<?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">APM</journal-id><journal-title-group><journal-title>Advances in Pure Mathematics</journal-title></journal-title-group><issn pub-type="epub">2160-0368</issn><publisher><publisher-name>Scientific Research Publishing</publisher-name></publisher></journal-meta><article-meta><article-id pub-id-type="doi">10.4236/apm.2014.41003</article-id><article-id pub-id-type="publisher-id">APM-41731</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>
 
 
  Common Fixed Points for a Countable Family of Set-Valued Mappings with Quasi-Contractive Conditions on Metrically Convex Spaces
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>uexi</surname><given-names>Jin</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>Ailian</surname><given-names>Jin</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>Yongjie</surname><given-names>Piao</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>Department of Mathematics, College of Science, Yanbian University, Yanji, China</addr-line></aff><author-notes><corresp id="cor1">* E-mail:<email>yuexi1004@163.com(UJ)</email>;<email>aljin@ybu.edu.cn(AJ)</email>;<email>pyj6216@hotmail.com(YP)</email>;</corresp></author-notes><pub-date pub-type="epub"><day>08</day><month>01</month><year>2014</year></pub-date><volume>04</volume><issue>01</issue><fpage>17</fpage><lpage>24</lpage><history><date date-type="received"><day>December</day>	<month>10,</month>	<year>2013</year></date><date date-type="rev-recd"><day>January</day>	<month>10,</month>	<year>2014</year>	</date><date date-type="accepted"><day>January</day>	<month>17,</month>	<year>2014</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, we consider a countable family of set-valued mappings satisfying some quasi-contractive conditions. We also construct a sequence by the quasi-contractive conditions of mappings and the boundary condition of a closed subset of a metrically convex space, and then prove that the unique limit of the sequence is the unique common fixed point of the mappings. Finally, we give more generalized common fixed point theorems for a countable family of single-valued mappings. The main results generalize and improve many common fixed point theorems for a finite or countable family of single valued or set-valued mappings with quasi-contractive conditions. 
 
</p></abstract><kwd-group><kwd>Common Fixed Point; Quasi-Contractive; Metrically Convex; Complete</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>There have appeared many fixed point theorems for a single-valued self map of a closed subset of a Banach space. However, in many applications, the mapping under considerations is not a self-mapping on a closed subset. In 1976, Assad [<xref ref-type="bibr" rid="scirp.41731-ref1">1</xref>] gave sufficient condition for such single valued mapping to obtain a fixed point by proving a fixed point theorem for Kannan mappings on a Banach space and putting certain boundary conditions on the mapping. Similar results for multi-valued mappings were respectively given by Assad [<xref ref-type="bibr" rid="scirp.41731-ref2">2</xref>] and Assad and Kirk [<xref ref-type="bibr" rid="scirp.41731-ref3">3</xref>]. On the other hand, many authors discussed common fixed point problems [4-7] for finite single or multi-valued mappings on a complete 2-metric convex space or a complete cone metric space respectively. And some authors also discussed common fixed point problems [8-13] for a countable family of self-single-valued mappings with contractive or quasi-contractive conditions on a metric space or a metrically convex space respectively. These results improved and generalized many previous works.</p><p>In this paper, we will discuss the existent problems of common fixed points for a countable family of surjective set-valued mappings, which satisfy certain quasi-contractive condition, defined on a complete metrically convex space and obtain some important theorems. The main results in this paper further generalize and improve many common fixed point theorems for single valued or multi-valued mappings with quasi-contractive type conditions.</p><p>Through this paper, <img src="3-5300618x\3bfebee9-4415-4200-b947-1f0454fd5f4b.jpg" />(or<img src="3-5300618x\d94b04cf-8f39-4d45-b6b7-30d1bbffe6b5.jpg" />) is a metric space. Let <img src="3-5300618x\064d1f59-e6c5-4d4b-8ae5-9d9a80dd8202.jpg" /> denote the families of all bounded closed subset of<img src="3-5300618x\9a3ce1f3-30d5-450c-919d-0ea2cf770c3c.jpg" />.</p><p>Let<img src="3-5300618x\ef3388ad-17d5-44e8-bbd9-5fa59a0c85c0.jpg" />, the distance between <img src="3-5300618x\267d0306-d2d2-4a6f-bc53-b5f92e4552ff.jpg" /> and<img src="3-5300618x\e8d802ae-244d-402a-b62d-c7be4b49d2f6.jpg" />.