42cf-b8ad-ffd43c4d46fe.jpg" />, <img src="1-7401639---16\222f5993-1836-48b0-acb5-b953bc498204.jpg" /> is left continuous at t = nT and x(t) is continuous at t = nT.</p><p>Lemma 1. Suppose <img src="1-7401639---16\432b5c97-9de9-4d5b-bd2a-dfc9b5861595.jpg" /> is any solution of system (2) with initial solution<img src="1-7401639---16\075de4eb-e7d5-4c05-b264-898880c90215.jpg" />. Then <img src="1-7401639---16\da3517f8-49d4-48b2-bc30-5915d1516632.jpg" /> for all<img src="1-7401639---16\11be9fd7-17eb-4b47-ab6d-a5f5212816aa.jpg" />. Moreover, if <img src="1-7401639---16\74130f20-7c04-406d-9242-a21c92c7018c.jpg" /> then <img src="1-7401639---16\1b94a55e-acb7-4031-86b5-2df0174ba9e8.jpg" /> for all<img src="1-7401639---16\27e5bbf9-0192-4be9-bc1b-48048776a14f.jpg" />.</p><p>The proof of Lemma 1 is simple, we omit it here.</p><p>In what follows, we give some basic properties about the following system.</p><disp-formula id="scirp.35091-formula12835"><label>(3)</label><graphic position="anchor" xlink:href="1-7401639---16\7141931a-2f2a-4e8c-a159-c40ccc25145e.jpg"  xlink:type="simple"/></disp-formula><p>Clearly,</p><p><img src="1-7401639---16\fa06f27e-6846-4e68-b929-8c34a09d26c1.jpg" /></p><p><img src="1-7401639---16\c70160d6-8aeb-4b24-9542-f385d834aacc.jpg" /></p><p>is a positive periodic solution of system (3). Any solution of system (3) is</p><p><img src="1-7401639---16\ee42481a-068a-412a-a0a0-752ecce5c8ac.jpg" /></p><p>Hence, we have the following result.</p><p>Lemma 2. System (3) has a positive periodic solution <img src="1-7401639---16\6c368e6b-3f4b-4119-9b92-80822f0e3fc8.jpg" /> and<img src="1-7401639---16\734dc026-578d-490c-9998-75c2c8cf32fc.jpg" />, as <img src="1-7401639---16\52369356-38aa-4d6e-8791-be236b683c85.jpg" /> for any solution u(t) of system (3). Moreover, <img src="1-7401639---16\a5036178-d40a-41d5-ac97-8e20612db845.jpg" />if <img src="1-7401639---16\2a92c702-9412-4be5-863c-273e4e9f0345.jpg" /> and <img src="1-7401639---16\f4f4b152-6818-4353-a541-b3f506b1fc8d.jpg" /> and <img src="1-7401639---16\53418b65-b46a-4f61-8735-db8fc59ef617.jpg" />.</p><p>The proof of Lemma 2 can be found in [<xref ref-type="bibr" rid="scirp.35091-ref16">16</xref>].</p><p>Lemma 3. There exists a constant M &gt; 0 such that S(t) &lt; M, x(t) &lt; M for each solution of (S(t); x(t)) system (2), for t large enough.</p><p>Proof Let (S(t); x(t)) be any solution of system (2) with initial value<img src="1-7401639---16\1beaadbb-cde2-4dca-ac4d-983040c45c54.jpg" />. Define a function<img src="1-7401639---16\b6c3f311-4b71-4c00-9719-de24e6cb34c3.jpg" />.</p><p>Then</p><p><img src="1-7401639---16\dc4508b4-bbd6-4138-b555-193fa31455bf.jpg" /></p><p>From the comparison theorem of impulsive differential equations, we have <img src="1-7401639---16\ebc46a5d-437c-4d8a-892a-b99dde290b86.jpg" /> for all t&#184; 0, where u(t) is the solution of system (3). From Lemma 2, we have <img src="1-7401639---16\1333acea-42a7-4a20-b276-59332b412d5e.jpg" /> as<img src="1-7401639---16\9978f14a-bb86-47e4-809b-4b5bb96e25a6.jpg" />, where</p><p><img src="1-7401639---16\cc48ce60-503e-4990-b497-1f1709131bc2.jpg" /></p><p>Hence,</p><p><img src="1-7401639---16\e6889ad9-1731-41c8-ab41-4a6431432eed.jpg" /></p><p>Thus, V(t) is ultimately bounded. From the definition of V(t), there exists a constant</p><p><img src="1-7401639---16\f445821a-1ed2-4600-a697-34540fdb37b5.jpg" /></p><p>such that S(t) &lt; M, x(t) &lt; M for any solution (S(t), x(t)) of system (2), for t large enough. This completes the proof.