<?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.2014.42005</article-id><article-id pub-id-type="publisher-id">APM-43121</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>
 
 
  Uniqueness of Meromorphic Functions of Differential Polynomials Sharing Two Values IM
 
</article-title></title-group><contrib-group><contrib contrib-type="author" xlink:type="simple"><name name-style="western"><surname>inhua</surname><given-names>Shi</given-names></name><xref ref-type="aff" rid="aff1"><sub>1</sub></xref><xref ref-type="corresp" rid="cor1"><sup>*</sup></xref></contrib></contrib-group><aff id="aff1"><label>1</label><addr-line>College of Science, Civil Aviation University of China, Tianjin, China</addr-line></aff><author-notes><corresp id="cor1">* E-mail:<email>xhshi2000@163.com</email></corresp></author-notes><pub-date pub-type="epub"><day>24</day><month>02</month><year>2014</year></pub-date><volume>04</volume><issue>02</issue><fpage>35</fpage><lpage>41</lpage><history><date date-type="received"><day>January</day>	<month>15,</month>	<year>2014</year></date><date date-type="rev-recd"><day>February</day>	<month>15,</month>	<year>2014</year>	</date><date date-type="accepted"><day>February</day>	<month>21,</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 shall study the uniqueness problems of meromorphic functions of differential polynomials sharing two values IM. Our results improve or generalize many previous results on value sharing of meromorphic functions. 
 
</p></abstract><kwd-group><kwd>Differential Polynomial; Uniqueness; Meromorphic Function; Shared Value</kwd></kwd-group></article-meta></front><body><sec id="s1"><title>1. Introduction</title><p>Let <img src="1-5300649x\9a440743-0d8e-4141-a4da-25f9178e2f84.jpg" /> and <img src="1-5300649x\b9512a48-aab4-4cbb-8d86-1e58b2eaf880.jpg" /> be two non-constant meromorphic functions defined in the open complex plane<img src="1-5300649x\d76f639d-d9c0-4ad0-988b-5a489a570931.jpg" />. Let<img src="1-5300649x\2d202f3a-6581-49fb-ae05-c669bfc96e12.jpg" />, we say that <img src="1-5300649x\82d99f96-df11-4a07-b141-32dc764cbe87.jpg" /> and <img src="1-5300649x\869fb3af-c126-40e4-9e13-6f807898f2fb.jpg" /> share <img src="1-5300649x\dfec64af-2001-4be9-b9d8-099dca82433a.jpg" /> CM (counting multiplicities) if<img src="1-5300649x\5e7642cf-770e-4761-ad28-c9c2e21d7e2e.jpg" />, <img src="1-5300649x\c59a5f21-82b8-4eef-b8b5-45b5d75109ec.jpg" />have the same zeros with the same multiplicities and we say that <img src="1-5300649x\2c5fb7d3-a052-4327-a197-e8e9e66af8c6.jpg" /> and <img src="1-5300649x\e65de559-c447-4312-808e-681ab493cce2.jpg" /> share <img src="1-5300649x\9371251c-f668-4ee9-852b-fbfc990b4534.jpg" /> (ignoring multiplicities) if we do not consider the multiplicities. We denote by <img src="1-5300649x\3af03db3-ae50-4c5c-bcf2-874af43322d2.jpg" /> the Nevanlinna characteristic function</p><p>of the meromorphic function <img src="1-5300649x\01159b4a-7c39-4ce7-a5dc-f583e3b37e2b.jpg" /> and by <img src="1-5300649x\ff89a33a-04d0-4f18-94ae-609758b8a787.jpg" /> any quantity satisfying <img src="1-5300649x\72454270-30db-407b-a696-d4caba644ad0.jpg" /> as <img src="1-5300649x\34e652af-97f1-452f-96d5-12948d0079f3.jpg" /></p><p>possibly outside a set of finite linear measure. <img src="1-5300649x\1d30008c-e148-4463-937b-2248f5f1ca52.jpg" />denotes the truncated counting function bounded by<img src="1-5300649x\53bbcb20-d56d-4427-b79e-b2fd014b393c.jpg" />. Moreover, <img src="1-5300649x\89396aca-18ac-4a29-ad86-c0cad673047f.jpg" />denotes the greatest common divisor of positive integers<img src="1-5300649x\4e0b40bc-d74e-4b7e-83fe-30df094971db.jpg" />.</p><p>For the sake of simplicity, let <img src="1-5300649x\798ea264-fd59-4a89-bf1e-4dc2eb884324.jpg" /> be a nonnegative integer, <img src="1-5300649x\c78ca711-cdef-4980-ab08-9a8731f81bf6.jpg" />be complex constants. Define</p><p><img src="1-5300649x\a72e3b97-e722-42c4-bfcb-4b6f39f92acf.jpg" /> (1.1)</p><p>In 1929, Nevanlinna [<xref ref-type="bibr" rid="scirp.43121-ref1">1</xref>] proved the following well-know result which is the so called Nevanlinna five values theorem.</p><p>Theorem A Let <img src="1-5300649x\3d89c42f-92cc-42ca-8a69-de3b17938070.jpg" /> and <img src="1-5300649x\76e87124-37a3-459f-8b6a-139396706bba.jpg" /> be two non-constant meromorphic functions. If <img src="1-5300649x\be7edb96-30bb-4293-a9c8-a53529c82c56.jpg" /> and <img src="1-5300649x\8efa0165-7dc1-40a6-a2d1-5e4beac4a947.jpg" /> share five distinct values IM, then<img src="1-5300649x\a66db9b6-45f3-4ee8-81ff-643ffb265f43.jpg" />.</p><p>Moreover, he got.</p><p>Theorem B Let <img src="1-5300649x\96861014-588d-435e-bba5-3a8556932456.jpg" /> and <img src="1-5300649x\dcafa5c9-ebde-45ca-9193-2b8256346d1f.jpg" /> be two distinct non-constant meromorphic functions and <img src="1-5300649x\6a776542-a7c9-4da0-a361-908677e9dcb2.jpg" /> be four distinct values. If <img src="1-5300649x\243e9c7d-8f8b-4f73-86b1-d9a13b9fb3b4.jpg" /> and <img src="1-5300649x\52136099-81d7-4044-beb2-27fa4c11aba6.jpg" /> share <img src="1-5300649x\f8cf55ff-78bb-4a58-985c-3c8679c41916.jpg" /> CM, then <img src="1-5300649x\f40e8e66-7c70-497b-b6ef-603ba3cea25b.jpg" /> is a Mobius transformation of<img src="1-5300649x\9f38603a-d214-4083-8e25-c63ea98d8aaf.jpg" />.</p><p>In 1976, L. Rubel asked the following question:</p><p>Whether CM can be replaced by IM in the hypothesis of Theorem A with the same conclusion or not?</p><p>In 1979, G. G. Gundersen [<xref ref-type="bibr" rid="scirp.43121-ref2">2</xref>] gave a negative answer for this question by the following counterexample:</p><p><img src="1-5300649x\ba24c46a-56e8-40ed-b7cc-05ddeaaa4a25.jpg" />,</p><p>where <img src="1-5300649x\b00a119d-7191-4b1e-af8a-76fab666a31a.jpg" /> is a non-constant entire function. It is easy to verify that <img src="1-5300649x\d973bff7-29ff-4f3e-a6da-24d2823f026b.jpg" /> and <img src="1-5300649x\77ed620e-c171-4fd0-b662-b4cfa1849fd2.jpg" /> share the four values<img src="1-5300649x\77316496-cb88-46b2-8a7a-5cba0caecc20.jpg" />, where none of the four values are shared CM, and <img src="1-5300649x\5d4f20f0-7262-411c-a32a-3d30920d4122.jpg" /> is not a Mobius transformation of<img src="1-5300649x\ae2c3997-4d56-4a20-bab5-9bba21079843.jpg" />.</p><p>On the other hand, G. G. Gundersen [<xref ref-type="bibr" rid="scirp.43121-ref3">3</xref>] proved the following result which is an improvement of Theorem B. Theorem C. If two distinct non-constant meromorphic functions share two values CM and share two other values IM, then the functions share all four values CM (hence the conclusions of Theorem B hold).</p><p>In this paper, we shall show that similar conclusions hold for certain types of differential polynomials when they share two values IM.</p><p>Theorem 1.1 Let <img src="1-5300649x\c5317663-58ec-439f-b01f-aa2ca4bb1cca.jpg" /> and <img src="1-5300649x\1b2f60d3-bd59-48af-9d24-299d43649c3b.jpg" /> be two non-constant meromorphic functions, <img src="1-5300649x\78426cfb-4754-4267-929d-705b98c00c45.jpg" />, and <img src="1-5300649x\2b7b770a-0382-46c2-8d1e-7c4f99b5b0f9.jpg" /> be</p><p>three integers with <img src="1-5300649x\708369f9-c2d4-43b4-af34-b0389cefabb9.jpg" /> and <img src="1-5300649x\38a4c06e-57ab-4090-a576-4da6baa0dbf9.jpg" /> be defined as in (1.1). If <img src="1-5300649x\64d923dd-0668-4fda-8262-54a90d3e2a9e.jpg" /> and <img src="1-5300649x\7e6ea298-4084-48b8-90ab-c17daefdb6a1.jpg" /></p><p>share 1 and <img src="1-5300649x\202a36d2-f9ed-4718-8ced-48221b387235.jpg" /> IM, then</p><p>1) when<img src="1-5300649x\b5c8fc8d-aae4-4971-a489-04faf33187b3.jpg" />,<img src="1-5300649x\722df2f0-e133-4165-9e1a-3b0a18eed696.jpg" />;</p><p>2) when<img src="1-5300649x\30ad0304-0432-4dd4-b085-64b834094b77.jpg" />, one of the following two cases holds:</p><p>3) <img src="1-5300649x\074b966b-6563-4d06-b0d6-fad4bfdaba76.jpg" />for a constant <img src="1-5300649x\b42eb60e-de8b-48d6-95ec-3fd93edc4148.jpg" /> such that<img src="1-5300649x\bf3e3953-4f18-4cbe-93d7-5bc2d4c8574c.jpg" />,</p><p>4)<img src="1-5300649x\1e1d89a2-5512-4bf1-adc8-888b69f4b02c.jpg" />, where <img src="1-5300649x\c2cb8aad-8cd9-4882-869e-109f495ede70.jpg" /> and <img src="1-5300649x\f0e52a5d-0e3c-42e4-a8cf-6ecf8de1d5e8.jpg" /> are three constants satisfying</p><p><img src="1-5300649x\5d040189-874f-49c7-87f3-b3aad6a369c3.jpg" />.</p><p>Remark 1.1 “<img src="1-5300649x\fdd856f7-8112-402d-8115-d827da378b0b.jpg" />and <img src="1-5300649x\6423fefd-538f-48d3-9b9d-3cef404660eb.jpg" /> share <img src="1-5300649x\3ff43f32-64b1-42ec-81bc-aec0c7f4bcb3.jpg" /> IM” <img src="1-5300649x\b977c40c-df14-4832-9d36-bdfaa1941181.jpg" /><img src="1-5300649x\ad5276bd-1de9-42db-9e51-db6edf741ec0.jpg" />and <img src="1-5300649x\41341bc9-a5be-41d9-8ae1-193dcba031e7.jpg" /> share <img src="1-5300649x\726bd235-330c-43a5-92f2-205b8f322e6b.jpg" /> IM”. Moreover,</p><p>from<img src="1-5300649x\8f0bac78-c4ac-46e2-a192-3fa490d3481d.jpg" />, one cannot get <img src="1-5300649x\9719b6a2-8778-4cfd-86e9-9cae6e099843.jpg" /> for some constant<img src="1-5300649x\4175ea34-b2bf-4c0e-9406-74222acf8437.jpg" />. For example, let<img src="1-5300649x\59855630-e2b6-4315-b5d3-5690d8691e03.jpg" />,</p><p><img src="1-5300649x\e7d52f7e-23a9-4fd0-a9a7-09ac7b44fbcc.jpg" />, then <img src="1-5300649x\5316c459-02e5-4e1f-99e5-64d0299843ef.jpg" /> where <img src="1-5300649x\45c5d073-4a76-4413-88de-97e41ab1b6c2.jpg" /> is a non-constant meromorphic function. Obviously, <img src="1-5300649x\1c89c285-f2c4-4fb6-8d38-cf91ad819307.jpg" />for some canstant <img src="1-5300649x\bedc331a-8a20-4c42-8ba3-9c48576a1f3f.jpg" /> but<img src="1-5300649x\f77c788a-8c33-484c-9ce2-b8c7c20d1b26.jpg" />.</p><p>Now we give some corollaries of Theorem 1.1. Corollary 1.2 and Corollary 1.3 improve Theorems D and E, respectively.