</p><p>Definition 1.1. ([8-10]) A metric space <img src="3-5300618x\232da29a-f6e8-4c2f-9602-7a8a3b2f821f.jpg" /> is said to be metrically convex, if any <img src="3-5300618x\403370a0-1f21-4471-8e8d-fd6a30d157bb.jpg" /> with<img src="3-5300618x\2191e0d8-b425-4d3a-995b-b2755907422e.jpg" />, there exists <img src="3-5300618x\7dbae0b6-c168-4c1a-96d3-984c81a0da05.jpg" /> such that<img src="3-5300618x\05e22592-4f7e-49c0-bb17-736037205a01.jpg" />, <img src="3-5300618x\d31f17f0-5e22-4319-a5bd-3cc27770a36e.jpg" />and<img src="3-5300618x\d015c9fe-1019-41d6-88ff-a46b90387e87.jpg" />.</p><p>Lemma 1.1. ([3,8]) If <img src="3-5300618x\18c41262-c04f-41d6-867a-6dd4e3514417.jpg" /> is a nonempty closed subset of a complete metrically convex space<img src="3-5300618x\f371efbb-c689-495e-be1a-ec4720151320.jpg" />, then for any <img src="3-5300618x\9eee2a98-9538-435e-8e91-8a239a23c436.jpg" /> and<img src="3-5300618x\17226349-8571-4f82-b73b-ea4ea0865bff.jpg" />, there exists <img src="3-5300618x\d91d431a-2365-4084-87d8-507ce992e00b.jpg" /> which satisfies<img src="3-5300618x\39c35e10-d0cd-4de3-b423-e67ac5009339.jpg" />.</p><p>Lemma 1.2. ([<xref ref-type="bibr" rid="scirp.41731-ref13">13</xref>]) If <img src="3-5300618x\b0eb8d88-6a94-46a7-bc15-3572abd4190d.jpg" /> is a complete metric space and<img src="3-5300618x\7ddd7a26-19f8-49b5-923b-6c01760a4070.jpg" />, then <img src="3-5300618x\fd0b9aad-2ca0-4b12-b18d-57e4cc13e471.jpg" /> is continuous on<img src="3-5300618x\f5c250c9-5ada-44ee-a7a7-42f6b591b7c9.jpg" />. Moreover, we have :</p><p>1)<img src="3-5300618x\da50c442-c413-4d4b-ba53-0fd9fb50ca19.jpg" />;</p><p>2) <img src="3-5300618x\3f93fb56-599a-4175-9270-9db471d5e980.jpg" />if and only if<img src="3-5300618x\d31d6823-b028-4d32-aad0-0fb62a42e7e8.jpg" />,<img src="3-5300618x\09923110-ec6d-4f11-90ed-18cee8407ace.jpg" />;</p><p>3) for any<img src="3-5300618x\1878fedf-faff-4c8a-a2c5-6b238939e45a.jpg" />,<img src="3-5300618x\52912228-c648-46c9-8132-22d7827d56a1.jpg" />.</p></sec><sec id="s2"><title>2. Main Results</title><p>Theorem 2.1. Let <img src="3-5300618x\119b54f8-b948-47b0-b734-436369ced02c.jpg" /> be a nonempty closed subset of a complete metrically convex space <img src="3-5300618x\2e966e74-8d4f-49e3-bc28-8d115d1593c7.jpg" /> with<img src="3-5300618x\baa22c53-e417-41cd-a143-d67e69c980d4.jpg" />, <img src="3-5300618x\ecf4317c-cc48-4b42-ae38-ad5ceea16643.jpg" />a countable family of surjective set-valued mappings with nonempty values such that for any <img src="3-5300618x\7bf8b519-f177-47fe-a721-da464877676b.jpg" /> with<img src="3-5300618x\d95b2966-b66d-46df-899f-80dc15db280f.jpg" />, any<img src="3-5300618x\fd8db726-898a-4e68-a24f-960f513f76dd.jpg" />,</p><disp-formula id="scirp.41731-formula82216"><label>(1)</label><graphic position="anchor" xlink:href="3-5300618x\891151b5-7919-48b2-9de7-0f239e413383.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="3-5300618x\7ac21b4d-66c2-4469-8e5c-68fa8b0a860d.jpg" /> and <img src="3-5300618x\ea70538a-50ca-46dc-b7db-20f8be3bc548.jpg" /> is a constant number.</p><p>Furthermore, if <img src="3-5300618x\8495b0f8-4588-41b5-b251-306c76c8a083.jpg" /> for all<img src="3-5300618x\0a3cca9d-d591-4f7d-a6ac-e716c4775685.jpg" />, and for each <img src="3-5300618x\39bd9476-cd92-454e-8d5d-99a4b024c2e7.jpg" /> and <img src="3-5300618x\94f6c22d-41f9-4831-9938-e1748f457aff.jpg" /> and any<img src="3-5300618x\37f57bc7-3240-49d7-95c4-9e784de8ea2e.jpg" />, there exists <img src="3-5300618x\32880652-30fc-463e-ab08-92e8946d4aa0.jpg" /> such that<img src="3-5300618x\65a4e1dd-51c6-47a8-8264-80635506c18e.jpg" />, then <img src="3-5300618x\9804a390-9d2b-49c2-a526-6a82c8a54c69.jpg" /> has a unique common fixed point in<img src="3-5300618x\d08cf946-b7f1-44ed-8265-3cebdd85f81d.jpg" />.</p><p>Proof Take<img src="3-5300618x\88257d54-cd0c-493e-86f2-65f257161a9e.jpg" />. We will construct two sequences <img src="3-5300618x\47b029b9-b6b3-4955-b77f-3316655670e5.jpg" /> and <img src="3-5300618x\d0fda22a-5bb9-44cb-a21b-ec230ea534a1.jpg" /> in the following manner. Since <img src="3-5300618x\84e1ea04-c0c4-4f2b-a991-344e551c7216.jpg" /> is on-to, there exists <img src="3-5300618x\24f24ac6-1193-4b95-a6fd-ca89731bb69e.jpg" /> such that<img src="3-5300618x\9fc51f9a-03db-4a41-aea1-e6d721abac44.jpg" />. If<img src="3-5300618x\a831bcb7-2e4e-457c-9b52-34d4fb242bbc.jpg" />, then put<img src="3-5300618x\84882813-cb7a-491a-9077-d1708d64e07c.jpg" />; if<img src="3-5300618x\7e23131f-35f7-4718-a51a-2caa4de74ea4.jpg" />, then by Lemma 1.1 there exits <img src="3-5300618x\09f57719-dc0e-4458-9d41-d4efd362d865.jpg" /> such that<img src="3-5300618x\fcd5aeb7-de4e-4949-8fef-cedbbd565427.jpg" />. For<img src="3-5300618x\f3ad6080-84a3-420d-8d9b-4404d25129e5.jpg" />, since <img src="3-5300618x\d283787c-9376-4a83-9bf3-1677097146ce.jpg" /> is on-to, there exists <img src="3-5300618x\d7f78fe9-40fe-4a32-807b-634ca7808683.jpg" /> such that<img src="3-5300618x\17caa675-6dda-4017-a10f-02aea87ece58.jpg" />. If<img src="3-5300618x\95cf33ca-fbfe-4959-8bac-51dc606786cf.jpg" />, then put<img src="3-5300618x\8354c0f9-4473-482d-a63e-2073e0e958e6.jpg" />; if<img src="3-5300618x\9a27ef5d-fb8b-4f91-9020-3cb022a0ed37.jpg" />, then by Lemma 1.1 there exists <img src="3-5300618x\0e09b6bb-33d3-4fdc-a347-1627faa93371.jpg" /> such