</p><p>The solution of system (2) corresponding to x(t) = 0 is called microorganism-free periodic solution. For system (2), if we choose<img src="1-7401639---16\0702fe6f-4c4d-43c1-97fc-26bde9d36d68.jpg" />, then system (2) becomes to the following system</p><disp-formula id="scirp.35091-formula12836"><label>(4)</label><graphic position="anchor" xlink:href="1-7401639---16\c78ff2d3-4782-43c3-8eda-8b342be19f27.jpg"  xlink:type="simple"/></disp-formula><p>System (4) has a unique global uniformly attractive positive solution</p><p><img src="1-7401639---16\42fe5bf1-221b-4c58-9023-b474b14ceb52.jpg" /></p><p>Hence, system (2) has a positive periodic solution <img src="1-7401639---16\f90e8cad-2de9-45d2-b634-7e7e31769dc6.jpg" /> at which microorganism culture fails. In the next section, we will study the global asymptotical stability of the microorganism-free periodic solution <img src="1-7401639---16\4fad7561-9d44-44e3-954f-38126cbadca9.jpg" /> as a solution of system (2).</p></sec><sec id="s3"><title>3. Main Results</title><p>Theorem 1. Suppose</p><disp-formula id="scirp.35091-formula12837"><label>(5)</label><graphic position="anchor" xlink:href="1-7401639---16\bde13cc1-b4b7-4e2a-99a0-df2597b100f7.jpg"  xlink:type="simple"/></disp-formula><p>Then periodic solution <img src="1-7401639---16\6b428e7e-5219-4d24-8665-11001f71352a.jpg" /> of system (2) is globally attractive.</p><p>Proof Let (<img src="1-7401639---16\e238e84f-c034-4b82-bc3a-2a3e980fdabe.jpg" />,<img src="1-7401639---16\96a73761-a4ec-48b0-b197-0a59035701b7.jpg" />) be any positive solution of system (2). Define a function as follows</p><p><img src="1-7401639---16\e257758f-fb25-40b1-b9d1-e1a1a25dbad1.jpg" /></p><p>Then similar to the proof of Lemma 3, we obtain <img src="1-7401639---16\25e85dda-9066-4c64-a9f4-112a4df05697.jpg" /> for all <img src="1-7401639---16\0b8bbd22-87e5-40c8-a102-93770c452b7c.jpg" /> where u(t) is the solution of system (3) and <img src="1-7401639---16\23b5859b-28c4-48b4-9f8f-27bdd6cd1da2.jpg" /> as<img src="1-7401639---16\2f10db72-e8af-4ea5-9c0e-f0cd1deedd6a.jpg" />. Hence, there exists a function <img src="1-7401639---16\20ea259e-c5ec-4b2a-8236-686ea6d58c85.jpg" /> satisfying <img src="1-7401639---16\0421a356-9d2e-4855-8431-e445795e8da0.jpg" /> as <img src="1-7401639---16\25982b9e-c013-4273-aa39-6d0e9e7ba5a0.jpg" /> such that</p><p><img src="1-7401639---16\8f1b9d9a-a16f-400a-8fcf-290f33422802.jpg" /></p><p>By the definition of<img src="1-7401639---16\50833f56-d725-46f8-b476-efaa13bf7f3d.jpg" />, we have</p><p><img src="1-7401639---16\be4b7ed4-73c0-49e0-827f-f15a33fa8765.jpg" /></p><p>It follows from the second equation of system (2) that</p><disp-formula id="scirp.35091-formula12838"><label>(6)</label><graphic position="anchor" xlink:href="1-7401639---16\cb60323e-d060-4aae-ad6f-46e6ef83df5f.jpg"  xlink:type="simple"/></disp-formula><p>From condition (5), for any enough small <img src="1-7401639---16\68e9880e-197b-49d2-8409-bbd66c46df5e.jpg" /> we have</p><p><img