</p><p>Corollary 1.2 Let <img src="1-5300649x\f115a7d3-514e-4a88-9128-2a7246cf291f.jpg" /> and <img src="1-5300649x\35088ab1-6768-411e-b2a2-639447fbcd32.jpg" /> be two non-constant meromorphic functions, and let <img src="1-5300649x\5417e938-b174-44d6-81f1-539dccb013db.jpg" /> be two positive</p><p>integers with<img src="1-5300649x\9c63d4ce-ac64-4f32-a2b9-025f833db7fa.jpg" />. If <img src="1-5300649x\c82b53ca-9226-4cd0-951f-9b25b5c15c41.jpg" /> and <img src="1-5300649x\2c3754ea-35af-46fe-b81c-3bb37a820f81.jpg" /> share 1 IM, <img src="1-5300649x\100b7b18-c329-4f5a-a4f3-d99b1d4bf414.jpg" />and <img src="1-5300649x\3e4858ee-6c31-40a6-b8cf-339c15ffcf0b.jpg" /> share <img src="1-5300649x\63411eef-96b4-4a16-8038-d8d1aeebe9a0.jpg" /> IM, then either<img src="1-5300649x\2ea8b1e3-3daa-4f46-9fb0-48ba7876959a.jpg" />, where <img src="1-5300649x\5b9041fc-780a-42bf-bab3-7a596904f254.jpg" /> and <img src="1-5300649x\73b734a8-15c2-4eb4-8a64-db2912f9580f.jpg" /> are three constants satisfying<img src="1-5300649x\ac731a9a-6549-44a2-b4c2-3eb383e9abeb.jpg" />, or</p><p><img src="1-5300649x\a12b7ab1-1a65-4cc3-8ef0-131c01c5f5b0.jpg" />for a constant <img src="1-5300649x\e592d80e-0b0e-4dd5-956c-b62f71190bd7.jpg" /> such that<img src="1-5300649x\c8c13c0f-86dd-4252-a96d-1cd7dc58dc75.jpg" />.</p><p>Corollary 1.3 Let <img src="1-5300649x\53ac043a-37b8-416e-a6c7-b5812d431d5f.jpg" /> and <img src="1-5300649x\7d5db8e9-16d2-4c90-954b-0dc6e2306a66.jpg" /> be two non-constant meromorphic functions satisfying<img src="1-5300649x\7f37551a-2a40-4014-b6c9-00948e4141a0.jpg" />, and let <img src="1-5300649x\61938c1a-9183-4807-80a4-f5b68e42481b.jpg" /> be two positive integers with<img src="1-5300649x\47285036-fc90-4a7a-a075-8a364acdc922.jpg" />. If <img src="1-5300649x\57bd0975-2faa-45f5-81e8-7d1e99688f23.jpg" /> and <img src="1-5300649x\56dbe0b9-23be-4e1a-af9b-19891590021e.jpg" /> share 1 IM, <img src="1-5300649x\f5be2e6c-4c94-44a3-8079-caa7375dc730.jpg" /></p><p>and <img src="1-5300649x\9382fde8-336f-4669-b404-b123d1fbce78.jpg" /> share <img src="1-5300649x\8e1ad1d3-a71f-4aea-8874-a91480e8d216.jpg" /> IM, then<img src="1-5300649x\705d2945-e45b-4529-8292-dab1778b578e.jpg" />.</p><p>Corollary 1.4 Let <img src="1-5300649x\4a109166-30bc-4d46-9a07-699ab4747a13.jpg" /> and <img src="1-5300649x\de3e4a3b-ea99-4141-8bfc-fd3cf65be7d7.jpg" /> be two non-constant meromorphic functions, and let <img src="1-5300649x\8467bb20-9e0f-4d09-b459-b48d4d9f67e9.jpg" /> be two positive integers with<img src="1-5300649x\5ee1ccd3-396e-4a47-a737-330f47e4a09a.jpg" />, <img src="1-5300649x\1d1439fc-cfc5-4de2-b515-96770f36d607.jpg" />be a nonzero constant. If <img src="1-5300649x\a431f3b7-b80b-4f61-a5c6-3a73c0e9bb20.jpg" /> and <img src="1-5300649x\3e2080af-507c-4f25-b749-49ea20ba35c5.jpg" /></p><p>share 1 IM, <img src="1-5300649x\35fc3e80-0ca0-4575-8907-76e8f94e6abd.jpg" />and <img src="1-5300649x\4e492a6e-fbba-461f-9067-10a12dac19f2.jpg" /> share <img src="1-5300649x\cb7928fe-5007-4057-9a8e-cfea1975df6b.jpg" /> IM, then <img src="1-5300649x\36daec84-4eb5-478a-bd77-e01e8c93ee3d.jpg" /> for some constant <img src="1-5300649x\b26de198-433b-47ee-b273-a31e2720bd42.jpg" /> such that<img src="1-5300649x\68f35034-2604-455b-9ff8-2d7a9209dc54.jpg" />, where</p><p><img src="1-5300649x\9ab5ac8b-6426-41a6-8ab5-7c96c8adde84.jpg" />.</p><p>Theorem 1.1 generalizes the following result that was obtained by Zhang, Chen and Lin [<xref ref-type="bibr" rid="scirp.43121-ref4">4</xref>].</p><p>Theorem D Let <img src="1-5300649x\67966f2d-ab87-4053-8ed3-9738bcb84898.jpg" /> and <img src="1-5300649x\661d464b-4c4d-4519-81dc-7203e019f58f.jpg" /> be two non-constant entire functions. Let<img src="1-5300649x\e1ddf429-2609-400d-b5a8-5680deff315a.jpg" />, and <img src="1-5300649x\10dd14eb-8673-486a-8de0-5b2dc73d9642.jpg" /> be three positive integ-</p><p>ers with <img src="1-5300649x\08009a01-ac0d-41a1-8884-1a877c5c0985.jpg" /> and let <img src="1-5300649x\0cc65d83-ed92-4890-833f-7fbcdf260708.jpg" /> or<img src="1-5300649x\42dc4253-cc01-4342-bb65-2881fdbaf38c.jpg" />, where <img src="1-5300649x\70c44f8c-b9e1-4009-becc-8e2ae90f7da8.jpg" /> are complex constants. If <img src="1-5300649x\59dba501-1f68-468e-939d-fa84c82602f2.jpg" /> and <img src="1-5300649x\39d159b8-d0ac-45ef-9580-65ef3ee06ebf.jpg" /> share 1 CM, then</p><p>1) when<img src="1-5300649x\2781bdb3-a669-40e3-99df-cbc3c70ee4ff.jpg" />, either <img src="1-5300649x\b8b0e19c-0bb7-4b07-a37a-7ae01873c265.jpg" /> for a constant <img src="1-5300649x\74e918c3-869d-4f84-99df-ee6c7c65a216.jpg" /> such that<img src="1-5300649x\c050d030-28cd-4a8a-81c6-827e4bd35661.jpg" />, where<img src="1-5300649x\a0326457-8031-4253-a0ef-4bb173d7c122.jpg" />, <img src="1-5300649x\1cc0fe5b-048e-46e7-8589-8fc5c7db9f6a.jpg" />for some<img src="1-5300649x\c8e03ecf-3020-4192-bc76-6088c79be14d.jpg" />, or <img src="1-5300649x\29c03ae2-e63f-4834-b056-0ff292db8218.jpg" /> and <img src="1-5300649x\ac6bad06-f8d9-41d8-a5ca-bafd205e6f11.jpg" /> satisfy the algebraic</p><p>equation<img src="1-5300649x\a8abd487-3daf-4f9f-9fb3-3f095ec7fc68.jpg" />,</p><p>where<img src="1-5300649x\c282ab1e-19e3-4cf8-9879-5c739c13eca5.jpg" />;</p><p>2) when<img src="1-5300649x\54aec185-83b5-4a3e-8436-242aa5e5f62c.jpg" />, either<img src="1-5300649x\0e5b84be-964e-41ee-8ed3-0d4123fef40d.jpg" />, where <img src="1-5300649x\c2d25965-f168-40b9-9229-62db76a2281a.jpg" /> and <img src="1-5300649x\feaadff2-8f81-4bd5-bebc-3a4568df1f1b.jpg" /> are three constants satisfying<img src="1-5300649x\2523b0f1-517b-4cea-9820-8b20b541c739.jpg" />, or <img src="1-5300649x\fc65884a-04b6-48ff-9d3e-6e67b590c4a9.jpg" /> for a constant <img src="1-5300649x\13965a6b-3df4-4f33-ac8f-33c6ece18a55.jpg" /> such that<img src="1-5300649x\e9ee0676-871a-470f-b343-a5b892ae7b11.jpg" />.</p><p>Corollaries 1.2-1.4 greatly improve the following result that was obtained by Liu [<xref ref-type="bibr" rid="scirp.43121-ref5">5</xref>] by reducing the lower bound of<img src="1-5300649x\4a38fe9f-189f-46eb-9357-11d561d2e6a5.jpg" />. Moreover, the proofs of Corollaries 1.2 - 1.4 fill some gaps appeared in the proof of Theorem E.</p><p>Theorem E Let <img src="1-5300649x\560de82c-1b81-40dd-a9f0-72118b790926.jpg" /> and <img src="1-5300649x\ae06baab-77ca-4c9f-9dd3-91a2ec07f962.jpg" /> be two non-constant meromorphic functions, and let<img src="1-5300649x\5ac3641d-a575-49ad-9d1f-22aa4e86af8e.jpg" />, and <img src="1-5300649x\530389d2-b6e8-4c2e-8f3c-ef915cab529a.jpg" /> be three</p><p>positive integers with<img src="1-5300649x\93224b1d-3f4c-42c5-9c4e-8ec971dd0038.jpg" />, and<img src="1-5300649x\a9bb21c6-6dd8-4b16-9842-d8a4e20e7641.jpg" />, <img src="1-5300649x\b149107f-7646-4a30-8427-f5b0b88f38d5.jpg" />be two constants such that<img src="1-5300649x\151ef4ad-6df0-439e-99b1-edc73d54ab6a.jpg" />. If</p><p><img src="1-5300649x\f98fb9ac-f929-42ae-809f-cbd3249c9fcf.jpg" />and <img src="1-5300649x\597ed4eb-782b-44c2-8773-72bff8f99486.jpg" /> share 1 IM, <img src="1-5300649x\24ba0a2e-8ce7-497b-945a-e824eb4af234.jpg" />and <img src="1-5300649x\bebc6991-8a88-4ce6-9dff-2592c084deee.jpg" /> share <img src="1-5300649x\d5e25174-cb4e-4ce9-9704-f503d847996e.jpg" /> IM, then\\</p><p>1) when<img src="1-5300649x\1429b727-c819-49eb-bc04-0db072596635.jpg" />, If <img src="1-5300649x\65a0b476-f669-4870-b2bd-f9facba5d8ef.jpg" /> and<img src="1-5300649x\8a994bde-2f9f-41e0-baf3-cdb2ef8a85dd.jpg" />, then<img src="1-5300649x\ce43027b-ac61-4fca-92e8-cec649fea93c.jpg" />.</p><p>If <img src="1-5300649x\01bbdf05-ba83-41f3-9a4b-ced3948b855e.jpg" /> and<img src="1-5300649x\d1a90908-75a7-4555-84eb-a23390c0fb14.jpg" />, then<img src="1-5300649x\5f7c6f7d-e317-42b7-bf39-9e95aad85a10.jpg" />;</p><p>2) when<img src="1-5300649x\80900a2b-6aa8-4b62-968f-2600a2844cd5.jpg" />, if <img src="1-5300649x\26366139-4232-4965-9aed-0dc806623c60.jpg" /> and<img src="1-5300649x\55643c86-0443-4181-8813-3e9709901a95.jpg" />, then either<img src="1-5300649x\aee713c5-1b96-43da-adfc-3bed0e618f8f.jpg" />, where <img src="1-5300649x\9e179ddf-f72e-449c-bf3d-238a39c40eff.jpg" /> is a constant satisfying<img src="1-5300649x\39face28-ed91-412f-a41c-b4c2ed564d7d.jpg" />, or<img src="1-5300649x\ca6e6978-01ce-434c-af2d-1a1fb1eeedbe.jpg" />, where <img src="1-5300649x\3dd3d01b-f393-40e2-b188-0d6d56a2185f.jpg" /> and <img src="1-5300649x\97f7e1fc-80a0-4135-88bf-d362018ffd55.jpg" /> are three constants satisfying</p><p><img src="1-5300649x\e46074ab-fa40-4b8e-9ada-e623c370e183.jpg" />or <img src="1-5300649x\d1d43025-eaf4-4a85-8601-73ba79dca235.jpg" /> Here, <img src="1-5300649x\124fd9c9-48cc-4a16-a43e-e44f8633a36a.jpg" />, where</p><p><img src="1-5300649x\9a8f4e82-448e-4657-85e0-63c4ff07e98b.jpg" />if<img src="1-5300649x\91866803-013b-4274-8328-2ca80eb75652.jpg" />, <img src="1-5300649x\4e0c54cc-00ca-4261-b4bf-10621302225a.jpg" />if<img src="1-5300649x\635394b3-0114-4c19-9098-e3b642e3f292.jpg" />.</p><p>2. Preliminary Lemmas</p><p>Let</p><p><img src="1-5300649x\c6b67a47-e891-4692-bc71-a41c9bd2ec30.jpg" /> (2.1)</p><p><img src="1-5300649x\13a2b664-b843-4b29-905d-954d6b697ab8.jpg" /> (2.2)</p><p>where <img src="1-5300649x\68ab0444-07de-449d-a69d-b5d79c94c73c.jpg" /> and <img src="1-5300649x\4fc8764a-232f-400a-8e89-0788fb6ba84c.jpg" /> are meromorphic functions.