that<img src="3-5300618x\22e26301-8bbf-43cd-91fe-29d85caef536.jpg" />. Continuing this way, we obtain <img src="3-5300618x\ee52436d-9313-4e23-ae7a-3a21dbe9f9b5.jpg" /> and<img src="3-5300618x\60d67cf2-10c4-4d00-aa34-0a2a20f51140.jpg" />:</p><p>1)<img src="3-5300618x\112f22cd-9e22-45f6-88e2-ae065e19c71e.jpg" />;</p><p>2) if<img src="3-5300618x\0969a604-d22d-4f29-a8b1-18d1286f28bd.jpg" />, then put<img src="3-5300618x\3d735863-f658-41a0-9e14-7aa3ea95ad5c.jpg" />;</p><p>3) if<img src="3-5300618x\34218e95-4e7a-4091-af58-959f835d6c14.jpg" />, then by Lemma 1.1 there exists <img src="3-5300618x\e2163215-6db5-4c29-b8a3-31a5c6af930e.jpg" /> such that <img src="3-5300618x\463ce339-b085-4d1f-8aa0-718bffba72ec.jpg" /></p><p>4) <img src="3-5300618x\08b1758a-c0cb-4de9-b228-c248ab059951.jpg" />for all <img src="3-5300618x\f8e75010-c023-44ba-950e-df7f16e00082.jpg" /></p><p>Let <img src="3-5300618x\66e707b1-449b-4d51-839d-fc11b77d0deb.jpg" /> and<img src="3-5300618x\2e31a264-1d15-40a9-8469-013ab1d23421.jpg" />. If there exists <img src="3-5300618x\0b2d96f3-b796-43d0-a46c-7fa95803af86.jpg" /> such that<img src="3-5300618x\d0410918-8cc6-4ff1-b1a7-e38bd397cff9.jpg" />, then <img src="3-5300618x\5a4cf6cd-74a0-4a99-9a3a-7d6c293b93bc.jpg" /> In fact, By 3) and the definition of<img src="3-5300618x\64a8ba01-0212-4ebf-b949-8033229c40c5.jpg" />, we have that<img src="3-5300618x\27ea5c67-7696-4ced-8ea9-966c2ad55b83.jpg" />, <img src="3-5300618x\e35135b2-834d-4a17-af83-8ccb809be01f.jpg" />,<img src="3-5300618x\e78023e6-d187-4822-bd52-c6ffb254cbc6.jpg" />. If<img src="3-5300618x\6db7e0b2-4929-41ee-9772-4c7910328b8a.jpg" />, then<img src="3-5300618x\d02c274c-9997-4f9c-8a72-0fdb54b29a2a.jpg" />. On the other hand, since <img src="3-5300618x\61b100c7-0f85-4464-9461-fd1d4c9da764.jpg" /> and<img src="3-5300618x\98097230-99f8-4e24-affb-7f77122512e7.jpg" />, hence <img src="3-5300618x\53b8b58c-c403-4926-a634-6839d30699a7.jpg" />which is a contradiction. If<img src="3-5300618x\4d0e5a12-29db-45a6-8f78-fb57e7082c65.jpg" />, then <img src="3-5300618x\0c376d2b-703c-47d4-b14b-79940d3a60f3.jpg" /> and<img src="3-5300618x\333076b0-6fe6-41e8-b2a9-4bf1d3b15a21.jpg" />, hence<img src="3-5300618x\8db43e4f-5513-496b-8d02-35ef34563d00.jpg" />, so<img src="3-5300618x\e2f4df78-f0a7-4e51-b983-fd4f9f0056e6.jpg" />, which is another contradiction.</p><p>By the definitions and properties of <img src="3-5300618x\2a56e686-765e-476a-ae12-ce4ce91c848b.jpg" /> and<img src="3-5300618x\ed22ba40-f4dd-4b7f-b13c-c080c5a75f57.jpg" />, we can estimate <img src="3-5300618x\c0f4d75d-5fa3-4a19-8696-065b7afcbc38.jpg" /> into three cases:</p><p>Case I.<img src="3-5300618x\6a8e998e-a964-4912-b1b2-90a1e8ea59d7.jpg" />. In this case, <img src="3-5300618x\a66a22b0-7377-419b-9a72-3fcffaa60361.jpg" />, <img src="3-5300618x\527d4202-fdde-49af-84d2-90021bdf0829.jpg" />, <img src="3-5300618x\181f73af-2e9f-40f5-869b-6844698fccb7.jpg" />and<img src="3-5300618x\95193109-03fb-46d6-b7f5-06180ae7f061.jpg" />. And we have</p><p><img src="3-5300618x\79d8cf07-d754-4ae5-85be-095484d54448.jpg" /></p><p>where</p><p><img src="3-5300618x\eb5dfd10-30d7-4295-ace4-acf53ac8d303.jpg" /></p><p>If <img src="3-5300618x\7b937be5-436a-4d8b-bc8f-e31d961caa55.jpg" /> then</p><p><img src="3-5300618x\116fc80a-3c08-4b04-afc0-937ddb305818.jpg" /></p><p>hence</p><p><img src="3-5300618x\8f998fa1-2e78-4411-bc15-6e8284cdeebc.jpg" /></p><p>If<img src="3-5300618x\12cc1ee9-94fc-41b5-b055-d0ffbec5714a.jpg" />, then</p><p><img src="3-5300618x\6b7885b2-bbd6-40d3-ab78-c79529dd248f.jpg" /></p><p>hence</p><p><img src="3-5300618x\67965991-2809-4f99-85c6-9499ac88e255.jpg" /></p><p>Therefore, in any situation, we have</p><p><img src="3-5300618x\0408fec7-7062-4b2c-b439-527eb080e81b.jpg" /></p><p>Case II. <img src="3-5300618x\e1c8d3b8-24f8-4a5b-9db6-9c78ff645820.jpg" />and<img src="3-5300618x\ea800a51-83c0-440a-927d-5bd56239ef0c.jpg" />. In this case, <img src="3-5300618x\9dfb424f-491b-4403-9fa5-6c515d0a318b.jpg" />, <img src="3-5300618x\90e36c26-8747-421b-ba17-0674cba22019.jpg" />and <img src="3-5300618x\5fd0f705-8e0b-44ba-9c77-665078d54de6.jpg" /> and<img src="3-5300618x\5e8787d0-ecb3-4fdf-8687-36e840be9932.jpg" />. And we have</p><p><img src="3-5300618x\1740cf3f-2dd7-4db1-b29f-f01606109412.jpg" /></p><p>where</p><p><img src="3-5300618x\6899fec1-ff5d-4615-9f95-cb4d0b681bf7.jpg" /></p><p>If <img src="3-5300618x\943733b1-e2cc-4add-869c-33a293369490.jpg" /> then</p><p><img src="3-5300618x\6a8b16dd-3fb9-44b3-a3fe-6434c530e875.jpg" /></p><p>hence</p><p><img src="3-5300618x\6735759b-c660-40a6-90f1-39f5b7f0ace5.jpg" /></p><p>If<img src="3-5300618x\96c7d24d-188b-4ac7-8dd4-5b195bcd8d40.jpg" />, then</p><p><img src="3-5300618x\0c7e6a91-be38-4230-9447-b498833923e1.jpg" /></p><p>hence</p><p><img src="3-5300618x\aeac6cde-3e10-4dd8-b1ba-50697dabef8c.jpg" /></p><p>Therefore, in any situation, we have</p><p><img src="3-5300618x\91e1682d-a7c0-4312-847d-3fe94c074e69.jpg" /></p><p>But<img src="3-5300618x\cda71087-9b71-47a8-bd72-a3f1339ba9bd.jpg" />, hence we