src="1-7401639---16\a5601855-6474-4a5f-bb92-287291c691bf.jpg" /></p><p>Since <img src="1-7401639---16\3637cb19-af0b-4cd5-9beb-86d06455abb6.jpg" /> which gives</p><p><img src="1-7401639---16\9ca59c2d-6200-47d9-b163-633224047a5d.jpg" /></p><p>Hence, there exist constants <img src="1-7401639---16\ffd2d88c-7eca-4f79-9a52-42d3601459c9.jpg" /> and<img src="1-7401639---16\30671e6d-47f9-45aa-9ce0-1b01c33d7b97.jpg" />, such that</p><disp-formula id="scirp.35091-formula12839"><label>(7)</label><graphic position="anchor" xlink:href="1-7401639---16\a7028e5c-03c9-4c77-b6b7-40d285cef558.jpg"  xlink:type="simple"/></disp-formula><p>If <img src="1-7401639---16\a1aac4f0-31e5-446f-96a5-280c17bd5d6f.jpg" /> for all<img src="1-7401639---16\828f8ce7-599a-4cf3-a8f3-4811378671e1.jpg" />, then from (6) we have</p><disp-formula id="scirp.35091-formula12840"><label>(8)</label><graphic position="anchor" xlink:href="1-7401639---16\19dea09e-7b0f-4d82-830b-93f4c6e89b3b.jpg"  xlink:type="simple"/></disp-formula><p>For any<img src="1-7401639---16\34c90ce8-2574-4358-a617-fb679a2f5fce.jpg" />, we choose an integer <img src="1-7401639---16\59732f62-c2dd-459b-bd5d-06f70705dd07.jpg" /> such that <img src="1-7401639---16\a43aebdb-22bc-4a34-a970-ff365d33d74d.jpg" /> then integrating (8) from <img src="1-7401639---16\853973d4-8462-48e8-bd83-92939fd822cc.jpg" /> to t, from (7) we have</p><disp-formula id="scirp.35091-formula12841"><label>(9)</label><graphic position="anchor" xlink:href="1-7401639---16\4b3fb085-49d2-4181-9c5c-d77ce5b06a7c.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="1-7401639---16\aff4c165-f77b-48ac-9e2e-154560791322.jpg" /> and M is given in Lemma 3. Since <img src="1-7401639---16\f2584054-b92e-4528-af5b-737658f1bfdc.jpg" /> as<img src="1-7401639---16\e8f336b3-e647-4574-ae89-8b452acc53ab.jpg" />, from (9) we have <img src="1-7401639---16\846a7273-55f4-4303-8ee0-0edb343fc476.jpg" /> as<img src="1-7401639---16\265718d7-e7be-4fe0-913c-6af8c2f0f632.jpg" />, which is a contradiction. Hencethere is a<img src="1-7401639---16\75c8938b-1a5c-49d9-b613-18fe7a49eec2.jpg" />, T<sub>0,</sub> such that<img src="1-7401639---16\f0a3ae1e-7417-45d7-a198-02942b28bcb9.jpg" />.</p><p>Now, we claim that there exists a constant <img src="1-7401639---16\71e6d624-1508-4371-8aa1-851fca524ba5.jpg" /> such that</p><p><img src="1-7401639---16\443ec1e8-ef96-4e2e-a8a2-ac8e47aeed49.jpg" /></p><p>In fact, if there exists a <img src="1-7401639---16\caefacbc-c5c7-4c38-8366-09d9cbf2ad00.jpg" />such that<img src="1-7401639---16\f3e0f8e2-c116-42a4-a9e7-deb0e0310b40.jpg" />, then there exists a <img src="1-7401639---16\94431b68-fe9f-4c8e-b843-21c22f9ac4d6.jpg" /> such that <img src="1-7401639---16\52b632b8-1a7b-4ec8-9fc4-66505795464d.jpg" /> and <img src="1-7401639---16\9d5cdb47-4a3d-47f7-80da-62c4a80ed2ac.jpg" /> for<img src="1-7401639---16\cac05c2f-2474-46b0-9955-dabf7e24807c.jpg" />. Choose an integer <img src="1-7401639---16\20ac324a-b66f-4f57-b60f-0984301727e2.jpg" /> such that <img src="1-7401639---16\a7810abb-fb09-4ff0-9058-cc7188d4b95c.jpg" /> Since for any <img src="1-7401639---16\ddb30bb6-0559-42ce-afd1-5e29b40697e3.jpg" /></p><p><img src="1-7401639---16\c3d80b86-556d-4f8b-a224-c1f580deb841.jpg" /></p><disp-formula id="scirp.35091-formula12842"><label>(10)</label><graphic position="anchor" xlink:href="1-7401639---16\62f179de-fe03-4760-b968-5319110663ba.jpg"  xlink:type="simple"/></disp-formula><p>integrating the above inequality from t<sub>2</sub> to t<sub>1</sub>, from (7) we obtain (10).