</p><p>Lemma 2.1 [<xref ref-type="bibr" rid="scirp.43121-ref6">6</xref>] Let <img src="1-5300649x\b6a6652c-7fca-4814-8138-72c7217839c5.jpg" /> be a non-constant meromorphic function and let <img src="1-5300649x\0d23e3f1-7bb4-4dc4-ae7d-ae1622d915f1.jpg" /> be</p><p>small functions with respect to<img src="1-5300649x\f546a698-b950-48e4-9839-6d14ffdfd1af.jpg" />. Then</p><p><img src="1-5300649x\e81bc595-3913-464d-8f33-f24a73d3e0b6.jpg" /></p><p>Lemma 2.2 [<xref ref-type="bibr" rid="scirp.43121-ref7">7</xref>] Let <img src="1-5300649x\365e305b-90a9-445a-9620-d18b3f6b1c6b.jpg" /> be a non-constant meromorphic function, <img src="1-5300649x\07cd84b4-6e54-48bf-8703-98a3bec973f1.jpg" />be two positive integers. Then</p><p><img src="1-5300649x\a21d1177-3556-41ad-a7f0-d2fcffce2465.jpg" /></p><p><img src="1-5300649x\4dd32ced-f1d8-49ad-86ce-d94e7e16cc4a.jpg" /></p><p>Lemma 2.3 [8-10] Let <img src="1-5300649x\1f73de7e-14f4-4edb-962a-38f4434e25d0.jpg" /> be a non-constant meromorphic function, and let <img src="1-5300649x\c4e3fa78-310b-43d8-9c56-cc2e22ea18e2.jpg" /> be a positive integer. Suppose that<img src="1-5300649x\2cf85e46-b8b7-41b6-98f7-9cae66527b2e.jpg" />, then</p><p><img src="1-5300649x\a578e485-a477-4cc3-93e2-4165d13b9730.jpg" /></p><p>By using the similar method to Banerjee [11, Lemma 2.14], we can prove the following Lemma.</p><p>Lemma 2.4 Let<img src="1-5300649x\42b3f0b9-1bc0-4a5c-9e0f-23567b586fd1.jpg" />, <img src="1-5300649x\e677c70b-fd84-4af6-b9b2-dce242a3d166.jpg" />and <img src="1-5300649x\aefc5462-369b-4265-b9d4-48efa4e7e1a1.jpg" /> be defined as in (2.1). If <img src="1-5300649x\77d7ad18-5a32-4c64-a19c-8a43f32aebd6.jpg" /> and <img src="1-5300649x\7c710474-ffac-4e08-af4b-4b9834d22285.jpg" /> share 1 CM and <img src="1-5300649x\dcd51010-6d8b-4151-a145-f6806a0d6357.jpg" /> IM, and<img src="1-5300649x\bd66d36e-5fca-46b8-824c-93b86bc7c640.jpg" />, then<img src="1-5300649x\9a9e1516-b445-4362-bb7d-e9c23cbe42e6.jpg" />, and</p><p><img src="1-5300649x\1c0ca462-3724-4823-9f32-e979d889076b.jpg" /></p><p>the same inequality holding for<img src="1-5300649x\be724ab9-cb38-4b1a-82b7-757e937badab.jpg" />.</p><p>Lemma 2.5 [<xref ref-type="bibr" rid="scirp.43121-ref12">12</xref>] Let<img src="1-5300649x\e9b3a2ce-c9c9-44fd-9ace-e93c5660ce17.jpg" />, <img src="1-5300649x\8215f584-0028-4f6f-afd5-c425657c862f.jpg" />and <img src="1-5300649x\5647587b-17ce-4e2a-96c9-bcecb424b8be.jpg" /> be defined as in (2.2). If <img src="1-5300649x\fccc447e-449e-4d31-8350-22595fcf0ae2.jpg" /> and <img src="1-5300649x\9230a3d5-eeca-4ab4-a194-365defceddda.jpg" /> share <img src="1-5300649x\fe8c0a27-afc2-446e-9ce6-caa701057ac5.jpg" /> IM, and<img src="1-5300649x\50466d90-026d-44d3-9ac9-d00a51d0d62a.jpg" />, then<img src="1-5300649x\f75ee397-5500-4046-9654-4cf6688745c4.jpg" />.</p><p>Lemma 2.6 [<xref ref-type="bibr" rid="scirp.43121-ref13">13</xref>] If <img src="1-5300649x\cfdba24d-79e9-4c37-a075-6f92d8d13e3a.jpg" /> and <img src="1-5300649x\4c375447-be73-4faa-abf1-bed3487bbab6.jpg" /> share 1 IM, then</p><p><img src="1-5300649x\c4d02b0f-c133-490f-87f2-f23a54d94e00.jpg" />.</p><p>Lemma 2.7 Let<img src="1-5300649x\c593a62a-4148-4504-a483-e2879e266937.jpg" />, <img src="1-5300649x\097f8f90-a3b8-48f5-b9f1-e80dbf265fb7.jpg" />be two non-constant meromorphic functions, <img src="1-5300649x\2b9719c7-96aa-4398-b084-0693e5da6c31.jpg" />be defined as in (2.2), where</p><p><img src="1-5300649x\85babb82-6118-4fb0-a0b2-c1878ac1d5da.jpg" />, <img src="1-5300649x\e8afd92b-4520-4f87-a805-9b36af14b6a6.jpg" />, <img src="1-5300649x\ee6ffa48-32a3-4ec2-bd4d-9e93e120a23f.jpg" />is defined as in (1.1), <img src="1-5300649x\cb1e2220-8e91-491c-b089-857edc07b808.jpg" />, <img src="1-5300649x\d4ede9b9-fc5f-4242-8a1f-1cc3ff430a24.jpg" />and <img src="1-5300649x\87e9780c-1747-4415-9e1b-621295806f33.jpg" /> are three in-</p><p>tegers. If<img src="1-5300649x\461a23c4-07af-4233-911d-dc281e068366.jpg" />, <img src="1-5300649x\e573fa97-f7ad-4342-81f1-6f539e4ddd4a.jpg" />and <img src="1-5300649x\de925771-5ea3-400a-a086-fc34f65c3b6a.jpg" /> share 1 CM and <img src="1-5300649x\95f917a2-d5b4-4157-bc41-d26dd3726c9e.jpg" /> IM, then</p><p><img src="1-5300649x\fd420543-699f-4e86-b776-0c2b1fd3c62f.jpg" /> (2.3)</p><p>Proof Since<img src="1-5300649x\223e0cd5-5e8d-4012-856a-2288d574fd5d.jpg" />, <img src="1-5300649x\220b1eda-c33d-4e22-86a9-88bfa31dec7d.jpg" />and <img src="1-5300649x\d1f986ff-d640-4d84-a8bc-6c3526537085.jpg" /> share <img src="1-5300649x\4b49bf43-45ac-4cc0-83d5-3f4e44ac72f3.jpg" /> IM, suppose that <img src="1-5300649x\85ec3d63-9eba-44fa-b7d9-d880a4e9c5f6.jpg" /> is a pole of <img src="1-5300649x\3669f784-cbc2-4838-b63a-144f3966b282.jpg" /> with multiplicity<img src="1-5300649x\20e916d2-1485-4217-ac3e-34f5db69851b.jpg" />, a pole of <img src="1-5300649x\102c943d-a8eb-4bbd-892a-6041d218d94b.jpg" /> with multiplicity<img src="1-5300649x\94125e54-63dd-4d10-a407-0b2b9130d952.jpg" />, then <img src="1-5300649x\86a7a65e-a4ed-409e-af51-330163afee80.jpg" /> is a pole of <img src="1-5300649x\bfb11769-7b37-4dec-a15f-5b1c1e3fe7d4.jpg" /> with multiplicity<img src="1-5300649x\8e6334ba-aa22-4a7f-a5cc-403ac653b612.jpg" />, a pole of <img src="1-5300649x\ce88bebe-ea2d-424b-b59c-f8c58a687e2b.jpg" /> with</p><p>multiplicity<img src="1-5300649x\3ff69476-ec36-411b-bff8-038fdbcb7428.jpg" />, thus <img src="1-5300649x\b87561f7-0ac1-4df2-9750-6b77df3a919b.jpg" /> is a zero of <img src="1-5300649x\59768dae-7ac4-4740-89a9-f68e4911e913.jpg" /> with multiplicity</p><p><img src="1-5300649x\e1f37f9f-6a1f-4295-b47c-42f79ac77844.jpg" />, and <img src="1-5300649x\53dfdef9-37ae-483d-9fbd-dc91d55d6ee5.jpg" /> is a zero of <img src="1-5300649x\42cd94df-f79f-4e4b-9796-be022c311864.jpg" /></p><p>with multiplicity<img src="1-5300649x\70ae496b-dca3-4a26-bdb2-6559fdcdad7e.jpg" />, hence <img src="1-5300649x\91958040-2eb8-417a-9aa0-7ad5bba966c7.jpg" /> is a zero of <img src="1-5300649x\5d453192-3830-44e6-8000-8f52b43bdaaa.jpg" /> with multiplicity at least</p><p><img src="1-5300649x\a0e5afa6-e0c7-439f-b955-350b0f33628b.jpg" />. So</p><p><img src="1-5300649x\6b6d15fb-d89c-4828-9abc-0070272fbb3f.jpg" /> (2.4)</p><p>By the logarithmic derivative lemma, we have<img src="1-5300649x\3fb73741-8b3a-47fe-8a61-228da3ef104b.jpg" />. Note that <img src="1-5300649x\c73c520e-99e9-4041-a244-f9165e1fd5a2.jpg" /> and <img src="1-5300649x\ecfb036c-ed48-4e9b-a8d8-c93705bd6df7.jpg" /> share 1</p><p>IM, by Lemma 2.6, so we have</p><p><img src="1-5300649x\0fcc5721-f8f2-4c50-bb99-bb03de4398b4.jpg" /> (2.5)</p><p>From (2.4) and (2.5) we get (2.3). This proves Lemma 2.7.</p><p>Lemma 2.8 [<xref ref-type="bibr" rid="scirp.43121-ref14">14</xref>] Let <img src="1-5300649x\a76087ed-c0c3-4db7-bd70-cb122bae2e4f.jpg" /> and <img src="1-5300649x\a36133d5-342f-4fd7-9617-55af1e80bb91.jpg" /> be two non-constant meromorphic functions, and <img src="1-5300649x\3984ef02-3467-4161-8cf0-91899a39477a.jpg" /> be two</p><p>positive integers. If<img src="1-5300649x\3c553de4-047f-421d-bfe0-55b8c14576ce.jpg" />, then <img src="1-5300649x\ca51af7c-7117-4c82-9b2e-89861a27bdaa.jpg" /> for a constant <img src="1-5300649x\6c7218e8-191a-46ae-88ba-decd00da201f.jpg" /> such that<img src="1-5300649x\155d8bf5-5460-43e1-a6d4-c4d3846a6415.jpg" />.</p><p>By the same reason as in Lemma 5 of [<xref ref-type="bibr" rid="scirp.43121-ref8">8</xref>], we obtain the following lemma.</p><p>Lemma 2.9 Let <img src="1-5300649x\8a999871-73ca-46a8-b1cc-4dca61774d65.jpg" /> and <img src="1-5300649x\9ea295c7-f859-4d32-b7c4-fcb1505778f4.jpg" /> be two non-constant meromorphic functions. Let <img src="1-5300649x\ac27b3d1-66b9-438c-b94a-98aba1c4ab21.jpg" /> be defined as in (1.1),</p><p>and<img src="1-5300649x\f868a674-14ec-44cf-bd76-cd328b87a671.jpg" />, and <img src="1-5300649x\84ab21c9-2b16-4f39-9806-df5e8f23b7b5.jpg" /> be three&#160; integers with<img src="1-5300649x\f7358879-3252-4a24-be74-3d2e7ec88ba2.jpg" />. If<img src="1-5300649x\79d989a7-7e2c-48ee-ac43-10c31b684cbb.jpg" />, then<img src="1-5300649x\09d2f644-9ae7-478a-ad87-3ada7d8eedcb.jpg" />.</p><p>Lemma 2.10 [<xref ref-type="bibr" rid="scirp.43121-ref15">15</xref>] Let <img src="1-5300649x\deedb469-88ff-4bf9-a62c-a3e413ced030.jpg" /> and <img src="1-5300649x\d0d788ae-44c9-41c3-941f-6d328d0227ae.jpg" /> be non-constant meromorphic functions, <img src="1-5300649x\a098e808-efa4-4648-9b76-959c02e0d9e2.jpg" />be two positive integers with<img src="1-5300649x\17f8ad8b-040b-4b42-95e6-266cfbd99ef3.jpg" />, and let <img src="1-5300649x\3cea8a2a-62ab-4aa5-b9a8-feced2298397.jpg" /> be defined as in (1.1), <img src="1-5300649x\fc726adc-9cce-47e1-9e3b-4cf62c5a5dce.jpg" />be a small function with respect to <img src="1-5300649x\33f6d5db-d7e2-45ab-bdef-1f0195eb5a61.jpg" /></p><p>with finitely many zeros and poles. If<img src="1-5300649x\469d35da-c7e1-4e10-af33-084e2f26cac3.jpg" />, <img src="1-5300649x\56bc5b55-2c11-4f1d-89ba-25f3b006fc23.jpg" />and <img src="1-5300649x\e084290c-eece-42f6-a529-f61786318a14.jpg" /> share <img src="1-5300649x\28870515-c460-4951-aaf9-f7c185668841.jpg" /> IM, then <img src="1-5300649x\8c92d3fd-828f-482c-822c-cc85dcd01ede.jpg" /></p><p>is reduced to a nonzero monomial.</p><p>Use the proof of Theorem 3 in [<xref ref-type="bibr" rid="scirp.43121-ref15">15</xref>] and we obtain.</p><p>Lemma 2.11 Let <img src="1-5300649x\44ca739d-664c-4f69-bfd0-ab6a199bad2c.jpg" /> and <img src="1-5300649x\09e3faf6-e2ee-4da8-bcff-5584bb5440e5.jpg" /> be non-constant meromorphic functions, <img src="1-5300649x\27fed56f-0ba9-4c8b-ad8c-98bd525bd7a7.jpg" />be two positive integers with</p><p><img src="1-5300649x\90897c8b-d776-4de2-afce-f8f3e5392baf.jpg" />. If<img src="1-5300649x\73e95845-eb11-4a19-89fa-3f12dca7993a.jpg" />, <img src="1-5300649x\8c33ec00-16fb-40f7-8f6a-c0855d532a36.jpg" />and <img src="1-5300649x\ea0bad23-140f-4be2-8714-6058645a4d2b.jpg" /> share <img src="1-5300649x\c29d9080-2f7d-4931-95db-8f45bb5b2b82.jpg" /> IM, then<img src="1-5300649x\ec71e2bc-2b42-46c8-be08-0e79d097d672.jpg" />, where <img src="1-5300649x\f75fd010-fd5f-4316-9caa-c4c79de76d9c.jpg" /> and <img src="1-5300649x\e4ce893b-49f9-4d02-b969-3551d5ef983c.jpg" /> are three constants satisfying<img src="1-5300649x\7edf330f-c2ac-4318-a291-65b114977538.jpg" />.