obtain</p><p><img src="3-5300618x\b1da09a1-d281-423b-aae4-a136f7baacbd.jpg" /></p><p>Case III. <img src="3-5300618x\047d35a1-7302-4eb2-929f-cb5d8e007f61.jpg" />and<img src="3-5300618x\f10ef4cf-db83-4ea7-aede-f79654201d66.jpg" />. In this case, <img src="3-5300618x\8a1a9a5c-22fe-4833-8cf1-0c2e1165db60.jpg" />by the property of <img src="3-5300618x\344585dd-9a5e-4351-a4b0-4bf2f382f4cd.jpg" /> and<img src="3-5300618x\9e03a40e-764c-4a66-afb5-728b80273bbb.jpg" />, and<img src="3-5300618x\51b09b47-70b3-4214-b375-2cf00959e76a.jpg" />, <img src="3-5300618x\2b7899e6-d5be-41d3-b5ab-44af61869a93.jpg" />, <img src="3-5300618x\f1822253-d1fb-4cb2-8c4e-74d6c06d2c36.jpg" />and<img src="3-5300618x\89c18afc-be8d-4f5c-863b-07d6813bb560.jpg" />. And we have</p><p><img src="3-5300618x\a2a3f3de-e8d8-42b1-b86f-321dddd3df1a.jpg" /></p><p>where</p><p><img src="3-5300618x\00719c5f-553b-480b-b346-98eb70bd2dbd.jpg" /></p><p>Here, we give two basic properties:</p><p>1) since <img src="3-5300618x\a289fd88-eee6-4e9a-a5fb-c5b7bc96676c.jpg" /> so <img src="3-5300618x\8bdfc63b-ee8a-4866-91fc-8fe5714bcd2a.jpg" /> and hence <img src="3-5300618x\baaac9c4-731b-40f7-8d21-378d52dd4291.jpg" /></p><p>2) since</p><p><img src="3-5300618x\9218ed69-75d4-4d10-a4cd-84ca8baafaea.jpg" />hence <img src="3-5300618x\5d257f5d-f78e-4e09-86e2-c304ea61e750.jpg" /></p><p>If <img src="3-5300618x\184cd9f5-f427-4a8e-8916-5d1e196c57b4.jpg" /> then</p><p><img src="3-5300618x\716ae024-acd3-425e-be7b-db4f3b4353a5.jpg" /></p><p>hence by 2),</p><p><img src="3-5300618x\a8da6cef-97f3-42b2-92c6-6f1ea0a69afa.jpg" /></p><p>So by Case II, we obtain</p><p><img src="3-5300618x\496ccd69-47c6-4c1c-8a72-e26fe4ef7ff5.jpg" /></p><p>If<img src="3-5300618x\176dfc3b-0d65-44de-9b56-0a602e14f35a.jpg" />, then</p><p><img src="3-5300618x\2e33c49b-6c00-4bb8-b098-0687c546876d.jpg" /></p><p>hence by 2),</p><p><img src="3-5300618x\8a63a6a8-7061-4137-a3ed-96523d70cd46.jpg" /></p><p>So by Case II again, we obtain</p><p><img src="3-5300618x\c779ff35-71fb-4e80-8f1d-131887426816.jpg" /></p><p>Hence in any situation, we have</p><p><img src="3-5300618x\c1b6ee9a-74c2-411c-a292-22514957f928.jpg" /></p><p>Therefore, from Case I, Case II and Case III, we obtain</p><p><img src="3-5300618x\297e82c3-d445-49e1-96b4-31527606043c.jpg" /></p><p>Let<img src="3-5300618x\91daa218-7b34-416c-b4d6-c9a30971e321.jpg" />, then <img src="3-5300618x\08e9a2cd-36a5-47be-bf52-98e27c12bb6f.jpg" /> since<img src="3-5300618x\6e39ef65-9967-4a1a-a8a1-b86e344b8d2a.jpg" />, hence we have</p><p><img src="3-5300618x\3710688b-a810-4df2-bf78-304b48c30d55.jpg" /></p><p>so</p><p><img src="3-5300618x\7c563a50-b4bd-4214-98f7-1dc416dd01d3.jpg" /></p><p>Let<img src="3-5300618x\ad37ab52-98ae-49ee-86b4-992f3eaa5d4b.jpg" />, then for<img src="3-5300618x\4f31726c-63be-46e1-9dad-bb9ada61cacc.jpg" />,</p><p><img src="3-5300618x\23a8d7d8-6de4-49f9-a20b-f10ac0e1a4b8.jpg" />as<img src="3-5300618x\d025fb07-a139-4b7a-9f3c-71cf0ec36448.jpg" />. Hence <img src="3-5300618x\798e8bba-4f7d-4baa-9244-9a5359b57def.jpg" /> is a Cauchy sequence. Since <img src="3-5300618x\3b2a5ce1-ccca-45f6-8b37-e91b31cc0aee.jpg" /> is complete, <img src="3-5300618x\1d726d93-b06f-4c23-afe0-1ca1db313957.jpg" />has a limit<img src="3-5300618x\9137a371-0810-4020-b9b4-ec61095c4001.jpg" />. But <img src="3-5300618x\46a1afd5-02bf-49ee-991d-8608787d3371.jpg" /> is closed and <img src="3-5300618x\e7ede74f-cc1d-4de6-aa64-174238c2aaae.jpg" /> for all<img src="3-5300618x\62957e07-fd6e-4419-a1b9-c27839d2a30a.jpg" />, hence<img src="3-5300618x\3f5c56b3-6838-4ab2-84cf-dbb32940411f.jpg" />.</p><p>By the property of <img src="3-5300618x\5d9e6aa4-87ae-40e3-8326-c42d32f170e2.jpg" /> and<img src="3-5300618x\fb8f9fe5-3105-4c0b-802e-1f39d344c5d5.jpg" />, we can see that there exists an infinite subsequence <img src="3-5300618x\d6d38ba0-a4c2-4137-b906-8afe8f2df5f0.jpg" /> of <img src="3-5300618x\84bdb637-9532-4b86-bc8b-3c3042f48299.jpg" /> such that<img src="3-5300618x\a62bb818-3e5a-4aa1-a4c6-46803f7dc700.jpg" />, hence <img src="3-5300618x\f43ad31c-f834-40dd-a2e9-19d7688baa06.jpg" /> and <img src="3-5300618x\7b0de37c-46f8-4a32-87b5-cf7e31000467.jpg" /></p><p>Next, we will prove that <img src="3-5300618x\5b8e1475-8570-4289-bc5b-16faa668bf73.jpg" /> is a common fixed point of<img src="3-5300618x\7ec8a928-30e6-4656-8b0f-6f0d01eb4327.jpg" />. Fix any<img src="3-5300618x\44cc850e-a538-4fb7-91c7-2ce389b289f3.jpg" />, for each fixed<img src="3-5300618x\14955fc3-6501-4d85-9331-59e2bdf9f632.jpg" />, there exists <img src="3-5300618x\15a742c6-98d4-4526-9f9b-7697f179e43b.jpg" /> such that <img src="3-5300618x\cbf3d1ba-515e-4754-a9c0-9fe0f66c32bf.jpg" />. Take an enough large <img src="3-5300618x\c441c268-61d2-4f99-9b0e-b644da0fc237.jpg" /> such that <img src="3-5300618x\85c2e34c-5f6c-4a40-800a-27bd87bcdc72.jpg" /> and<img src="3-5300618x\6565a57c-9e19-49f3-95d0-042caf6c7f36.jpg" />. By Lemma 1.2 3) and (1), we have</p><p><img src="3-5300618x\a18edeaf-3db3-41d1-bb2b-4bfe55885638.jpg" /></p><p>and</p><p><img