</p><p>Obviously, let<img src="1-7401639---16\a477ee7d-8754-465a-9d61-d8de81db10a7.jpg" />, then from (10) we obtain a contradiction. Hence, <img src="1-7401639---16\99d6409e-3615-40ef-b02d-e6a34096a135.jpg" />for all<img src="1-7401639---16\33fea93f-2703-465e-bca4-10f9f8415398.jpg" />. Since <img src="1-7401639---16\8a8a3a08-fad2-46a6-945d-3fbb0c97deb7.jpg" /> is arbitrary, we finally have</p><p><img src="1-7401639---16\f6367ea3-b33a-4391-826e-ee9bd808226c.jpg" />.</p><p>This completes the proof.</p><p>Theorem 2. Suppose</p><disp-formula id="scirp.35091-formula12843"><label>(11)</label><graphic position="anchor" xlink:href="1-7401639---16\392acc88-943c-471f-a90b-7e14fdf1f231.jpg"  xlink:type="simple"/></disp-formula><p>Then system (2) is permanent.</p><p>Proof Let (S(t); x(t)) be any solution of system (2) with initial value<img src="1-7401639---16\3463b81c-27ad-43fe-aba8-6281d4bf629b.jpg" />. By Lemma 3, the first equation of system (2) becomes</p><p><img src="1-7401639---16\a5f1a281-7f5b-4bc2-a4cf-dc78d3ef9d01.jpg" /></p><p>Using Lemma 2 and the comparison theorem of impulsive differential equation, we obtain <img src="1-7401639---16\b25b7189-ebbf-4ad5-a5a9-c7a0759040c1.jpg" /> for all, <img src="1-7401639---16\7e59c864-258d-460b-a4d9-aeb2e421e35d.jpg" />where <img src="1-7401639---16\981c3829-8a8f-4d7e-a76d-4cbc783e5ef3.jpg" /> is the solution of the following impulsive system</p><p><img src="1-7401639---16\8c515fe6-da71-4856-b12c-cd55e7e39100.jpg" /></p><p>with initial condition<img src="1-7401639---16\ee3679d9-030d-415a-87a5-c226b97a2743.jpg" />. Further from Lemma 2, we have</p><p><img src="1-7401639---16\56afbc19-a532-4e07-b0bb-b7649b3aa1f5.jpg" /></p><p>where</p><p><img src="1-7401639---16\381eb0b9-2dae-4e22-949d-5c76065db563.jpg" /></p><p>Therefore, we finally obtain</p><p><img src="1-7401639---16\50a9270f-ffe8-4cb8-81ff-cb17026e7c7b.jpg" /></p><p>This shows that S(t) in system (2) is permanent.</p><p>In the following, we want to find a constant<img src="1-7401639---16\ef84f2ef-c78e-4d90-a2e7-454ba07389fb.jpg" />, such that <img src="1-7401639---16\b0f5d57c-ae89-499c-91ac-bd3bda991c99.jpg" /> for t large enough.</p><p>Since</p><p><img src="1-7401639---16\0d382aee-5ffd-4c96-b604-215fd804b9ed.jpg" /></p><p>we can chose a constant <img src="1-7401639---16\aae1b0b7-2b21-47ff-a201-2b9d02296d48.jpg" /> small enough such that</p><p><img src="1-7401639---16\e453c8ee-5e9a-4a85-b320-f0a96d562468.jpg" /></p><p>Consider the following auxiliary impulsive system</p><disp-formula id="scirp.35091-formula12844"><label>(12)</label><graphic position="anchor" xlink:href="1-7401639---16\db589636-6cc3-4fb2-bb3e-9e36ae4a9b80.jpg"  xlink:type="simple"/></disp-formula><p>from Lemma 2, system (12) has a globally uniformly attractive positive periodic solution</p><p><img src="1-7401639---16\041beb43-a1b4-4ead-836f-0b0ba4ea1979.jpg" /></p><p>Since<img src="1-7401639---16\ff27de13-ce41-4e3f-9d32-cb21dd83f10e.jpg" />, for above<img