</p><p>Lemma 2.12 [<xref ref-type="bibr" rid="scirp.43121-ref16">16</xref>] Let <img src="1-5300649x\8d7d6cde-dad8-4be5-bd51-a3785adb1f16.jpg" /> and <img src="1-5300649x\2ecea6fa-1b68-48aa-aea8-8d2fa09129d1.jpg" /> are relatively prime integers, and let <img src="1-5300649x\54ad44e3-a367-43c1-a5b7-3cce9baffdbc.jpg" /> be a complex number such that<img src="1-5300649x\1d212932-49a4-41dd-a33c-c0eeff8dd329.jpg" />. Then there exists one and only one common zero of <img src="1-5300649x\f3dddb2f-5706-45be-a3a1-ca675d13e4d2.jpg" /> and<img src="1-5300649x\4402eb5b-7ed6-473c-9e51-219e6f89a337.jpg" />.</p><p>3. Proof of Theorem 1.1</p><p>Let<img src="1-5300649x\24cabb3d-ff61-4d9b-83f9-55d63629e56b.jpg" />, <img src="1-5300649x\16ce42d4-af83-4676-83cb-428d99f9b48b.jpg" />, <img src="1-5300649x\be9b3ec4-46c4-4b47-8dea-07e036c9be51.jpg" />, <img src="1-5300649x\a0ed9ec8-4d35-4c70-b295-d14d5564a618.jpg" />, then <img src="1-5300649x\2cbb455a-b923-4c04-b90f-03db7facb1fb.jpg" /> and <img src="1-5300649x\632c2a48-0367-4c02-abfd-721016643b71.jpg" /> share 1 IM and <img src="1-5300649x\e89da1ae-8391-4e70-a168-5c1a5b68e7a4.jpg" /></p><p>IM. Suppose that<img src="1-5300649x\e18b0903-a55a-43cc-85d0-8a341a3ed4fa.jpg" />, then<img src="1-5300649x\e0d09d8c-106e-4a96-b2a6-7e9c7b141c91.jpg" />, and<img src="1-5300649x\70b02c04-83fd-4942-96ec-4aea30ab22aa.jpg" />.</p><p>Case 1.<img src="1-5300649x\4078092c-f7a7-479e-b72c-ed0817d79fcd.jpg" />. By Lemma 2.4 we have</p><p><img src="1-5300649x\63a1da35-8c1b-4ba2-8844-aedc51277257.jpg" /> (3.1)</p><p>By Lemma 2.2 with<img src="1-5300649x\2809a329-5d11-4657-9d34-91d67675ca51.jpg" />, we obtain</p><p><img src="1-5300649x\d7ef9cdd-4c6f-4a31-8584-cc711222de7f.jpg" /> (3.2)</p><p>and</p><p><img src="1-5300649x\39107664-1e33-4fb2-9e6b-a635ef4a6a28.jpg" /> (3.3)</p><p>Combining (3.1) - (3.3) gives</p><p><img src="1-5300649x\394b09aa-db45-46bb-99d3-90740185980a.jpg" /></p><p>It follows from Lemma 2.1 and the above inequality that</p><p><img src="1-5300649x\96cc2b13-ec78-4faf-95d8-de7c623ed1d3.jpg" /> (3.4)</p><p>Similarly we have</p><p><img src="1-5300649x\79830379-b45d-43ca-bbf5-54884d09a4dd.jpg" /> (3.5)</p><p>Note that .<img src="1-5300649x\3728a339-00b9-4f9d-8d5d-4064850558da.jpg" />. From (3.4) and (3.5) we deduce that</p><p><img src="1-5300649x\1746a40e-74d1-44f3-be7a-0c838c50b0bd.jpg" />. (3.6)</p><p>Note that <img src="1-5300649x\2b478695-c13d-4b3d-921b-b80ef49b4768.jpg" /> and we get (2.3). By Lemma 2.2 with<img src="1-5300649x\8ace2fca-8707-4ae7-9957-83f31599a759.jpg" />, we obtain</p><p><img src="1-5300649x\08544882-1c2b-4ed5-8a38-5c8b0e4b023b.jpg" /> (3.7)</p><p>and</p><p><img src="1-5300649x\8741145b-80dc-474a-80d6-eb7175909a8b.jpg" /> (3.8)</p><p>From (2.3), (3.7) and (3.8) we get</p><p><img src="1-5300649x\e0071d37-b5de-4bc6-bd12-40d086179830.jpg" /> (3.9)</p><p>Combining (3.6) - (3.9) gives</p><p><img src="1-5300649x\0aa7766b-55a2-4a11-8d99-048c4f548461.jpg" />(3.10)</p><p>which is a contradiction since<img src="1-5300649x\eee30bf9-79ae-4cc2-aeb3-8565dc0fb726.jpg" />. Thus<img src="1-5300649x\cd0318b0-1b50-4bbb-ba00-117b1c005067.jpg" />. Similar to the proof of [17, Lemma 3], we obtain</p><p>1)<img src="1-5300649x\7f514b0d-553c-4ec4-ac4a-19c622cd233e.jpg" />, or</p><p>2)<img src="1-5300649x\88469c90-aee9-4c75-9b36-293e777a639b.jpg" />.</p><p>By Lemma 2.10, the case of 1) is impossible. By Lemma 2.9, we get <img src="1-5300649x\b7e2a531-5831-44b3-b604-a51ec8843752.jpg" /> from 2).</p><p>Case 2.<img src="1-5300649x\93560e24-5d11-4ba0-95b9-11ba0d380d29.jpg" />. Similar to the proof of Case 1, we get</p><p><img src="1-5300649x\2ca6d448-3eef-46d7-8414-95ed692f6941.jpg" />, (3.11)</p><p>which is a contradiction since<img src="1-5300649x\a0425151-4a3d-4d2b-b1cb-9f84682140a5.jpg" />. Thus<img src="1-5300649x\a39cd25c-8a45-44ae-91ea-ce0317a0b2b8.jpg" />. and we have</p><p>3)<img src="1-5300649x\4ce32afc-831d-4541-ab2a-82ca253b0323.jpg" />, or</p><p>4)<img src="1-5300649x\2c27abd2-98d0-4368-ba80-f9e45fa9d6dd.jpg" />.</p><p>For 3), by Lemma 2.11, we get<img src="1-5300649x\87918208-4e9b-4355-b2e3-9d7face92461.jpg" />, where <img src="1-5300649x\c953cb15-c388-49ef-9dfc-96cc71d72bbf.jpg" /> and <img src="1-5300649x\082f0e73-a3b4-48c0-9790-dc4ec017f5b8.jpg" /> are three con-</p><p>stants satisfying<img src="1-5300649x\6ea73f13-6f6e-4992-830e-1b0e6c490ea8.jpg" />.</p><p>For 4), By Lemma 2.8, we get <img src="1-5300649x\0e17fd20-7f84-4f35-b033-74e25104c86d.jpg" /> for a constant <img src="1-5300649x\090aae17-6679-4f44-bad8-b533a704d794.jpg" /> such that<img src="1-5300649x\f1ef533a-992d-4ced-9b42-6a08210991f4.jpg" />. This completes the proof of Theorem 1.1.</p><p>4. Proof of Corollaries 1.2 - 1.4</p><p>The proof of Corollary 1.2 is the same to the proof of Case 2 of Theorem 1.1, we only need to let<img src="1-5300649x\ff558124-4ad0-4bea-b3e7-37745337c5d5.jpg" />. Thus we omit the proof here.</p><p>Now we prove Corollary 1.3, Let<img src="1-5300649x\ce8aae0c-af84-4654-ae74-d337ec151715.jpg" />, similar to (3.10), we get</p><p><img src="1-5300649x\e0e59411-45a0-4e21-b67d-8fefa78c06c2.jpg" />, (3.12)</p><p>which is a contradiction since<img src="1-5300649x\0685e526-6ded-44c0-b7bd-32edfbb6b2ea.jpg" />. Thus <img src="1-5300649x\8d01ad4f-6b27-4e9c-be78-eb7be60e06e7.jpg" /> and we have</p><p>1)<img src="1-5300649x\db34f124-514e-4eac-aba7-a5346c8fca3c.jpg" />, or</p><p>2)<img src="1-5300649x\b17cb582-0643-4dea-bd4d-9afcd7bb07f2.jpg" />.</p><p>By Lemma 2.10, the case of (i) is impossible. By Lemma 2.9, we get <img src="1-5300649x\428fca97-cb65-4481-ac46-271cefe640c5.jpg" /> from 2).</p><p>Similar to the proof of Theorem 2 in [<xref ref-type="bibr" rid="scirp.43121-ref14">14</xref>], we get<img src="1-5300649x\119001c5-df44-49fc-abf9-f70732361fbb.jpg" />. This proves Corollary 1.3.</p><p>Next we prove Corollary 1.4.</p><p>According to the proof of Case 1 in Theorem 1.1, we have</p><p>1)<img src="1-5300649x\a8572ea0-4468-4c12-8b90-941f9049a322.jpg" />, or</p><p>2)<img src="1-5300649x\ef4bf33a-9f3d-4e0f-a115-9afce9741727.jpg" />.</p><p>By Lemma 2.10, the case of 1) is impossible. By Lemma 2.9, we get <img src="1-5300649x\76586f2b-6b52-4d67-8582-a306e492087b.jpg" /> from 2).</p><p>Let<img src="1-5300649x\5aa702ca-4779-412d-bd7a-443e7044a462.jpg" />. If <img src="1-5300649x\321012a4-f410-45f1-a222-94d903ee62e9.jpg" /> is not a constant, then substitute <img src="1-5300649x\1974c4bd-3d31-464c-96f1-5201a8140698.jpg" /> into <img src="1-5300649x\3b61f7cb-4209-4274-9b73-2db352b9a573.jpg" /> and we get</p><p><img src="1-5300649x\47cb5124-55c0-44d2-ae71-e81cc1eaf533.jpg" /></p><p>where <img src="1-5300649x\540273f2-1f38-4c43-b0a5-e1c57786d3b5.jpg" /> are distinct roots of the algebraic equation<img src="1-5300649x\7d55662b-7987-4b2a-9871-b905b8e916f1.jpg" />, <img src="1-5300649x\dba57393-2f18-4b6f-b3df-c77f2c12717d.jpg" />are distinct roots of the algebraic equation<img src="1-5300649x\fa05e139-8da3-4a98-b566-8ee8ff6f682d.jpg" />.</p><p>Suppose that<img src="1-5300649x\32a701d9-0241-4d7b-8649-10a3cef9c4f0.jpg" />, then<img src="1-5300649x\13d228d1-01a0-4b23-99ea-d6633d865cd4.jpg" />, <img src="1-5300649x\2de8e0f9-90ce-475a-aaa5-38af732047a5.jpg" />, where<img src="1-5300649x\65429354-16d0-48bd-9d9c-856c8e0c2c53.jpg" />, <img src="1-5300649x\02f01de4-a319-416b-ab21-bcb287472cb8.jpg" />are co-prime integers and<img src="1-5300649x\752b8258-2e02-4d85-8f91-352199774236.jpg" />,</p><p>thus<img src="1-5300649x\49908755-b714-4f68-a7c8-d658e32abc06.jpg" />, which implies<img src="1-5300649x\12474765-b876-43fd-bd44-aa4200d2bd72.jpg" />. By Lemma 2.12, there exists one and only one common zero of <img src="1-5300649x\918c2d43-6795-4fcd-bc1d-2a8b6d197e4c.jpg" /> and<img src="1-5300649x\afa4ec05-2b0a-47dc-8034-4db3dc864068.jpg" />, namely<img src="1-5300649x\3a092853-b5f1-42bd-b03c-2b485e182e3d.jpg" />. Therefore, there exists at least <img src="1-5300649x\d80f2f00-d032-4beb-a45f-a38346d405eb.jpg" /> of <img src="1-5300649x\0c02fb99-1662-43cd-add8-6115cd071f7d.jpg" /> different from<img src="1-5300649x\93f2c98d-047c-494c-a08b-21f53c52e8c2.jpg" />. Suppose that <img src="1-5300649x\7614b86b-20ea-4536-acd0-da9f5f4ba788.jpg" /> are different from<img src="1-5300649x\9bcbdd7e-e25d-4048-ab90-656b8b173d82.jpg" />, then all zeros of <img src="1-5300649x\2ac511a1-fa60-4996-b1dc-9c593164937d.jpg" /> have order of at least m. Applying the second fundamental theorem to <img src="1-5300649x\df49f0f3-ff4f-4831-85e1-9bef8efba00e.jpg" /> gives</p><p><img src="1-5300649x\2a1f6d04-53bb-4911-ad9a-013a07e9e375.jpg" /></p><p>Note that <img src="1-5300649x\39793606-5d2c-4f8a-82fb-ecb82ef7f161.jpg" /> and we get a contradiction. Thus <img src="1-5300649x\e7e70980-ed02-4e65-8ae8-48a208311248.jpg" /> is a constant. From (4.2) we have <img src="1-5300649x\b6516dce-1ef4-44d5-8399-2f4d978f7172.jpg" /> and<img src="1-5300649x\370684d7-5a85-43a1-9d08-172003f80b92.jpg" />, thus <img src="1-5300649x\5792a53a-afeb-44e2-9caa-b45235371ed9.jpg" /> for some constant <img src="1-5300649x\97e77cab-affa-406e-a7d3-13e0c79d1a46.jpg" /> such that<img src="1-5300649x\40f721da-1d4e-4a89-ab08-89cfa2244868.jpg" />, where<img src="1-5300649x\8d56ca5f-7d82-4199-a150-75d2bb31494f.jpg" />. This proves Corollary 1.4.</p><p>5. Open Problem</p><p>For further study, we pose the following. Problem: What form of <img src="1-5300649x\166c8502-f33d-44fa-8993-75b43e3c9f75.jpg" /> implies <img src="1-5300649x\2d954064-72a5-4da9-80e5-f2f96eb4c86a.jpg" /> for some constant<img src="1-5300649x\f4400867-0d22-4753-bb3a-bab930dcd54a.jpg" />?