src="3-5300618x\b1422400-6fa3-40b3-867b-49d3259eaa0d.jpg" /></p><p>where</p><p><img src="3-5300618x\d2182c29-59e4-45a5-80f1-224107461769.jpg" /></p><p>If <img src="3-5300618x\751e746c-8ea8-4ecc-859a-78162c2fde60.jpg" /> then</p><p><img src="3-5300618x\47be54d2-da3d-4fb2-9eea-51f20f2764ca.jpg" /></p><p>Let<img src="3-5300618x\1f187ecb-385c-4f1f-a9ee-a4ecee1a8e00.jpg" />, then <img src="3-5300618x\c65e9686-ce8a-41d3-a69c-dc655c7a21cf.jpg" /> since<img src="3-5300618x\e7d97702-9ef9-466a-a04b-3751c5cc4d46.jpg" />, hence</p><p><img src="3-5300618x\dd617d8b-04e5-4367-8ed5-360031f491e7.jpg" />. So <img src="3-5300618x\694160c5-1075-4fba-a0f8-4c71ef799415.jpg" /> since<img src="3-5300618x\1f19f8fb-cdb0-4bfd-87da-8fb0382ef2a0.jpg" />, therefore <img src="3-5300618x\65fb91c2-5fb0-41d4-a48a-71f30f108c3d.jpg" /> by Lemma 1.2 1).</p><p>If<img src="3-5300618x\c9b27dd2-03e7-49e8-aad2-7da4fadf6d44.jpg" />, then</p><p><img src="3-5300618x\f513df5c-ed9f-4c07-8cfd-a157e80fdae4.jpg" /></p><p>Let<img src="3-5300618x\c67f2091-75b2-4cc4-874c-9f54fd90d773.jpg" />, then <img src="3-5300618x\7928c326-74a7-4ab4-9a72-e814b2ab92da.jpg" /> since<img src="3-5300618x\37030026-04cc-4c9b-84e9-acaeef83c4f5.jpg" />, hence similarly, <img src="3-5300618x\f48e243c-6d06-48a1-87f1-72cadbd115e8.jpg" /></p><p>So in any situation, <img src="3-5300618x\d5db8d4e-7b89-4864-9c16-ef6fa782f1c3.jpg" />for all<img src="3-5300618x\68c37398-faa4-4bb8-844f-0fe8c146c5a4.jpg" />, so <img src="3-5300618x\6ecce829-df11-440c-88b7-3d75d7ea2f9a.jpg" /> is a common fixed point of<img src="3-5300618x\62499202-82ee-45a5-a10d-6395dd74bc46.jpg" />.</p><p>If <img src="3-5300618x\3c0796a7-91e5-421e-9642-65fe3f6e1743.jpg" /> and <img src="3-5300618x\05832818-e0d1-45e8-a82d-4e4ecb829802.jpg" /> are all common fixed points of<img src="3-5300618x\b74d51ee-903e-49c0-b4a5-6eeeaf6a05f4.jpg" />, then we will have</p><p><img src="3-5300618x\35129875-38f3-4b7b-86e2-3863b2b24a9b.jpg" /></p><p>where</p><p><img src="3-5300618x\a5cbf139-269d-41b4-95e1-3c9a85b60b79.jpg" /></p><p>If<img src="3-5300618x\f6db5997-ceb1-4b2a-90d5-8c2ac6f9dd45.jpg" />, then<img src="3-5300618x\027e24bc-93cd-4303-99bb-0e84cde645c9.jpg" />, hence<img src="3-5300618x\1fcddd93-c3c4-4f37-be68-ed6a5afdc518.jpg" />;</p><p>If<img src="3-5300618x\4217533a-a27d-4f28-b4ac-2b34d1ffd276.jpg" />, then<img src="3-5300618x\2363bbfa-ca0b-47c3-9955-fe7850e47fc5.jpg" />hence <img src="3-5300618x\b4832385-37b5-42bf-9d7a-df917b31456f.jpg" /> since<img src="3-5300618x\a76303a1-df3a-44a8-9d38-56c263a594ec.jpg" />, so<img src="3-5300618x\f600ef83-bcbd-452d-a311-906da409e398.jpg" />.</p><p>Hence in any situation,<img src="3-5300618x\aeec04d4-074e-4809-8264-8e0adb2b3960.jpg" />. So <img src="3-5300618x\ae5f945a-8466-4b33-ae93-8651af351d83.jpg" /> is the unique common fixed points of <img src="3-5300618x\fa3734ba-698a-4de1-b45d-efc7debf8643.jpg" /></p><p>If the mappings in Theorem 2.1 are all single-valued, then Theorem 2.1 becomes the next form.</p><p>Theorem 2.2. Let <img src="3-5300618x\2b0f51c7-581f-494c-b630-6b10be02ef3c.jpg" /> be a nonempty closed subset of a complete metrically convex space <img src="3-5300618x\26bce076-d411-4b34-b2f6-7cd7118846a6.jpg" /> with<img src="3-5300618x\9cbe6a2e-9efd-472e-9f3f-1a81fd18bf60.jpg" />, <img src="3-5300618x\638acfdd-172e-4712-9a9c-178d01901260.jpg" />a countable family of surjective single-valued mappings such that for any <img src="3-5300618x\1eeb7550-52a4-4995-a9d3-6fb29831b68f.jpg" /> with<img src="3-5300618x\0afe2ac2-7812-4614-a549-6850e2c1e327.jpg" />, any<img src="3-5300618x\5d20bc60-3fc3-44d8-a02e-167b7cbd6fda.jpg" />,</p><disp-formula id="scirp.41731-formula82217"><label>(2)</label><graphic position="anchor" xlink:href="3-5300618x\3db7ce07-54f5-4482-a57c-e1331e2dc05a.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="3-5300618x\0610f8f5-f793-4d6e-bf17-e2e95ba0ff47.jpg" /> and <img src="3-5300618x\81524adc-3ee3-4b55-a50d-6cda961e6288.jpg" /> is a constant number.</p><p>Furthermore, if <img src="3-5300618x\a5ac954b-19ed-4691-a9a8-12bd75bdcbd2.jpg" /> for all<img src="3-5300618x\a66219e3-0a43-4c85-8405-83592754b894.jpg" />, and for each <img src="3-5300618x\390c7c3a-e6df-44dd-90cb-5540ba0d74ce.jpg" /> and<img src="3-5300618x\97d9a43f-6d61-4b8f-a907-295f21d75353.jpg" />, there exists <img src="3-5300618x\38a55bba-d12b-4686-a4b6-3159623e457c.jpg" /> such that<img src="3-5300618x\94be79ff-c573-4308-bfbc-872af34295a0.jpg" />, then <img src="3-5300618x\d367caef-8e48-4e90-9253-418e33eb1c4e.jpg" /> has a unique common fixed point in<img src="3-5300618x\6ef0f292-a99f-4031-979e-9ccfe284ff5e.jpg" />.</p><p>From Theorem 2.2, we can obtain the following more generalized common fixed point theorem.