src="1-7401639---16\f93a3f6d-56f7-455a-ae67-0b3485647a19.jpg" />, there is a <img src="1-7401639---16\c9ee6048-8ff3-4618-98e5-57a049ec2586.jpg" /> and <img src="1-7401639---16\c181a832-5a3e-4ade-b601-90026df06412.jpg" /> such that</p><disp-formula id="scirp.35091-formula12845"><label>(13)</label><graphic position="anchor" xlink:href="1-7401639---16\0d7dcaaf-fdfa-4522-8ffd-06218336c488.jpg"  xlink:type="simple"/></disp-formula><p>Further, for above <img src="1-7401639---16\5c1504b0-27e8-44f5-953e-1d0f235e3c35.jpg" /> and M &gt; 0, where M is given in Lemma 3, there is a <img src="1-7401639---16\0729b901-b919-491f-8843-563374d5510f.jpg" /> such that for any <img src="1-7401639---16\e1c151ee-b904-4046-8a24-4f3531cb6780.jpg" /> and <img src="1-7401639---16\50026c65-525c-4fbe-897f-eedc9cfc30ae.jpg" /> we have</p><disp-formula id="scirp.35091-formula12846"><label>(14)</label><graphic position="anchor" xlink:href="1-7401639---16\aa4f00d3-70f8-484c-af4f-af30ef18a677.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="1-7401639---16\937239ff-752c-41a2-ad5a-4e901421df83.jpg" /> is the solution of system (12) with initial condition<img src="1-7401639---16\4119d576-c476-494b-85e0-c2af01c1f579.jpg" />.</p><p>For any <img src="1-7401639---16\e2e6c05d-65b7-4d5c-9b66-4947aaeb8718.jpg" />&#184; if <img src="1-7401639---16\37b4b480-2add-4c4f-98c1-f87fb837b36b.jpg" /> for all<img src="1-7401639---16\df5b3f57-86d5-4008-860e-6e5ea84cd8e5.jpg" />, then from system (2) we have</p><p><img src="1-7401639---16\05062f1b-6c18-4723-911c-f836d514f9ad.jpg" /></p><p>By the comparison theorem of impulsive differential equations, we have <img src="1-7401639---16\fa72b90b-84e6-4534-a234-b70ed3c05761.jpg" /> for<img src="1-7401639---16\809023a2-4367-4604-93e0-827d219ee334.jpg" />, where y(t) is the solution of system (12) with initial condition<img src="1-7401639---16\bd3116fb-1ec0-4ec0-8d6f-425650a2fbdc.jpg" />. From (14) we have</p><p><img src="1-7401639---16\fea789b7-d6b2-4f30-8d12-8095b704b2eb.jpg" /></p><p>Hence, from (13) we further have</p><p><img src="1-7401639---16\187fc3c0-a57e-45b5-80d6-2fdea6d2a365.jpg" /></p><p>From the second equation of system (2) we have</p><disp-formula id="scirp.35091-formula12847"><label>(15)</label><graphic position="anchor" xlink:href="1-7401639---16\375e5f64-2afa-4306-9e66-f0c0417b5c5c.jpg"  xlink:type="simple"/></disp-formula><p>Let <img src="1-7401639---16\4bcad997-a187-466b-bdbc-0be93f8dbaf0.jpg" /> such that<img src="1-7401639---16\2df83a05-6625-4e84-82b3-859e7b0984c9.jpg" />. Integrating (15) on <img src="1-7401639---16\a07af8eb-2fb0-4be8-9185-bc4127be2b43.jpg" /> for all<img src="1-7401639---16\1f2dc634-2beb-4686-93b2-77d8020837ce.jpg" />, we have</p><p><img src="1-7401639---16\b5b8d009-6d8e-4562-8874-8d301f6a3c47.jpg" /></p><p>Hence, <img src="1-7401639---16\a5f88193-a40b-4e60-ac4d-48c620474d35.jpg" />for all<img src="1-7401639---16\4b613fb8-cdd0-4b30-8b73-450db4fd3c11.jpg" />. Then we have<img src="1-7401639---16\dca70eb9-7ca0-4d37-b26d-92cbc16b48e0.jpg" />, which is a contradiction. Hence, there exists a <img src="1-7401639---16\42ff2be4-9c13-4ea3-85b6-c6f0edc7883d.jpg" /> such that<img src="1-7401639---16\d5dc57ae-8327-4447-a4df-a2fb8857390b.jpg" />.