</p><p>Let <img src="1-5300649x\9a440743-0d8e-4141-a4da-25f9178e2f84.jpg" /> and <img src="1-5300649x\b9512a48-aab4-4cbb-8d86-1e58b2eaf880.jpg" /> be two non-constant meromorphic functions defined in the open complex plane<img src="1-5300649x\d76f639d-d9c0-4ad0-988b-5a489a570931.jpg" />. Let<img src="1-5300649x\2d202f3a-6581-49fb-ae05-c669bfc96e12.jpg" />, we say that <img src="1-5300649x\82d99f96-df11-4a07-b141-32dc764cbe87.jpg" /> and <img src="1-5300649x\869fb3af-c126-40e4-9e13-6f807898f2fb.jpg" /> share <img src="1-5300649x\dfec64af-2001-4be9-b9d8-099dca82433a.jpg" /> CM (counting multiplicities) if<img src="1-5300649x\5e7642cf-770e-4761-ad28-c9c2e21d7e2e.jpg" />, <img src="1-5300649x\c59a5f21-82b8-4eef-b8b5-45b5d75109ec.jpg" />have the same zeros with the same multiplicities and we say that <img src="1-5300649x\2c5fb7d3-a052-4327-a197-e8e9e66af8c6.jpg" /> and <img src="1-5300649x\e65de559-c447-4312-808e-681ab493cce2.jpg" /> share <img src="1-5300649x\9371251c-f668-4ee9-852b-fbfc990b4534.jpg" /> (ignoring multiplicities) if we do not consider the multiplicities. We denote by <img src="1-5300649x\3af03db3-ae50-4c5c-bcf2-874af43322d2.jpg" /> the Nevanlinna characteristic function of the meromorphic function <img src="1-5300649x\01159b4a-7c39-4ce7-a5dc-f583e3b37e2b.jpg" /> and by <img src="1-5300649x\ff89a33a-04d0-4f18-94ae-609758b8a787.jpg" /> any quantity satisfying <img src="1-5300649x\72454270-30db-407b-a696-d4caba644ad0.jpg" /> as <img src="1-5300649x\34e652af-97f1-452f-96d5-12948d0079f3.jpg" /></p><p>possibly outside a set of finite linear measure. <img src="1-5300649x\1d30008c-e148-4463-937b-2248f5f1ca52.jpg" />denotes the truncated counting function bounded by<img src="1-5300649x\53bbcb20-d56d-4427-b79e-b2fd014b393c.jpg" />. Moreover, <img src="1-5300649x\89396aca-18ac-4a29-ad86-c0cad673047f.jpg" />denotes the greatest common divisor of positive integers<img src="1-5300649x\4e0b40bc-d74e-4b7e-83fe-30df094971db.jpg" />.</p><p>For the sake of simplicity, let <img src="1-5300649x\798ea264-fd59-4a89-bf1e-4dc2eb884324.jpg" /> be a nonnegative integer, <img src="1-5300649x\c78ca711-cdef-4980-ab08-9a8731f81bf6.jpg" />be complex constants. Define</p><disp-formula id="scirp.43121-formula8092"><label>(1.1)</label><graphic position="anchor" xlink:href="1-5300649x\a72e3b97-e722-42c4-bfcb-4b6f39f92acf.jpg"  xlink:type="simple"/></disp-formula><p>In 1929, Nevanlinna [<xref ref-type="bibr" rid="scirp.43121-ref1">1</xref>] proved the following well-know result which is the so called Nevanlinna five values theorem.</p><p>Theorem A Let <img src="1-5300649x\3d89c42f-92cc-42ca-8a69-de3b17938070.jpg" /> and <img src="1-5300649x\76e87124-37a3-459f-8b6a-139396706bba.jpg" /> be two non-constant meromorphic functions. If <img src="1-5300649x\be7edb96-30bb-4293-a9c8-a53529c82c56.jpg" /> and <img src="1-5300649x\8efa0165-7dc1-40a6-a2d1-5e4beac4a947.jpg" /> share five distinct values IM, then<img src="1-5300649x\a66db9b6-45f3-4ee8-81ff-643ffb265f43.jpg" />.</p><p>Moreover, he got.</p><p>Theorem B Let <img src="1-5300649x\96861014-588d-435e-bba5-3a8556932456.jpg" /> and <img src="1-5300649x\dcafa5c9-ebde-45ca-9193-2b8256346d1f.jpg" /> be two distinct non-constant meromorphic functions and <img src="1-5300649x\6a776542-a7c9-4da0-a361-908677e9dcb2.jpg" /> be four distinct values. If <img src="1-5300649x\243e9c7d-8f8b-4f73-86b1-d9a13b9fb3b4.jpg" /> and <img src="1-5300649x\52136099-81d7-4044-beb2-27fa4c11aba6.jpg" /> share <img src="1-5300649x\f8cf55ff-78bb-4a58-985c-3c8679c41916.jpg" /> CM, then <img src="1-5300649x\f40e8e66-7c70-497b-b6ef-603ba3cea25b.jpg" /> is a Mobius transformation of<img src="1-5300649x\9f38603a-d214-4083-8e25-c63ea98d8aaf.jpg" />.</p><p>In 1976, L. Rubel asked the following question:</p><p>Whether CM can be replaced by IM in the hypothesis of Theorem A with the same conclusion or not?</p><p>In 1979, G. G. Gundersen [<xref ref-type="bibr" rid="scirp.43121-ref2">2</xref>] gave a negative answer for this question by the following counterexample:</p><p><img src="1-5300649x\ba24c46a-56e8-40ed-b7cc-05ddeaaa4a25.jpg" />where <img src="1-5300649x\b00a119d-7191-4b1e-af8a-76fab666a31a.jpg" /> is a non-constant entire function. It is easy to verify that <img src="1-5300649x\d973bff7-29ff-4f3e-a6da-24d2823f026b.jpg" /> and <img src="1-5300649x\77ed620e-c171-4fd0-b662-b4cfa1849fd2.jpg" /> share the four values<img src="1-5300649x\77316496-cb88-46b2-8a7a-5cba0caecc20.jpg" />, where none of the four values are shared CM, and <img src="1-5300649x\5d4f20f0-7262-411c-a32a-3d30920d4122.jpg" /> is not a Mobius transformation of<img src="1-5300649x\ae2c3997-4d56-4a20-bab5-9bba21079843.jpg" />.</p><p>On the other hand, G. G. Gundersen [<xref ref-type="bibr" rid="scirp.43121-ref3">3</xref>] proved the following result which is an improvement of Theorem B. Theorem C. If two distinct non-constant meromorphic functions share two values CM and share two other values IM, then the functions share all four values CM (hence the conclusions of Theorem B hold).</p><p>In this paper, we shall show that similar conclusions hold for certain types of differential polynomials when they share two values IM.</p><p>Theorem 1.1 Let <img src="1-5300649x\c5317663-58ec-439f-b01f-aa2ca4bb1cca.jpg" /> and <img src="1-5300649x\1b2f60d3-bd59-48af-9d24-299d43649c3b.jpg" /> be two non-constant meromorphic functions, <img src="1-5300649x\78426cfb-4754-4267-929d-705b98c00c45.jpg" />, and <img src="1-5300649x\2b7b770a-0382-46c2-8d1e-7c4f99b5b0f9.jpg" /> be three integers with <img src="1-5300649x\708369f9-c2d4-43b4-af34-b0389cefabb9.jpg" /> and <img src="1-5300649x\38a4c06e-57ab-4090-a576-4da6baa0dbf9.jpg" /> be defined as in (1.1). If <img src="1-5300649x\64d923dd-0668-4fda-8262-54a90d3e2a9e.jpg" /> and <img src="1-5300649x\7e6ea298-4084-48b8-90ab-c17daefdb6a1.jpg" /></p><p>share 1 and <img src="1-5300649x\202a36d2-f9ed-4718-8ced-48221b387235.jpg" /> IM, then 1) when<img src="1-5300649x\b5c8fc8d-aae4-4971-a489-04faf33187b3.jpg" />,<img src="1-5300649x\722df2f0-e133-4165-9e1a-3b0a18eed696.jpg" />;</p><p>2) when<img src="1-5300649x\30ad0304-0432-4dd4-b085-64b834094b77.jpg" />, one of the following two cases holds:</p><p>3) <img src="1-5300649x\074b966b-6563-4d06-b0d6-fad4bfdaba76.jpg" />for a constant <img src="1-5300649x\b42eb60e-de8b-48d6-95ec-3fd93edc4148.jpg" /> such that<img src="1-5300649x\bf3e3953-4f18-4cbe-93d7-5bc2d4c8574c.jpg" />4)<img src="1-5300649x\1e1d89a2-5512-4bf1-adc8-888b69f4b02c.jpg" />, where <img src="1-5300649x\c2cb8aad-8cd9-4882-869e-109f495ede70.jpg" /> and <img src="1-5300649x\f0e52a5d-0e3c-42e4-a8cf-6ecf8de1d5e8.jpg" /> are three constants satisfying</p><p><img src="1-5300649x\5d040189-874f-49c7-87f3-b3aad6a369c3.jpg" />.</p><p>Remark 1.1 “<img src="1-5300649x\fdd856f7-8112-402d-8115-d827da378b0b.jpg" />and <img src="1-5300649x\6423fefd-538f-48d3-9b9d-3cef404660eb.jpg" /> share <img src="1-5300649x\3ff43f32-64b1-42ec-81bc-aec0c7f4bcb3.jpg" /> IM” <img src="1-5300649x\b977c40c-df14-4832-9d36-bdfaa1941181.jpg" /><img src="1-5300649x\ad5276bd-1de9-42db-9e51-db6edf741ec0.jpg" />and <img src="1-5300649x\41341bc9-a5be-41d9-8ae1-193dcba031e7.jpg" /> share <img src="1-5300649x\726bd235-330c-43a5-92f2-205b8f322e6b.jpg" /> IM”. Moreoverfrom<img src="1-5300649x\8f0bac78-c4ac-46e2-a192-3fa490d3481d.jpg" />, one cannot get <img src="1-5300649x\9719b6a2-8778-4cfd-86e9-9cae6e099843.jpg" /> for some constant<img src="1-5300649x\4175ea34-b2bf-4c0e-9406-74222acf8437.jpg" />. For example, let<img src="1-5300649x\59855630-e2b6-4315-b5d3-5690d8691e03.jpg" />,</p><p><img src="1-5300649x\e7d52f7e-23a9-4fd0-a9a7-09ac7b44fbcc.jpg" />, then <img src="1-5300649x\5316c459-02e5-4e1f-99e5-64d0299843ef.jpg" /> where <img src="1-5300649x\45c5d073-4a76-4413-88de-97e41ab1b6c2.jpg" /> is a non-constant meromorphic function. Obviously, <img src="1-5300649x\1c89c285-f2c4-4fb6-8d38-cf91ad819307.jpg" />for some canstant <img src="1-5300649x\bedc331a-8a20-4c42-8ba3-9c48576a1f3f.jpg" /> but<img src="1-5300649x\f77c788a-8c33-484c-9ce2-b8c7c20d1b26.jpg" />.</p><p>Now we give some corollaries of Theorem 1.1. Corollary 1.2 and Corollary 1.3 improve Theorems D and E, respectively.</p><p>Corollary 1.2 Let <img src="1-5300649x\f115a7d3-514e-4a88-9128-2a7246cf291f.jpg" /> and <img src="1-5300649x\35088ab1-6768-411e-b2a2-639447fbcd32.jpg" /> be two non-constant meromorphic functions, and let <img src="1-5300649x\5417e938-b174-44d6-81f1-539dccb013db.jpg" /> be two positive integers with<img src="1-5300649x\9c63d4ce-ac64-4f32-a2b9-025f833db7fa.jpg" />. If <img src="1-5300649x\c82b53ca-9226-4cd0-951f-9b25b5c15c41.jpg" /> and <img src="1-5300649x\2c3754ea-35af-46fe-b81c-3bb37a820f81.jpg" /> share 1 IM, <img src="1-5300649x\100b7b18-c329-4f5a-a4f3-d99b1d4bf414.jpg" />and <img src="1-5300649x\3e4858ee-6c31-40a6-b8cf-339c15ffcf0b.jpg" /> share <img src="1-5300649x\63411eef-96b4-4a16-8038-d8d1aeebe9a0.jpg" /> IM, then either<img src="1-5300649x\2ea8b1e3-3daa-4f46-9fb0-48ba7876959a.jpg" />, where <img src="1-5300649x\5b9041fc-780a-42bf-bab3-7a596904f254.jpg" /> and <img src="1-5300649x\73b734a8-15c2-4eb4-8a64-db2912f9580f.jpg" /> are three constants satisfying<img src="1-5300649x\ac731a9a-6549-44a2-b4c2-3eb383e9abeb.jpg" />, or</p><p><img src="1-5300649x\a12b7ab1-1a65-4cc3-8ef0-131c01c5f5b0.jpg" />for a constant <img src="1-5300649x\e592d80e-0b0e-4dd5-956c-b62f71190bd7.jpg" /> such that<img src="1-5300649x\c8c13c0f-86dd-4252-a96d-1cd7dc58dc75.jpg" />.</p><p>Corollary 1.3 Let <img src="1-5300649x\53ac043a-37b8-416e-a6c7-b5812d431d5f.jpg" /> and <img src="1-5300649x\7d5db8e9-16d2-4c90-954b-0dc6e2306a66.jpg" /> be two non-constant meromorphic functions satisfying<img src="1-5300649x\7f37551a-2a40-4014-b6c9-00948e4141a0.jpg" />, and let <img src="1-5300649x\61938c1a-9183-4807-80a4-f5b68e42481b.jpg" /> be two positive integers with<img src="1-5300649x\47285036-fc90-4a7a-a075-8a364acdc922.jpg" />. If <img src="1-5300649x\57bd0975-2faa-45f5-81e8-7d1e99688f23.jpg" /> and <img src="1-5300649x\56dbe0b9-23be-4e1a-af9b-19891590021e.jpg" /> share 1 IM, <img src="1-5300649x\f5be2e6c-4c94-44a3-8079-caa7375dc730.jpg" /></p><p>and <img src="1-5300649x\9382fde8-336f-4669-b404-b123d1fbce78.jpg" /> share <img src="1-5300649x\8e1ad1d3-a71f-4aea-8874-a91480e8d216.jpg" /> IM, then<img src="1-5300649x\705d2945-e45b-4529-8292-dab1778b578e.jpg" />.