</p><p>Theorem 2.3. Let <img src="3-5300618x\ec23bcf0-c788-47af-9479-303df9a4429b.jpg" /> be a nonempty closed subset of a complete metrically convex space <img src="3-5300618x\2a3c001a-403d-4afa-b2d6-5a9528cffc96.jpg" /> with<img src="3-5300618x\71f99c27-501b-466e-9ef8-87a176cf16bd.jpg" />, <img src="3-5300618x\312867a1-1d46-405e-9448-34bdd3879f64.jpg" />a family of subjective single-valued mappings, <img src="3-5300618x\996135ed-c03a-443c-a397-d6a5dc868e3f.jpg" />a family of positive integral numbers such that for any<img src="3-5300618x\603d5e3b-bc83-4d77-826a-cb8dbd0d68c3.jpg" />, <img src="3-5300618x\6749b4de-6841-441f-8b74-4e36e6448949.jpg" />,</p><disp-formula id="scirp.41731-formula82218"><label>(3)</label><graphic position="anchor" xlink:href="3-5300618x\781f26c4-6453-47c2-a2f2-ac9e3de0c9f9.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="3-5300618x\0aed409b-3cd6-4268-880e-2091babde77e.jpg" /> and <img src="3-5300618x\96919adb-e60a-4c3a-90b7-b79d1573f1cd.jpg" /> is a constant number. Furthermore, if 1) <img src="3-5300618x\33a1d1c3-bffe-42c0-ae32-dc75f6a94c22.jpg" />for all<img src="3-5300618x\c74c7658-bd13-481a-941d-d3301dd36446.jpg" />, 2) for each <img src="3-5300618x\4f4fb67c-ee80-45ed-a3ab-b7ac96568ec2.jpg" /> and<img src="3-5300618x\ed851e11-02c8-4bd2-aa27-7a4d927ff961.jpg" />there exists <img src="3-5300618x\c5f7964d-1c00-4c31-a86d-2031fb325cd6.jpg" /> such that<img src="3-5300618x\2f09afd2-5035-42be-beb3-0c0382ff71ee.jpg" />, 3) for each <img src="3-5300618x\344e5ef3-52b1-4f0e-b5cd-5e279a35cbe7.jpg" /> with<img src="3-5300618x\eade396d-6e49-4cd1-8749-9d91f00a8e7f.jpg" />,<img src="3-5300618x\ab686e95-1d56-444f-a4ec-9354bbd8fb8c.jpg" />. Then <img src="3-5300618x\ee932232-b454-459b-89c9-1c310d6eb003.jpg" /> has a unique common fixed point in<img src="3-5300618x\2f56b29f-0aa0-4cbc-b964-0e2f55bfa524.jpg" />.</p><p>Proof Fix<img src="3-5300618x\1a84338f-d02f-43fb-972d-1015a0b4f9b6.jpg" />, and let<img src="3-5300618x\2a76ecc2-cac9-40e6-9ab5-9aa7d1dd83f3.jpg" />, then <img src="3-5300618x\107a1fa2-96ae-45e1-b461-21b10195cc36.jpg" /> satisfies all of the conditions of Theorem 2.2, hence <img src="3-5300618x\8560cb2b-d5f1-4943-9c4c-c38cdf11282b.jpg" /> has an unique common fixed point <img src="3-5300618x\79ecb0ee-75eb-451e-aa7d-1aacefbb9fb5.jpg" /> in<img src="3-5300618x\d6213174-4e0e-47f9-97b4-63433438ceff.jpg" />. Now, we will prove that <img src="3-5300618x\9307a521-8d0b-426b-bc92-daf0d859d687.jpg" /> is also unique common fixed point of<img src="3-5300618x\a999b1b7-ea6c-4170-8cb0-964d127b47d4.jpg" />. In fact, for any fixed<img src="3-5300618x\bdf28192-6649-4d31-b3c2-0b8129506a9b.jpg" />,</p><p><img src="3-5300618x\851c8cea-30d1-444f-bd69-0ba08ae97ab2.jpg" />. This means that <img src="3-5300618x\99eca6b6-88ac-4101-83f0-fbef092b8ce0.jpg" /> is a fixed point of<img src="3-5300618x\5876db45-6ec7-482d-b323-b2faca66fb33.jpg" />. For any <img src="3-5300618x\8e8da4f5-8d88-46b2-ba83-9cfeb11f6ac8.jpg" /> with<img src="3-5300618x\5db96f62-6093-4ee8-99f1-a92c96738ecd.jpg" />, there exists <img src="3-5300618x\656eda3a-8cbf-49ba-9934-4739b3bb6b92.jpg" /> such that <img src="3-5300618x\7db98041-0b5f-4e27-bc22-ee1a01cb2261.jpg" /> by 2), and by (3) we have that</p><p><img src="3-5300618x\f25d2c75-de95-4234-82b8-da630c8dacf3.jpg" /></p><p>where</p><p><img src="3-5300618x\95d31417-23b7-41ea-b81b-b71972924429.jpg" /></p><p>If<img src="3-5300618x\5b528e21-9efe-4e4d-8770-a27d35aad1ac.jpg" />, then<img src="3-5300618x\e279221f-6682-4eaf-95d8-90cb9c5fa468.jpg" />, hence<img src="3-5300618x\268cdde0-9c43-4db6-942a-60a5c1bb631b.jpg" />;</p><p>If<img src="3-5300618x\83400dd9-d9a8-4938-ac4d-158e4af5c18e.jpg" />, then</p><p><img src="3-5300618x\5be428e5-a076-4712-9aa6-d3e9b4838116.jpg" />, hence <img src="3-5300618x\26c74e12-1b55-4d1d-9365-fbece471cc0d.jpg" /></p><p>Hence in any situation, we have that <img src="3-5300618x\22123ff2-08f2-488f-ba3d-8153afb65f22.jpg" /> is a fixed point of <img src="3-5300618x\b6de78a3-7352-4950-bc77-80804ab4fffb.jpg" /> for each <img src="3-5300618x\eb6e1504-f560-4478-9c77-bcab751f8572.jpg" /> with<img src="3-5300618x\9ecf30cb-f593-44a0-9922-e8b97950caf7.jpg" />. So <img src="3-5300618x\ec98c8f7-52df-4cd7-b73e-417a6c7f8e8b.jpg" /> is a common fixed point of<img src="3-5300618x\60d1e808-4948-418e-bb9e-e89bf01ec20b.jpg" />. By uniqueness of common fixed points of<img src="3-5300618x\45c3ff14-25cd-4dc6-b8ad-559ef57ff04e.jpg" />, we have <img src="3-5300618x\4f7589fe-b154-4105-905c-e84d8549cb95.jpg" /> for each<img src="3-5300618x\076ca9e9-0769-4ae4-b96b-3cea9c6487b0.jpg" />. Hence <img src="3-5300618x\7f71a6c1-ee67-49d7-a1cf-6a1e3491dcc3.jpg" /> is a common fixed point of<img src="3-5300618x\d08f6633-694b-4a97-86c6-d7a05817d227.jpg" />.</p><p>If <img src="3-5300618x\34469113-9a83-47b6-982b-fe187cf8deea.jpg" /> and <img src="3-5300618x\69b82746-345b-4ef2-adc8-d8d8d2385354.jpg" /> are all common fixed points of<img src="3-5300618x\b03572c0-ff5c-4d40-8ed4-d05fc7df3df2.jpg" />, then they are also common fixed points of<img src="3-5300618x\226a1127-4936-4326-bc1b-c59ddf68b010.jpg" />, hence by the uniqueness of common fixed points of<img src="3-5300618x\b70535a4-fca5-4796-9231-59d81e268081.jpg" />, we obtain<img src="3-5300618x\99a3db73-c07a-4569-86e5-30163dee3d64.jpg" />. This means that for each <img src="3-5300618x\16044420-aa22-4212-a764-50d723812e1e.jpg" /> has a unique common fixed point<img src="3-5300618x\90e312cd-1f6a-42d5-b992-e584018aaafe.jpg" />.