</p><p>If <img src="1-7401639---16\eec1b5f0-b8dd-41a5-9972-d8dbd95c4886.jpg" /> for all<img src="1-7401639---16\57f8c3e4-4ca1-49d9-b50b-d82e4bf48157.jpg" />, then our goal is obtained. Hence, we need only to consider these solutions which are oscillatory about<img src="1-7401639---16\fb6fa33a-69cf-43cc-a7bd-758f8622c6fe.jpg" />. Let <img src="1-7401639---16\92b21a88-7eeb-42e2-beff-27f515244cb6.jpg" /> and <img src="1-7401639---16\6389d15b-f14c-4479-bb98-d3e6235ff3c0.jpg" /> be two large enough times such that <img src="1-7401639---16\7a0da7b8-f767-44bb-9a70-b7546625d9c5.jpg" /> and <img src="1-7401639---16\ff92b84c-9266-411e-9340-56a204b9df7c.jpg" /> for all<img src="1-7401639---16\75424e08-ae38-47ca-b588-d12e95cc0b2e.jpg" />. When<img src="1-7401639---16\13d4f3d4-fa7d-4eeb-bffe-51d48e8fe60f.jpg" />, since</p><p><img src="1-7401639---16\0f3e9c53-a465-49bb-93f7-37cc0286e5a3.jpg" /></p><p>integrating this inequality for any<img src="1-7401639---16\41e72a4f-fd44-46cb-a88a-89968104ccff.jpg" />, we have</p><disp-formula id="scirp.35091-formula12848"><label>(16)</label><graphic position="anchor" xlink:href="1-7401639---16\b2c47ecb-fb26-4fe7-b115-e639b41be1d3.jpg"  xlink:type="simple"/></disp-formula><p>Let<img src="1-7401639---16\7b3c59d3-90ac-4fc3-a518-9e76f64aeb26.jpg" />. For any<img src="1-7401639---16\324b398f-3d9c-420a-a6c5-4086df292f65.jpg" />, if<img src="1-7401639---16\5bd398c5-fd44-4e41-bb71-996da1a6acf4.jpg" />, then according to the above discussing on the case of<img src="1-7401639---16\dbdf1778-7726-41f3-b583-df4a22b2c087.jpg" />, we also have inequality (16). Particularly, we obtain<img src="1-7401639---16\a2cb1c3c-ad78-48fd-b332-0497933fb068.jpg" />, since <img src="1-7401639---16\f5a9cb69-226e-41e7-9a50-0feda011f773.jpg" /> for all<img src="1-7401639---16\f55d295e-2286-48a5-a96e-2bd8b461d986.jpg" />, from system (2) we have</p><p><img src="1-7401639---16\1a02e67f-fa41-4efe-a76a-bc1c37ebed6e.jpg" /></p><p>Hence, from the comparison theorem of impulsive differential equations, we have <img src="1-7401639---16\fb9c417d-8fec-48a8-a891-637839c2313e.jpg" /> for all<img src="1-7401639---16\91b706ac-0e81-4e06-9837-93d1b0395609.jpg" />, where y(t) is the solution of system (12) with initial condition<img src="1-7401639---16\8e7c199d-0f7e-419d-b6d8-e85c62ed63ca.jpg" />. From (14), we have</p><p><img src="1-7401639---16\c23c51b5-4846-408f-a186-9a38276e4ace.jpg" /></p><p>Further from (13), we also have</p><p><img src="1-7401639---16\5e069621-4db4-4286-baf3-65a5a6bd5f0d.jpg" /></p><p>Thus, from system (2), we have</p><disp-formula id="scirp.35091-formula12849"><label>(17)</label><graphic position="anchor" xlink:href="1-7401639---16\c49930bc-1dd0-43e5-a7cf-6bd19d46affd.jpg"  xlink:type="simple"/></disp-formula><p>For any<img src="1-7401639---16\52b9e291-7c6e-489b-85ba-5aedb95d07b1.jpg" />, we choose an integer <img src="1-7401639---16\36ab0d46-3005-42ea-ad77-b62b868a3d62.jpg" /> such that</p><p><img src="1-7401639---16\72088f13-fce4-4dcc-87b5-adc2317f094b.jpg" />.</p><p>Integrating (17) from <img src="1-7401639---16\866ac80e-dcc4-4e33-b4ed-dd7c0fa091bd.jpg" /> to t, we have</p><p><img src="1-7401639---16\f377441f-5572-4378-ad93-147b8b9fe68d.jpg" /></p><p>where</p><p><img src="1-7401639---16\85c08769-1164-4fdd-8e79-50fc857af831.jpg" /></p><p>From the above discussion, we have<img src="1-7401639---16\1be4e813-7ae0-45d4-ac5d-13ae83d3008b.jpg" />, and <img src="1-7401639---16\cefd5e60-adc7-4954-b690-85625c993454.jpg" /> is independent of any solution (S(t); x(t)) of system (2). This completes the proof.