</p><p>Corollary 1.4 Let <img src="1-5300649x\4a109166-30bc-4d46-9a07-699ab4747a13.jpg" /> and <img src="1-5300649x\de3e4a3b-ea99-4141-8bfc-fd3cf65be7d7.jpg" /> be two non-constant meromorphic functions, and let <img src="1-5300649x\8467bb20-9e0f-4d09-b459-b48d4d9f67e9.jpg" /> be two positive integers with<img src="1-5300649x\5ee1ccd3-396e-4a47-a737-330f47e4a09a.jpg" />, <img src="1-5300649x\1d1439fc-cfc5-4de2-b515-96770f36d607.jpg" />be a nonzero constant. If <img src="1-5300649x\a431f3b7-b80b-4f61-a5c6-3a73c0e9bb20.jpg" /> and <img src="1-5300649x\3e2080af-507c-4f25-b749-49ea20ba35c5.jpg" /></p><p>share 1 IM, <img src="1-5300649x\35fc3e80-0ca0-4575-8907-76e8f94e6abd.jpg" />and <img src="1-5300649x\4e492a6e-fbba-461f-9067-10a12dac19f2.jpg" /> share <img src="1-5300649x\cb7928fe-5007-4057-9a8e-cfea1975df6b.jpg" /> IM, then <img src="1-5300649x\36daec84-4eb5-478a-bd77-e01e8c93ee3d.jpg" /> for some constant <img src="1-5300649x\b26de198-433b-47ee-b273-a31e2720bd42.jpg" /> such that<img src="1-5300649x\68f35034-2604-455b-9ff8-2d7a9209dc54.jpg" />, where</p><p><img src="1-5300649x\9ab5ac8b-6426-41a6-8ab5-7c96c8adde84.jpg" />.</p><p>Theorem 1.1 generalizes the following result that was obtained by Zhang, Chen and Lin [<xref ref-type="bibr" rid="scirp.43121-ref4">4</xref>].</p><p>Theorem D Let <img src="1-5300649x\67966f2d-ab87-4053-8ed3-9738bcb84898.jpg" /> and <img src="1-5300649x\661d464b-4c4d-4519-81dc-7203e019f58f.jpg" /> be two non-constant entire functions. Let<img src="1-5300649x\e1ddf429-2609-400d-b5a8-5680deff315a.jpg" />, and <img src="1-5300649x\10dd14eb-8673-486a-8de0-5b2dc73d9642.jpg" /> be three positive integers with <img src="1-5300649x\08009a01-ac0d-41a1-8884-1a877c5c0985.jpg" /> and let <img src="1-5300649x\0cc65d83-ed92-4890-833f-7fbcdf260708.jpg" /> or<img src="1-5300649x\42dc4253-cc01-4342-bb65-2881fdbaf38c.jpg" />, where <img src="1-5300649x\70c44f8c-b9e1-4009-becc-8e2ae90f7da8.jpg" /> are complex constants. If <img src="1-5300649x\59dba501-1f68-468e-939d-fa84c82602f2.jpg" /> and <img src="1-5300649x\39d159b8-d0ac-45ef-9580-65ef3ee06ebf.jpg" /> share 1 CM, then 1) when<img src="1-5300649x\2781bdb3-a669-40e3-99df-cbc3c70ee4ff.jpg" />, either <img src="1-5300649x\b8b0e19c-0bb7-4b07-a37a-7ae01873c265.jpg" /> for a constant <img src="1-5300649x\74e918c3-869d-4f84-99df-ee6c7c65a216.jpg" /> such that<img src="1-5300649x\c050d030-28cd-4a8a-81c6-827e4bd35661.jpg" />, where<img src="1-5300649x\a0326457-8031-4253-a0ef-4bb173d7c122.jpg" />, <img src="1-5300649x\1cc0fe5b-048e-46e7-8589-8fc5c7db9f6a.jpg" />for some<img src="1-5300649x\c8e03ecf-3020-4192-bc76-6088c79be14d.jpg" />, or <img src="1-5300649x\29c03ae2-e63f-4834-b056-0ff292db8218.jpg" /> and <img src="1-5300649x\ac6bad06-f8d9-41d8-a5ca-bafd205e6f11.jpg" /> satisfy the algebraic equation<img src="1-5300649x\a8abd487-3daf-4f9f-9fb3-3f095ec7fc68.jpg" />where<img src="1-5300649x\c282ab1e-19e3-4cf8-9879-5c739c13eca5.jpg" />;</p><p>2) when<img src="1-5300649x\54aec185-83b5-4a3e-8436-242aa5e5f62c.jpg" />, either<img src="1-5300649x\0e5b84be-964e-41ee-8ed3-0d4123fef40d.jpg" />, where <img src="1-5300649x\c2d25965-f168-40b9-9229-62db76a2281a.jpg" /> and <img src="1-5300649x\feaadff2-8f81-4bd5-bebc-3a4568df1f1b.jpg" /> are three constants satisfying<img src="1-5300649x\2523b0f1-517b-4cea-9820-8b20b541c739.jpg" />, or <img src="1-5300649x\fc65884a-04b6-48ff-9d3e-6e67b590c4a9.jpg" /> for a constant <img src="1-5300649x\13965a6b-3df4-4f33-ac8f-33c6ece18a55.jpg" /> such that<img src="1-5300649x\e9ee0676-871a-470f-b343-a5b892ae7b11.jpg" />.</p><p>Corollaries 1.2-1.4 greatly improve the following result that was obtained by Liu [<xref ref-type="bibr" rid="scirp.43121-ref5">5</xref>] by reducing the lower bound of<img src="1-5300649x\4a38fe9f-189f-46eb-9357-11d561d2e6a5.jpg" />. Moreover, the proofs of Corollaries 1.2 - 1.4 fill some gaps appeared in the proof of Theorem E.</p><p>Theorem E Let <img src="1-5300649x\560de82c-1b81-40dd-a9f0-72118b790926.jpg" /> and <img src="1-5300649x\ae06baab-77ca-4c9f-9dd3-91a2ec07f962.jpg" /> be two non-constant meromorphic functions, and let<img src="1-5300649x\5ac3641d-a575-49ad-9d1f-22aa4e86af8e.jpg" />, and <img src="1-5300649x\530389d2-b6e8-4c2e-8f3c-ef915cab529a.jpg" /> be three positive integers with<img src="1-5300649x\93224b1d-3f4c-42c5-9c4e-8ec971dd0038.jpg" />, and<img src="1-5300649x\a9bb21c6-6dd8-4b16-9842-d8a4e20e7641.jpg" />, <img src="1-5300649x\b149107f-7646-4a30-8427-f5b0b88f38d5.jpg" />be two constants such that<img src="1-5300649x\151ef4ad-6df0-439e-99b1-edc73d54ab6a.jpg" />. If</p><p><img src="1-5300649x\f98fb9ac-f929-42ae-809f-cbd3249c9fcf.jpg" />and <img src="1-5300649x\597ed4eb-782b-44c2-8773-72bff8f99486.jpg" /> share 1 IM, <img src="1-5300649x\24ba0a2e-8ce7-497b-945a-e824eb4af234.jpg" />and <img src="1-5300649x\bebc6991-8a88-4ce6-9dff-2592c084deee.jpg" /> share <img src="1-5300649x\d5e25174-cb4e-4ce9-9704-f503d847996e.jpg" /> IM, then\\</p><p>1) when<img src="1-5300649x\1429b727-c819-49eb-bc04-0db072596635.jpg" />, If <img src="1-5300649x\65a0b476-f669-4870-b2bd-f9facba5d8ef.jpg" /> and<img src="1-5300649x\8a994bde-2f9f-41e0-baf3-cdb2ef8a85dd.jpg" />, then<img src="1-5300649x\ce43027b-ac61-4fca-92e8-cec649fea93c.jpg" />.</p><p>If <img src="1-5300649x\01bbdf05-ba83-41f3-9a4b-ced3948b855e.jpg" /> and<img src="1-5300649x\d1a90908-75a7-4555-84eb-a23390c0fb14.jpg" />, then<img src="1-5300649x\5f7c6f7d-e317-42b7-bf39-9e95aad85a10.jpg" />;</p><p>2) when<img src="1-5300649x\80900a2b-6aa8-4b62-968f-2600a2844cd5.jpg" />, if <img src="1-5300649x\26366139-4232-4965-9aed-0dc806623c60.jpg" /> and<img src="1-5300649x\55643c86-0443-4181-8813-3e9709901a95.jpg" />, then either<img src="1-5300649x\aee713c5-1b96-43da-adfc-3bed0e618f8f.jpg" />, where <img src="1-5300649x\9e179ddf-f72e-449c-bf3d-238a39c40eff.jpg" /> is a constant satisfying<img src="1-5300649x\39face28-ed91-412f-a41c-b4c2ed564d7d.jpg" />, or<img src="1-5300649x\ca6e6978-01ce-434c-af2d-1a1fb1eeedbe.jpg" />, where <img src="1-5300649x\3dd3d01b-f393-40e2-b188-0d6d56a2185f.jpg" /> and <img src="1-5300649x\97f7e1fc-80a0-4135-88bf-d362018ffd55.jpg" /> are three constants satisfying</p><p><img src="1-5300649x\e46074ab-fa40-4b8e-9ada-e623c370e183.jpg" />or <img src="1-5300649x\d1d43025-eaf4-4a85-8601-73ba79dca235.jpg" /> Here, <img src="1-5300649x\124fd9c9-48cc-4a16-a43e-e44f8633a36a.jpg" />, where</p><p><img src="1-5300649x\9a8f4e82-448e-4657-85e0-63c4ff07e98b.jpg" />if<img src="1-5300649x\91866803-013b-4274-8328-2ca80eb75652.jpg" />, <img src="1-5300649x\4e0c54cc-00ca-4261-b4bf-10621302225a.jpg" />if<img src="1-5300649x\635394b3-0114-4c19-9098-e3b642e3f292.jpg" />.</p></sec><sec id="s2"><title>2. Preliminary Lemmas</title><p>Let</p><disp-formula id="scirp.43121-formula8093"><label>(2.1)</label><graphic position="anchor" xlink:href="1-5300649x\c6b67a47-e891-4692-bc71-a41c9bd2ec30.jpg"  xlink:type="simple"/></disp-formula><disp-formula id="scirp.43121-formula8094"><label>(2.2)</label><graphic position="anchor" xlink:href="1-5300649x\13a2b664-b843-4b29-905d-954d6b697ab8.jpg"  xlink:type="simple"/></disp-formula><p>where <img src="1-5300649x\68ab0444-07de-449d-a69d-b5d79c94c73c.jpg" /> and <img src="1-5300649x\4fc8764a-232f-400a-8e89-0788fb6ba84c.jpg" /> are meromorphic functions.</p><p>Lemma 2.1 [<xref ref-type="bibr" rid="scirp.43121-ref6">6</xref>] Let <img src="1-5300649x\b6a6652c-7fca-4814-8138-72c7217839c5.jpg" /> be a non-constant meromorphic function and let <img src="1-5300649x\0d23e3f1-7bb4-4dc4-ae7d-ae1622d915f1.jpg" /> be small functions with respect to<img src="1-5300649x\f546a698-b950-48e4-9839-6d14ffdfd1af.jpg" />. Then</p><p><img src="1-5300649x\e81bc595-3913-464d-8f33-f24a73d3e0b6.jpg" /></p><p>Lemma 2.2 [<xref ref-type="bibr" rid="scirp.43121-ref7">7</xref>] Let <img src="1-5300649x\365e305b-90a9-445a-9620-d18b3f6b1c6b.jpg" /> be a non-constant meromorphic function, <img src="1-5300649x\07cd84b4-6e54-48bf-8703-98a3bec973f1.jpg" />be two positive integers. Then</p><p><img src="1-5300649x\a21d1177-3556-41ad-a7f0-d2fcffce2465.jpg" /></p><p><img src="1-5300649x\4dd32ced-f1d8-49ad-86ce-d94e7e16cc4a.jpg" /></p><p>Lemma 2.3 [8-10] Let <img src="1-5300649x\1f73de7e-14f4-4edb-962a-38f4434e25d0.jpg" /> be a non-constant meromorphic function, and let <img src="1-5300649x\c4e3fa78-310b-43d8-9c56-cc2e22ea18e2.jpg" /> be a positive integer. Suppose that<img src="1-5300649x\2cf85e46-b8b7-41b6-98f7-9cae66527b2e.jpg" />, then</p><p><img src="1-5300649x\a578e485-a477-4cc3-93e2-4165d13b9730.jpg" /></p><p>By using the similar method to Banerjee [11, Lemma 2.14], we can prove the following Lemma.</p><p>Lemma 2.4 Let<img src="1-5300649x\42b3f0b9-1bc0-4a5c-9e0f-23567b586fd1.jpg" />, <img src="1-5300649x\e677c70b-fd84-4af6-b9b2-dce242a3d166.jpg" />and <img src="1-5300649x\aefc5462-369b-4265-b9d4-48efa4e7e1a1.jpg" /> be defined as in (2.1). If <img src="1-5300649x\77d7ad18-5a32-4c64-a19c-8a43f32aebd6.jpg" /> and <img src="1-5300649x\7c710474-ffac-4e08-af4b-4b9834d22285.jpg" /> share 1 CM and <img src="1-5300649x\dcd51010-6d8b-4151-a145-f6806a0d6357.jpg" /> IM, and<img src="1-5300649x\bd66d36e-5fca-46b8-824c-93b86bc7c640.jpg" />, then<img src="1-5300649x\9a9e1516-b445-4362-bb7d-e9c23cbe42e6.jpg" />, and</p><p><img src="1-5300649x\1c0ca462-3724-4823-9f32-e979d889076b.jpg" /></p><p>the same inequality holding for<img src="1-5300649x\be724ab9-cb38-4b1a-82b7-757e937badab.jpg" />.</p><p>Lemma 2.5 [<xref ref-type="bibr" rid="scirp.43121-ref12">12</xref>] Let<img src="1-5300649x\e9b3a2ce-c9c9-44fd-9ace-e93c5660ce17.jpg" />, <img src="1-5300649x\8215f584-0028-4f6f-afd5-c425657c862f.jpg" />and <img src="1-5300649x\5647587b-17ce-4e2a-96c9-bcecb424b8be.jpg" /> be defined as in (2.2). If <img src="1-5300649x\fccc447e-449e-4d31-8350-22595fcf0ae2.jpg" /> and <img src="1-5300649x\9230a3d5-eeca-4ab4-a194-365defceddda.jpg" /> share <img src="1-5300649x\fe8c0a27-afc2-446e-9ce6-caa701057ac5.jpg" /> IM, and<img src="1-5300649x\50466d90-026d-44d3-9ac9-d00a51d0d62a.jpg" />, then<img src="1-5300649x\f75ee397-5500-4046-9654-4cf6688745c4.jpg" />.