</p><p>Now, we prove <img src="3-5300618x\6c291bab-c800-4e50-9f47-7822135627c1.jpg" /> for each<img src="3-5300618x\7f13a396-8074-4951-9fd6-20c858e13a3e.jpg" />. In fact, for any <img src="3-5300618x\1d884cb8-ce78-4be9-b70f-8b17faf42199.jpg" /> with<img src="3-5300618x\ffce4c37-48e7-4b45-8736-d759550bb954.jpg" />, since <img src="3-5300618x\0f9199df-52f4-41a2-8df4-6c554eae7fc5.jpg" /> and<img src="3-5300618x\1ce580ef-8d4d-4829-8587-0cc05a70c1b2.jpg" />, so<img src="3-5300618x\ad3a4eca-ba9e-41d7-abc2-ad160f830131.jpg" />, hence</p><p><img src="3-5300618x\1470a2fb-18a8-4bd2-aaa1-8fde4c593420.jpg" />by 3). Therefore, <img src="3-5300618x\9c31d1ae-f885-4f4c-a254-eb215be1a75b.jpg" />is a fixed point of <img src="3-5300618x\4b3780c2-d439-4cab-8ccc-0bb014f75457.jpg" /> for each<img src="3-5300618x\2bfa7926-72a6-4b54-98a2-1ea348fc0f95.jpg" />i.e., <img src="3-5300618x\61da73ac-44b0-4bb8-9eb8-6dcee026ccab.jpg" />is a common fixed point of<img src="3-5300618x\c2a177b1-bb10-4cc4-aaf1-c681521db9cd.jpg" />. But <img src="3-5300618x\770d8f01-9a43-43a9-9c17-21c8162620f5.jpg" /> has a unique common fixe point<img src="3-5300618x\eacc4d48-6ece-4ff5-a4ee-ccc6cd507697.jpg" />, hence <img src="3-5300618x\178338dd-bdf0-490a-9e97-82fe52444b93.jpg" /> for each<img src="3-5300618x\94e29c24-f33b-4243-abfe-e016e9058322.jpg" />, and therefore <img src="3-5300618x\da3037d1-edd0-4c38-a51e-03ad510edf92.jpg" /> is a common fixed point of<img src="3-5300618x\b92532e2-6227-455d-a379-913c41763cf9.jpg" />. But <img src="3-5300618x\0600e9f7-e760-4cbc-92a4-8f7019f1841d.jpg" /></p><p>has a unique common fixed point<img src="3-5300618x\1e1e21c8-6fe8-4085-9a32-cf79fe0fbd55.jpg" />, hence<img src="3-5300618x\e4736571-551c-4d47-b735-30517b79769d.jpg" />. Let<img src="3-5300618x\08b079b9-0eb6-4982-9cf7-f3acbf2ddd4a.jpg" />, then <img src="3-5300618x\b348ca45-79ed-4642-a7ad-cdf7f4928919.jpg" /> is the common fixed point of<img src="3-5300618x\136290c1-b155-4fb6-845d-fbc227f1d4d9.jpg" />. The uniqueness of common fixed points of <img src="3-5300618x\9dfa9ca8-d3cb-4a86-b891-d30a07dc11c1.jpg" /> is obvious.</p></sec><sec id="s3"><title>Funding</title><p>This work was supported by the National Natural Science Foundation of China (No. 11361064).</p></sec><sec id="s4"><title>REFERENCES</title><p>[<xref ref-type="bibr" rid="scirp.41731-ref1">1</xref>]&#160;&#160;&#160;&#160;&#160;&#160; N. A. Assad, “On Fixed Point Theorem of Kannan in Banach Spaces,” Tamkang Journal of Mathematics, Vol. 7, 1976, pp. 91-94.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref2">2</xref>]&#160;&#160;&#160;&#160;&#160;&#160; N. A. Assad, “Fixed point Theorems for Set-Valued Transformations on Compact Sets,” Bolletino della Unione Matematica Italiana, Vol. 7, No. 4, 1973, pp. 1-7.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref3">3</xref>]&#160;&#160;&#160;&#160;&#160;&#160; N. A. Assad and W. A. Kirk, “Fixed Point Theorems for Set-Valued Mappings of Contractive Type,” Pacific Journal of Mathematics, Vol. 43, No. 3, 1972, pp. 553-562. http://dx.doi.org/10.2140/pjm.1972.43.553</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref4">4</xref>]&#160;&#160;&#160;&#160;&#160;&#160; X. Zhang, “Common Fixed Point Theorem of Lipschitz Type Mappings on Convex Cone Metric Spaces,” Acta Mathematica Sinica (Chinese Series), Vol. 53, No. 6, 2010, pp. 1139-1148.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref5">5</xref>]&#160;&#160;&#160;&#160;&#160;&#160; M. Abbas, B. E. Rhoades, et al., “Common Fixed Points of Generalized Contractive Multivalued Mappings in Cone Metric Spaces,” Mathematical Communications, Vol. 14, No. 2, 2009, pp. 365-378.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref6">6</xref>]&#160;&#160;&#160;&#160;&#160;&#160; S. L. Singh and B. Ram, “Common Fixed Points of Commuting Mappings in 2-Metric Spaces,” Mathematical Semester Notes, Vol. 10, 1982, pp. 197-207.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref7">7</xref>]&#160;&#160;&#160;&#160;&#160;&#160; Y. J. Piao and Y. F. Jin, “New Unique Common Fixed Point Results for Four Mappings with <img src="3-5300618x\5a7be7fa-21ed-48c3-9ee5-81281dd7d52a.jpg" />-Contractive Type Theorems in 2-Metric Spaces,” Applied Mathematics, Vol. 3, No. 7, 2012, pp. 734-737. http://dx.doi.org/10.4236/am.2012.37108</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref8">8</xref>]&#160;&#160;&#160;&#160;&#160;&#160; M. S. Khan, H. K. Pathak and M. D. Khan, “Some Fixed Point Theorems in Metrically Convex Spaces,” Georgian Mathematical Journal, Vol. 7, No. 3, 2000, pp. 523-530.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref9">9</xref>]&#160;&#160;&#160; S. K. Chatterjea, “Fixed Point Theorems,” Comptes rendus de l'Acad&#233;mie des Sciences, Vol. 25, 1972, pp. 727-730.