</p><p>As a consequence of Theorem 1 and Theorem 2, we have the following corollary.</p><p>Corollary 1 For system (2), the following conclusions hold.</p><p>a) The microorganism-extinction solution <img src="1-7401639---16\bb4ddc79-5752-4738-8dc6-70d4d8b20d50.jpg" /> is globally attractive if and only if</p><p><img src="1-7401639---16\94b5d19b-d902-4f4d-bd0e-a15586327ca4.jpg" /></p><p>b) The microorganism x(t) of System (2) is permanent if and only if</p><p><img src="1-7401639---16\f3a07afc-ff9a-4410-984a-222fa22b2c14.jpg" /></p></sec><sec id="s4"><title>4. Discussion and Numerical Analysis</title><p>In this paper, we investigate Beddington-DeAngelis type chemostat with nutrient recycling and impulsive input. We prove that the microorganism-free periodic solution of the system (2) is globally attractive. The necessary and sufficient condition for permanence of system (2) are obtained in this paper.</p><p>According to Theorem 1, the microorganism-free periodic solution <img src="1-7401639---16\e756005b-3129-423e-962b-4c919a5bed98.jpg" /> is globally attractive if (5) hold. That is, this kind of microorganisms can not be cultivated under this condition. Suppose that <img src="1-7401639---16\22e6a4b8-bc3c-4c7a-8b45-97dce92040d6.jpg" /> and set</p><p><img src="1-7401639---16\78a20969-765e-44ba-9b9d-a5ddc5b2f9df.jpg" /></p><p>Then Theorem 1-2 can be state as: If <img src="1-7401639---16\7dc1a438-c8fb-4d33-92ec-346ca938c5a9.jpg" /> and<img src="1-7401639---16\b4647f11-d725-4fa0-923c-028c8f4d098b.jpg" />, then the microorganism will eventually disappear; If <img src="1-7401639---16\54a6ed25-1d4d-43fb-ab6a-77c7aef8d8f3.jpg" /> and<img src="1-7401639---16\3a6a57b1-40fa-4aba-8d5a-4a068ebec0e8.jpg" />, then system (2) is permanent. This implies that if we choose a smaller impulsive input of nutrient when the death rate of microorganism is larger than some certain value, then the microorganism x(t) will tend to extinct; If we choose a lager impulsive input of nutrient, then system can coexist. By the above analysis, we know that conditions for the system coexist or non-coexist are due to the influences of the impulsive perturbations.</p><p>In order to illustrate our mathematical results and investigate the effect of impulsive input nutrient we present the following results of a numerical simulation.</p><p>From Theorem 1, we consider dynamical behavior of the system (2) with D =2, a = 5, A = 20, B = 2, b = 1, k = 0.5, r = 0.5, p = 10, T = 2, then system (2) becomes</p><disp-formula id="scirp.35091-formula12850"><label>(18)</label><graphic position="anchor" xlink:href="1-7401639---16\99e3befd-da41-436f-a3e8-5d626a4b9858.jpg"  xlink:type="simple"/></disp-formula><p>By calculating, we obtain</p><p><img src="1-7401639---16\dec8db02-1b8b-4688-81e5-ddb86207e286.jpg" /></p><p>and</p><p><img src="1-7401639---16\a024845e-2c3e-4571-bdc4-4ba1a9d44fce.jpg" /></p><p>That is condition (5) holds. We choose initial value <img