</p><p>Lemma 2.6 [<xref ref-type="bibr" rid="scirp.43121-ref13">13</xref>] If <img src="1-5300649x\cfdba24d-79e9-4c37-a075-6f92d8d13e3a.jpg" /> and <img src="1-5300649x\4c375447-be73-4faa-abf1-bed3487bbab6.jpg" /> share 1 IM, then</p><p><img src="1-5300649x\c4d02b0f-c133-490f-87f2-f23a54d94e00.jpg" />.</p><p>Lemma 2.7 Let<img src="1-5300649x\c593a62a-4148-4504-a483-e2879e266937.jpg" />, <img src="1-5300649x\097f8f90-a3b8-48f5-b9f1-e80dbf265fb7.jpg" />be two non-constant meromorphic functions, <img src="1-5300649x\2b9719c7-96aa-4398-b084-0693e5da6c31.jpg" />be defined as in (2.2), where</p><p><img src="1-5300649x\85babb82-6118-4fb0-a0b2-c1878ac1d5da.jpg" />, <img src="1-5300649x\e8afd92b-4520-4f87-a805-9b36af14b6a6.jpg" />, <img src="1-5300649x\ee6ffa48-32a3-4ec2-bd4d-9e93e120a23f.jpg" />is defined as in (1.1), <img src="1-5300649x\cb1e2220-8e91-491c-b089-857edc07b808.jpg" />, <img src="1-5300649x\d4ede9b9-fc5f-4242-8a1f-1cc3ff430a24.jpg" />and <img src="1-5300649x\87e9780c-1747-4415-9e1b-621295806f33.jpg" /> are three integers. If<img src="1-5300649x\461a23c4-07af-4233-911d-dc281e068366.jpg" />, <img src="1-5300649x\e573fa97-f7ad-4342-81f1-6f539e4ddd4a.jpg" />and <img src="1-5300649x\de925771-5ea3-400a-a086-fc34f65c3b6a.jpg" /> share 1 CM and <img src="1-5300649x\95f917a2-d5b4-4157-bc41-d26dd3726c9e.jpg" /> IM, then</p><disp-formula id="scirp.43121-formula8095"><label>(2.3)</label><graphic position="anchor" xlink:href="1-5300649x\fd420543-699f-4e86-b776-0c2b1fd3c62f.jpg"  xlink:type="simple"/></disp-formula><p>Proof Since<img src="1-5300649x\223e0cd5-5e8d-4012-856a-2288d574fd5d.jpg" />, <img src="1-5300649x\220b1eda-c33d-4e22-86a9-88bfa31dec7d.jpg" />and <img src="1-5300649x\d1f986ff-d640-4d84-a8bc-6c3526537085.jpg" /> share <img src="1-5300649x\4b49bf43-45ac-4cc0-83d5-3f4e44ac72f3.jpg" /> IM, suppose that <img src="1-5300649x\85ec3d63-9eba-44fa-b7d9-d880a4e9c5f6.jpg" /> is a pole of <img src="1-5300649x\3669f784-cbc2-4838-b63a-144f3966b282.jpg" /> with multiplicity<img src="1-5300649x\20e916d2-1485-4217-ac3e-34f5db69851b.jpg" />, a pole of <img src="1-5300649x\102c943d-a8eb-4bbd-892a-6041d218d94b.jpg" /> with multiplicity<img src="1-5300649x\94125e54-63dd-4d10-a407-0b2b9130d952.jpg" />, then <img src="1-5300649x\86a7a65e-a4ed-409e-af51-330163afee80.jpg" /> is a pole of <img src="1-5300649x\bfb11769-7b37-4dec-a15f-5b1c1e3fe7d4.jpg" /> with multiplicity<img src="1-5300649x\8e6334ba-aa22-4a7f-a5cc-403ac653b612.jpg" />, a pole of <img src="1-5300649x\ce88bebe-ea2d-424b-b59c-f8c58a687e2b.jpg" /> with multiplicity<img src="1-5300649x\3ff69476-ec36-411b-bff8-038fdbcb7428.jpg" />, thus <img src="1-5300649x\b87561f7-0ac1-4df2-9750-6b77df3a919b.jpg" /> is a zero of <img src="1-5300649x\59768dae-7ac4-4740-89a9-f68e4911e913.jpg" /> with multiplicity</p><p><img src="1-5300649x\e1f37f9f-6a1f-4295-b47c-42f79ac77844.jpg" />, and <img src="1-5300649x\53dfdef9-37ae-483d-9fbd-dc91d55d6ee5.jpg" /> is a zero of <img src="1-5300649x\42cd94df-f79f-4e4b-9796-be022c311864.jpg" /></p><p>with multiplicity<img src="1-5300649x\70ae496b-dca3-4a26-bdb2-6559fdcdad7e.jpg" />, hence <img src="1-5300649x\91958040-2eb8-417a-9aa0-7ad5bba966c7.jpg" /> is a zero of <img src="1-5300649x\5d453192-3830-44e6-8000-8f52b43bdaaa.jpg" /> with multiplicity at least</p><p><img src="1-5300649x\a0e5afa6-e0c7-439f-b955-350b0f33628b.jpg" />. So</p><disp-formula id="scirp.43121-formula8096"><label>(2.4)</label><graphic position="anchor" xlink:href="1-5300649x\6b6d15fb-d89c-4828-9abc-0070272fbb3f.jpg"  xlink:type="simple"/></disp-formula><p>By the logarithmic derivative lemma, we have<img src="1-5300649x\3fb73741-8b3a-47fe-8a61-228da3ef104b.jpg" />. Note that <img src="1-5300649x\c73c520e-99e9-4041-a244-f9165e1fd5a2.jpg" /> and <img src="1-5300649x\ecfb036c-ed48-4e9b-a8d8-c93705bd6df7.jpg" /> share 1 IM, by Lemma 2.6, so we have</p><disp-formula id="scirp.43121-formula8097"><label>(2.5)</label><graphic position="anchor" xlink:href="1-5300649x\0fcc5721-f8f2-4c50-bb99-bb03de4398b4.jpg"  xlink:type="simple"/></disp-formula><p>From (2.4) and (2.5) we get (2.3). This proves Lemma 2.7.</p><p>Lemma 2.8 [<xref ref-type="bibr" rid="scirp.43121-ref14">14</xref>] Let <img src="1-5300649x\a76087ed-c0c3-4db7-bd70-cb122bae2e4f.jpg" /> and <img src="1-5300649x\a36133d5-342f-4fd7-9617-55af1e80bb91.jpg" /> be two non-constant meromorphic functions, and <img src="1-5300649x\3984ef02-3467-4161-8cf0-91899a39477a.jpg" /> be two positive integers. If<img src="1-5300649x\3c553de4-047f-421d-bfe0-55b8c14576ce.jpg" />, then <img src="1-5300649x\ca51af7c-7117-4c82-9b2e-89861a27bdaa.jpg" /> for a constant <img src="1-5300649x\6c7218e8-191a-46ae-88ba-decd00da201f.jpg" /> such that<img src="1-5300649x\155d8bf5-5460-43e1-a6d4-c4d3846a6415.jpg" />.</p><p>By the same reason as in Lemma 5 of [<xref ref-type="bibr" rid="scirp.43121-ref8">8</xref>], we obtain the following lemma.</p><p>Lemma 2.9 Let <img src="1-5300649x\8a999871-73ca-46a8-b1cc-4dca61774d65.jpg" /> and <img src="1-5300649x\9ea295c7-f859-4d32-b7c4-fcb1505778f4.jpg" /> be two non-constant meromorphic functions. Let <img src="1-5300649x\ac27b3d1-66b9-438c-b94a-98aba1c4ab21.jpg" /> be defined as in (1.1)and<img src="1-5300649x\f868a674-14ec-44cf-bd76-cd328b87a671.jpg" />, and <img src="1-5300649x\84ab21c9-2b16-4f39-9806-df5e8f23b7b5.jpg" /> be three&#160; integers with<img src="1-5300649x\f7358879-3252-4a24-be74-3d2e7ec88ba2.jpg" />. If<img src="1-5300649x\79d989a7-7e2c-48ee-ac43-10c31b684cbb.jpg" />, then<img src="1-5300649x\09d2f644-9ae7-478a-ad87-3ada7d8eedcb.jpg" />.</p><p>Lemma 2.10 [<xref ref-type="bibr" rid="scirp.43121-ref15">15</xref>] Let <img src="1-5300649x\deedb469-88ff-4bf9-a62c-a3e413ced030.jpg" /> and <img src="1-5300649x\d0d788ae-44c9-41c3-941f-6d328d0227ae.jpg" /> be non-constant meromorphic functions, <img src="1-5300649x\a098e808-efa4-4648-9b76-959c02e0d9e2.jpg" />be two positive integers with<img src="1-5300649x\17f8ad8b-040b-4b42-95e6-266cfbd99ef3.jpg" />, and let <img src="1-5300649x\3cea8a2a-62ab-4aa5-b9a8-feced2298397.jpg" /> be defined as in (1.1), <img src="1-5300649x\fc726adc-9cce-47e1-9e3b-4cf62c5a5dce.jpg" />be a small function with respect to <img src="1-5300649x\33f6d5db-d7e2-45ab-bdef-1f0195eb5a61.jpg" /></p><p>with finitely many zeros and poles. If<img src="1-5300649x\469d35da-c7e1-4e10-af33-084e2f26cac3.jpg" />, <img src="1-5300649x\56bc5b55-2c11-4f1d-89ba-25f3b006fc23.jpg" />and <img src="1-5300649x\e084290c-eece-42f6-a529-f61786318a14.jpg" /> share <img src="1-5300649x\28870515-c460-4951-aaf9-f7c185668841.jpg" /> IM, then <img src="1-5300649x\8c92d3fd-828f-482c-822c-cc85dcd01ede.jpg" /></p><p>is reduced to a nonzero monomial.</p><p>Use the proof of Theorem 3 in [<xref ref-type="bibr" rid="scirp.43121-ref15">15</xref>] and we obtain.</p><p>Lemma 2.11 Let <img src="1-5300649x\44ca739d-664c-4f69-bfd0-ab6a199bad2c.jpg" /> and <img src="1-5300649x\09e3faf6-e2ee-4da8-bcff-5584bb5440e5.jpg" /> be non-constant meromorphic functions, <img src="1-5300649x\27fed56f-0ba9-4c8b-ad8c-98bd525bd7a7.jpg" />be two positive integers with</p><p><img src="1-5300649x\90897c8b-d776-4de2-afce-f8f3e5392baf.jpg" />. If<img src="1-5300649x\73e95845-eb11-4a19-89fa-3f12dca7993a.jpg" />, <img src="1-5300649x\8c33ec00-16fb-40f7-8f6a-c0855d532a36.jpg" />and <img src="1-5300649x\ea0bad23-140f-4be2-8714-6058645a4d2b.jpg" /> share <img src="1-5300649x\c29d9080-2f7d-4931-95db-8f45bb5b2b82.jpg" /> IM, then<img src="1-5300649x\ec71e2bc-2b42-46c8-be08-0e79d097d672.jpg" />, where <img src="1-5300649x\f75fd010-fd5f-4316-9caa-c4c79de76d9c.jpg" /> and <img src="1-5300649x\e4ce893b-49f9-4d02-b969-3551d5ef983c.jpg" /> are three constants satisfying<img src="1-5300649x\7edf330f-c2ac-4318-a291-65b114977538.jpg" />.</p><p>Lemma 2.12 [<xref ref-type="bibr" rid="scirp.43121-ref16">16</xref>] Let <img src="1-5300649x\8d7d6cde-dad8-4be5-bd51-a3785adb1f16.jpg" /> and <img src="1-5300649x\2ecea6fa-1b68-48aa-aea8-8d2fa09129d1.jpg" /> are relatively prime integers, and let <img src="1-5300649x\54ad44e3-a367-43c1-a5b7-3cce9baffdbc.jpg" /> be a complex number such that<img src="1-5300649x\1d212932-49a4-41dd-a33c-c0eeff8dd329.jpg" />. Then there exists one and only one common zero of <img src="1-5300649x\f3dddb2f-5706-45be-a3a1-ca675d13e4d2.jpg" /> and<img src="1-5300649x\4402eb5b-7ed6-473c-9e51-219e6f89a337.jpg" />.</p></sec><sec id="s3"><title>3. Proof of Theorem 1.1</title><p>Let<img src="1-5300649x\24cabb3d-ff61-4d9b-83f9-55d63629e56b.jpg" />, <img src="1-5300649x\16ce42d4-af83-4676-83cb-428d99f9b48b.jpg" />, <img src="1-5300649x\be9b3ec4-46c4-4b47-8dea-07e036c9be51.jpg" />, <img src="1-5300649x\a0ed9ec8-4d35-4c70-b295-d14d5564a618.jpg" />, then <img src="1-5300649x\2cbb455a-b923-4c04-b90f-03db7facb1fb.jpg" /> and <img src="1-5300649x\632c2a48-0367-4c02-abfd-721016643b71.jpg" /> share 1 IM and <img src="1-5300649x\e89da1ae-8391-4e70-a168-5c1a5b68e7a4.jpg" /></p><p>IM. Suppose that<img src="1-5300649x\e18b0903-a55a-43cc-85d0-8a341a3ed4fa.jpg" />, then<img src="1-5300649x\e0d09d8c-106e-4a96-b2a6-7e9c7b141c91.jpg" />, and<img src="1-5300649x\70b02c04-83fd-4942-96ec-4aea30ab22aa.jpg" />.</p><p>Case 1.