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref10">10</xref>]&#160;&#160;&#160; O. Hadzic, “Common Fixed Point Theorem for a Family of Mappings in Convex Metric Spaces,” Univ. U. Novom Sadu, Zb. Rad. Prirod. Mat. Fak. Ser. Mat., Vol. 20, No. 1, 1990, pp. 89-95.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref11">11</xref>]&#160;&#160;&#160; Y. J. Piao, “Unique Common Fixed Point Theorems for a Family of Non-Self Maps in Metrically Convex Spaces,” Applied Mathematics, Vol. 22, No. 4, 2009, pp. 852-857.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref12">12</xref>]&#160;&#160;&#160; Y. J. piao, “Unique Common Fixed Point Theorems for a Family of Quasi-Contractive Type Maps in Metrically Convex Spaces,” Acta Mathematica Scientia, Vol. 30A, No. 2, 2010, pp. 487-493.</p><p>[<xref ref-type="bibr" rid="scirp.41731-ref13">13</xref>]&#160;&#160;&#160; J. R. Wu and H. Y. Liu, “Common Fixed Point Theorems for Sequences of <img src="3-5300618x\350eaaef-b220-4115-8f6e-e9e9a7708d45.jpg" />-Type Contraction Set-Valued Mappings,” Chinese Quarterly Journal of Mathematics, Vol. 24, No. 4, 2009, pp. 504-510.</p></sec><sec id="s5"><title>NOTES</title></sec></body><back><ref-list><title>References</title><ref id="scirp.41731-ref1"><label>1</label><mixed-citation publication-type="other" xlink:type="simple">N. A. Assad, “On Fixed Point Theorem of Kannan in Banach Spaces,” Tamkang Journal of Mathematics, Vol. 7, 1976, pp. 91-94.</mixed-citation></ref><ref id="scirp.41731-ref2"><label>2</label><mixed-citation publication-type="other" xlink:type="simple">N. A. Assad, “Fixed point Theorems for Set-Valued Transformations on Compact Sets,” Bolletino della Unione Matematica Italiana, Vol. 7, No. 4, 1973, pp. 1-7.</mixed-citation></ref><ref id="scirp.41731-ref3"><label>3</label><mixed-citation publication-type="other" xlink:type="simple">N. A. Assad and W. A. Kirk, “Fixed Point Theorems for Set-Valued Mappings of Contractive Type,” Pacific Journal of Mathematics, Vol. 43, No. 3, 1972, pp. 553-562. http://dx.doi.org/10.2140/pjm.1972.43.553</mixed-citation></ref><ref id="scirp.41731-ref4"><label>4</label><mixed-citation publication-type="other" xlink:type="simple">X. Zhang, “Common Fixed Point Theorem of Lipschitz Type Mappings on Convex Cone Metric Spaces,” Acta Mathematica Sinica (Chinese Series), Vol. 53, No. 6, 2010, pp. 1139-1148.</mixed-citation></ref><ref id="scirp.41731-ref5"><label>5</label><mixed-citation publication-type="other" xlink:type="simple">M. Abbas, B. E. Rhoades, et al., “Common Fixed Points of Generalized Contractive Multivalued Mappings in Cone Metric Spaces,” Mathematical Communications, Vol. 14, No. 2, 2009, pp. 365-378.</mixed-citation></ref><ref id="scirp.41731-ref6"><label>6</label><mixed-citation publication-type="other" xlink:type="simple">S. L. Singh and B. Ram, “Common Fixed Points of Commuting Mappings in 2-Metric Spaces,” Mathematical Semester Notes, Vol. 10, 1982, pp. 197-207.</mixed-citation></ref><ref id="scirp.41731-ref7"><label>7</label><mixed-citation publication-type="other" xlink:type="simple">Y. J. Piao and Y. F. Jin, “New Unique Common Fixed Point Results for Four Mappings with  -Contractive Type Theorems in 2-Metric Spaces,” Applied Mathematics, Vol. 3, No. 7, 2012, pp. 734-737.http://dx.doi.org/10.4236/am.2012.37108</mixed-citation></ref><ref id="scirp.41731-ref8"><label>8</label><mixed-citation publication-type="other" xlink:type="simple">M. S. Khan, H. K. Pathak and M. D. Khan, “Some Fixed Point Theorems in Metrically Convex Spaces,” Georgian Mathematical Journal, Vol. 7, No. 3, 2000, pp. 523-530.</mixed-citation></ref><ref id="scirp.41731-ref9"><label>9</label><mixed-citation publication-type="other" xlink:type="simple">S. K. Chatterjea, “Fixed Point Theorems,” Comptes rendus de l'Académie des Sciences, Vol. 25, 1972, pp. 727-730.</mixed-citation></ref><ref id="scirp.41731-ref10"><label>10</label><mixed-citation publication-type="other" xlink:type="simple">O. Hadzic, “Common Fixed Point Theorem for a Family of Mappings in Convex Metric Spaces,” Univ. U. Novom Sadu, Zb. Rad. Prirod. Mat. Fak. Ser. Mat., Vol. 20, No. 1, 1990, pp. 89-95.</mixed-citation></ref><ref id="scirp.41731-ref11"><label>11</label><mixed-citation publication-type="other" xlink:type="simple">Y. J. Piao, “Unique Common Fixed Point Theorems for a Family of Non-Self Maps in Metrically Convex Spaces,” Applied Mathematics, Vol. 22, No. 4, 2009, pp. 852-857.</mixed-citation></ref><ref id="scirp.41731-ref12"><label>12</label><mixed-citation publication-type="other" xlink:type="simple">Y. J. piao, “Unique Common Fixed Point Theorems for a Family of Quasi-Contractive Type Maps in Metrically Convex Spaces,” Acta Mathematica Scientia, Vol. 30A, No. 2, 2010, pp. 487-493.</mixed-citation></ref><ref id="scirp.41731-ref13"><label>13</label><mixed-citation publication-type="other" xlink:type="simple">J. R. Wu and H. Y. Liu, “Common Fixed Point Theorems for Sequences of  -Type Contraction Set-Valued Mappings,” Chinese Quarterly Journal of Mathematics, Vol. 24, No. 4, 2009, pp. 504-510.</mixed-citation></ref></ref-list></back></article>