src="1-7401639---16\5c052565-34d9-4e98-8f54-64846ddd461b.jpg" /> = (1,1.3), (1,2.5), (3,3.4), (4,4.7), (5,6), (6,7.3), (7,7.9), (8,9.5), (9,10.7), (10,12.5) respectively, then from the numerical simulation (<xref ref-type="fig" rid="fig1">Figure 1</xref>) we see that there exists a positive periodic solution <img src="1-7401639---16\5460e185-12fa-47f9-b090-35c739302f8d.jpg" /> of system (18) such that any solution (S(t), x(t)) of system (20) with initial value <img src="1-7401639---16\be538272-4244-411c-970f-84beb36b1fe3.jpg" /> tends to <img src="1-7401639---16\f65d07c9-3ff8-47ff-8532-1d5e503316b6.jpg" /> as<img src="1-7401639---16\ae50c8f5-bc26-4659-a5b5-d44899f62e7b.jpg" />. Therefore, if condition (5) holds, then system (18) has a positive periodic solution which is globally attracttive.</p><p>From Theorem 1, we consider dynamical behavior of the system (2) with D =1, a = 10, A = 10, B = 2, b = 1, k = 0.5, r = 0.2, p = 12, T = 2, then system (2) becomes</p><disp-formula id="scirp.35091-formula12851"><label>(19)</label><graphic position="anchor" xlink:href="1-7401639---16\d3d5bcc8-4ba9-4519-aae5-5da16eb9cb10.jpg"  xlink:type="simple"/></disp-formula><p>By calculating, we obtain</p><p>and</p><p><img src="1-7401639---16\907bf579-4af8-4354-84a4-db1a79aa5060.jpg" /></p><p>That is condition (11) holds. We choose initial value <img src="1-7401639---16\7a7d11b1-d2c8-4f2d-a41b-6ec44fb1ee9f.jpg" /> then from the numerical simulation (<xref ref-type="fig" rid="fig2">Figure 2</xref>) we see that system (19) is permanent.</p><p>It is difficult to study the global attractivity of system (2) analytically. We present here two examples to show that system (2) is global attractive under the condition (11). Setting D = 1, a = 6, A = 8, r = 0:4, p = 18, T = 2, b = 1, so that condition (11) holds. Choosing initial value <img src="1-7401639---16\b4881bf5-511f-4a63-841e-78503cb70e60.jpg" /> (2.5,1.6), (4.7,2.6), (7.1,6.3), (9.4,5.8), (12.2,7.3), (14.4), (16.5,9.7), (19.3,11.4), (21.4,12.5), (23,12), respectively, then from the numerical simulation (<xref ref-type="fig" rid="fig3">Figure 3</xref>) we see that there exist a unique T-period solution <img src="1-7401639---16\1403584e-bb5a-4eca-a05e-5224445d119c.jpg" /> of system (2) which is globally attractive. Let D = 1, a = 6, A = 8, r = 0:2, p = 20, T = 2, b = 1. Then the condition (3.9) holds for those parameters. Choosing initial values <img src="1-7401639---16\12527ecf-f161-43e4-b9b6-98ac6aa9a3da.jpg" /> = (0.5,0.4), (1,0.8), (1.5,1.2), (2,1.6), (2.5,2), (3,2.4), (3.5,2.8), (4,3.2), (4.5,3.6), (5,4), respectively, the numerical simulation (<xref ref-type="fig" rid="fig3">Figure 3</xref>) also show that system (2) is globally attractive. Therefore, we can guess if only condition (11) holds then</p><p>the system (2) has a unique T-period solution which is globally attractive</p></sec><sec id="s5"><title>5. Acknowledgements</title><p>This work was supported by the National Natural Science Foundation of China (Grant Nos. 11261056, 11261058).</p></sec><sec id="s6"><title>REFERENCES</title></sec><sec id="s7"><title>NOTES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.35091-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">H. L. 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