<img src="1-5300649x\4078092c-f7a7-479e-b72c-ed0817d79fcd.jpg" />. By Lemma 2.4 we have</p><disp-formula id="scirp.43121-formula8098"><label>(3.1)</label><graphic position="anchor" xlink:href="1-5300649x\63a1da35-8c1b-4ba2-8844-aedc51277257.jpg"  xlink:type="simple"/></disp-formula><p>By Lemma 2.2 with<img src="1-5300649x\2809a329-5d11-4657-9d34-91d67675ca51.jpg" />, we obtain</p><disp-formula id="scirp.43121-formula8099"><label>(3.2)</label><graphic position="anchor" xlink:href="1-5300649x\d7ef9cdd-4c6f-4a31-8584-cc711222de7f.jpg"  xlink:type="simple"/></disp-formula><p>and</p><disp-formula id="scirp.43121-formula8100"><label>(3.3)</label><graphic position="anchor" xlink:href="1-5300649x\39107664-1e33-4fb2-9e6b-a635ef4a6a28.jpg"  xlink:type="simple"/></disp-formula><p>Combining (3.1) - (3.3) gives</p><p><img src="1-5300649x\394b09aa-db45-46bb-99d3-90740185980a.jpg" /></p><p>It follows from Lemma 2.1 and the above inequality that</p><disp-formula id="scirp.43121-formula8101"><label>(3.4)</label><graphic position="anchor" xlink:href="1-5300649x\96cc2b13-ec78-4faf-95d8-de7c623ed1d3.jpg"  xlink:type="simple"/></disp-formula><p>Similarly we have</p><disp-formula id="scirp.43121-formula8102"><label>(3.5)</label><graphic position="anchor" xlink:href="1-5300649x\79830379-b45d-43ca-bbf5-54884d09a4dd.jpg"  xlink:type="simple"/></disp-formula><p>Note that .<img src="1-5300649x\3728a339-00b9-4f9d-8d5d-4064850558da.jpg" />. From (3.4) and (3.5) we deduce that</p><disp-formula id="scirp.43121-formula8103"><label>. (3.6)</label><graphic position="anchor" xlink:href="1-5300649x\1746a40e-74d1-44f3-be7a-0c838c50b0bd.jpg"  xlink:type="simple"/></disp-formula><p>Note that <img src="1-5300649x\2b478695-c13d-4b3d-921b-b80ef49b4768.jpg" /> and we get (2.3). By Lemma 2.2 with<img src="1-5300649x\8ace2fca-8707-4ae7-9957-83f31599a759.jpg" />, we obtain</p><disp-formula id="scirp.43121-formula8104"><label>(3.7)</label><graphic position="anchor" xlink:href="1-5300649x\08544882-1c2b-4ed5-8a38-5c8b0e4b023b.jpg"  xlink:type="simple"/></disp-formula><p>and</p><disp-formula id="scirp.43121-formula8105"><label>(3.8)</label><graphic position="anchor" xlink:href="1-5300649x\8741145b-80dc-474a-80d6-eb7175909a8b.jpg"  xlink:type="simple"/></disp-formula><p>From (2.3), (3.7) and (3.8) we get</p><disp-formula id="scirp.43121-formula8106"><label>(3.9)</label><graphic position="anchor" xlink:href="1-5300649x\e0071d37-b5de-4bc6-bd12-40d086179830.jpg"  xlink:type="simple"/></disp-formula><p>Combining (3.6) - (3.9) gives</p><disp-formula id="scirp.43121-formula8107"><label>(3.10)</label><graphic position="anchor" xlink:href="1-5300649x\0aa7766b-55a2-4a11-8d99-048c4f548461.jpg"  xlink:type="simple"/></disp-formula><p>which is a contradiction since<img src="1-5300649x\eee30bf9-79ae-4cc2-aeb3-8565dc0fb726.jpg" />. Thus<img src="1-5300649x\cd0318b0-1b50-4bbb-ba00-117b1c005067.jpg" />. Similar to the proof of [17, Lemma 3], we obtain 1)<img src="1-5300649x\7f514b0d-553c-4ec4-ac4a-19c622cd233e.jpg" />, or 2)<img src="1-5300649x\88469c90-aee9-4c75-9b36-293e777a639b.jpg" />.</p><p>By Lemma 2.10, the case of 1) is impossible. By Lemma 2.9, we get <img src="1-5300649x\b7e2a531-5831-44b3-b604-a51ec8843752.jpg" /> from 2).</p><p>Case 2.<img src="1-5300649x\93560e24-5d11-4ba0-95b9-11ba0d380d29.jpg" />. Similar to the proof of Case 1, we get</p><disp-formula id="scirp.43121-formula8108"><label>, (3.11)</label><graphic position="anchor" xlink:href="1-5300649x\2ca6d448-3eef-46d7-8414-95ed692f6941.jpg"  xlink:type="simple"/></disp-formula><p>which is a contradiction since<img src="1-5300649x\a0425151-4a3d-4d2b-b1cb-9f84682140a5.jpg" />. Thus<img src="1-5300649x\a39cd25c-8a45-44ae-91ea-ce0317a0b2b8.jpg" />. and we have 3)<img src="1-5300649x\4ce32afc-831d-4541-ab2a-82ca253b0323.jpg" />, or 4)<img src="1-5300649x\2c27abd2-98d0-4368-ba80-f9e45fa9d6dd.jpg" />.</p><p>For 3), by Lemma 2.11, we get<img src="1-5300649x\87918208-4e9b-4355-b2e3-9d7face92461.jpg" />, where <img src="1-5300649x\c953cb15-c388-49ef-9dfc-96cc71d72bbf.jpg" /> and <img src="1-5300649x\082f0e73-a3b4-48c0-9790-dc4ec017f5b8.jpg" /> are three constants satisfying<img src="1-5300649x\6ea73f13-6f6e-4992-830e-1b0e6c490ea8.jpg" />.</p><p>For 4), By Lemma 2.8, we get <img src="1-5300649x\0e17fd20-7f84-4f35-b033-74e25104c86d.jpg" /> for a constant <img src="1-5300649x\090aae17-6679-4f44-bad8-b533a704d794.jpg" /> such that<img src="1-5300649x\f1ef533a-992d-4ced-9b42-6a08210991f4.jpg" />. This completes the proof of Theorem 1.1.</p></sec><sec id="s4"><title>4. Proof of Corollaries 1.2 - 1.4</title><p>The proof of Corollary 1.2 is the same to the proof of Case 2 of Theorem 1.1, we only need to let<img src="1-5300649x\ff558124-4ad0-4bea-b3e7-37745337c5d5.jpg" />. Thus we omit the proof here.</p><p>Now we prove Corollary 1.3, Let<img src="1-5300649x\ce8aae0c-af84-4654-ae74-d337ec151715.jpg" />, similar to (3.10), we get</p><disp-formula id="scirp.43121-formula8109"><label>, (3.12)</label><graphic position="anchor" xlink:href="1-5300649x\e0e59411-45a0-4e21-b67d-8fefa78c06c2.jpg"  xlink:type="simple"/></disp-formula><p>which is a contradiction since<img src="1-5300649x\0685e526-6ded-44c0-b7bd-32edfbb6b2ea.jpg" />. Thus <img src="1-5300649x\8d01ad4f-6b27-4e9c-be78-eb7be60e06e7.jpg" /> and we have 1)<img src="1-5300649x\db34f124-514e-4eac-aba7-a5346c8fca3c.jpg" />, or 2)<img src="1-5300649x\b17cb582-0643-4dea-bd4d-9afcd7bb07f2.jpg" />.</p><p>By Lemma 2.10, the case of (i) is impossible. By Lemma 2.9, we get <img src="1-5300649x\428fca97-cb65-4481-ac46-271cefe640c5.jpg" /> from 2).</p><p>Similar to the proof of Theorem 2 in [<xref ref-type="bibr" rid="scirp.43121-ref14">14</xref>], we get<img src="1-5300649x\119001c5-df44-49fc-abf9-f70732361fbb.jpg" />. This proves Corollary 1.3.</p><p>Next we prove Corollary 1.4.</p><p>According to the proof of Case 1 in Theorem 1.1, we have 1)<img src="1-5300649x\a8572ea0-4468-4c12-8b90-941f9049a322.jpg" />, or 2)<img src="1-5300649x\ef4bf33a-9f3d-4e0f-a115-9afce9741727.jpg" />.</p><p>By Lemma 2.10, the case of 1) is impossible. By Lemma 2.9, we get <img src="1-5300649x\76586f2b-6b52-4d67-8582-a306e492087b.jpg" /> from 2).</p><p>Let<img src="1-5300649x\5aa702ca-4779-412d-bd7a-443e7044a462.jpg" />. If <img src="1-5300649x\321012a4-f410-45f1-a222-94d903ee62e9.jpg" /> is not a constant, then substitute <img src="1-5300649x\1974c4bd-3d31-464c-96f1-5201a8140698.jpg" /> into <img src="1-5300649x\3b61f7cb-4209-4274-9b73-2db352b9a573.jpg" /> and we get</p><p><img src="1-5300649x\47cb5124-55c0-44d2-ae71-e81cc1eaf533.jpg" /></p><p>where <img src="1-5300649x\540273f2-1f38-4c43-b0a5-e1c57786d3b5.jpg" /> are distinct roots of the algebraic equation<img src="1-5300649x\7d55662b-7987-4b2a-9871-b905b8e916f1.jpg" />, <img src="1-5300649x\dba57393-2f18-4b6f-b3df-c77f2c12717d.jpg" />are distinct roots of the algebraic equation<img src="1-5300649x\fa05e139-8da3-4a98-b566-8ee8ff6f682d.jpg" />.</p><p>Suppose that<img src="1-5300649x\32a701d9-0241-4d7b-8649-10a3cef9c4f0.jpg" />, then<img src="1-5300649x\13d228d1-01a0-4b23-99ea-d6633d865cd4.jpg" />, <img src="1-5300649x\2de8e0f9-90ce-475a-aaa5-38af732047a5.jpg" />, where<img src="1-5300649x\65429354-16d0-48bd-9d9c-856c8e0c2c53.jpg" />, <img src="1-5300649x\02f01de4-a319-416b-ab21-bcb287472cb8.jpg" />are co-prime integers and<img src="1-5300649x\752b8258-2e02-4d85-8f91-352199774236.jpg" />thus<img src="1-5300649x\49908755-b714-4f68-a7c8-d658e32abc06.jpg" />, which implies<img src="1-5300649x\12474765-b876-43fd-bd44-aa4200d2bd72.jpg" />. By Lemma 2.12, there exists one and only one common zero of <img src="1-5300649x\918c2d43-6795-4fcd-bc1d-2a8b6d197e4c.jpg" /> and<img src="1-5300649x\afa4ec05-2b0a-47dc-8034-4db3dc864068.jpg" />, namely<img src="1-5300649x\3a092853-b5f1-42bd-b03c-2b485e182e3d.jpg" />. Therefore, there exists at least <img src="1-5300649x\d80f2f00-d032-4beb-a45f-a38346d405eb.jpg" /> of <img src="1-5300649x\0c02fb99-1662-43cd-add8-6115cd071f7d.jpg" /> different from<img src="1-5300649x\93f2c98d-047c-494c-a08b-21f53c52e8c2.jpg" />. Suppose that <img src="1-5300649x\7614b86b-20ea-4536-acd0-da9f5f4ba788.jpg" /> are different from<img src="1-5300649x\9bcbdd7e-e25d-4048-ab90-656b8b173d82.jpg" />, then all zeros of <img src="1-5300649x\2ac511a1-fa60-4996-b1dc-9c593164937d.jpg" /> have order of at least m. Applying the second fundamental theorem to <img src="1-5300649x\df49f0f3-ff4f-4831-85e1-9bef8efba00e.jpg" /> gives</p><p><img src="1-5300649x\2a1f6d04-53bb-4911-ad9a-013a07e9e375.jpg" /></p><p>Note that <img src="1-5300649x\39793606-5d2c-4f8a-82fb-ecb82ef7f161.jpg" /> and we get a contradiction. Thus <img src="1-5300649x\e7e70980-ed02-4e65-8ae8-48a208311248.jpg" /> is a constant. From (4.2) we have <img src="1-5300649x\b6516dce-1ef4-44d5-8399-2f4d978f7172.jpg" /> and<img src="1-5300649x\370684d7-5a85-43a1-9d08-172003f80b92.jpg" />, thus <img src="1-5300649x\5792a53a-afeb-44e2-9caa-b45235371ed9.jpg" /> for some constant <img src="1-5300649x\97e77cab-affa-406e-a7d3-13e0c79d1a46.jpg" /> such that<img src="1-5300649x\40f721da-1d4e-4a89-ab08-89cfa2244868.jpg" />, where<img src="1-5300649x\8d56ca5f-7d82-4199-a150-75d2bb31494f.jpg" />. This proves Corollary 1.4.</p></sec><sec id="s5"><title>5. Open Problem</title><p>For further study, we pose the following. Problem: What form of <img src="1-5300649x\166c8502-f33d-44fa-8993-75b43e3c9f75.jpg" /> implies <img src="1-5300649x\2d954064-72a5-4da9-80e5-f2f96eb4c86a.jpg" /> for some constant<img src="1-5300649x\f4400867-0d22-4753-bb3a-bab930dcd54a.jpg" />?</p></sec><sec id="s6"><title>Acknowledgements</title><p>The author would like to thank the referee for his valuable suggestions.</p></sec><sec id="s7"><title>REFERENCES</title><p>[<xref ref-type="bibr" rid="scirp.43121-ref1">1</xref>] R. Nevanliana, “Le Theoreme de Picard-Borel at la Theorie des Fonctions Meromorph,” Gauthier-Villars, Paries, 1929.</p><p>[<xref ref-type="bibr" rid="scirp.43121-ref2">2</xref>] G. G. Gundersen, “Meromorphic Functions That Share Three or Four Values,” Journal of the London Mathematical Society, Vol. 20, No. 2, 1979, pp. 457-466. http://dx.doi.org/10.1112/jlms/s2-20.3.457</p><p>[<xref ref-type="bibr" rid="scirp.43121-ref3">3</xref>] G. G. 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