What is claimed is:1. A method for named-entity recognition and verification, comprising the steps of:(A) segmenting text data from an article into at least one to-be-tested segments according to a text window;(B) parsing the to-be-tested segments to remove ill-formed segments from the to-be-tested segments according to a predefined grammar;(C) using a hypothesis test to assess a confidence measure of each to-be-tested segment, wherein the confidence measure is determined from dividing a probability$P\left(o\begin{array}{c}L,x\\ L,1\end{array},o\begin{array}{c}C,y\\ C,1\end{array},o\begin{array}{c}R,z\\ R,1\end{array}|H_0\right)$of assuming that the to-be-teated tested segment has a named-entity by a probability$P\left(o\begin{array}{c}L,x\\ L,1\end{array},o\begin{array}{c}C,y\\ C,1\end{array},o\begin{array}{c}R,z\\ R,1\end{array}|H_1\right)$of assuming that the to-be-tested segment doesn't have a named-entity, where$O\begin{array}{c}C,y\\ C,1\end{array}$is a candidate,$O\begin{array}{c}L,x\\ L,1\end{array}$is the left context of the candidate, and$O\begin{array}{c}R,z\\ R,1\end{array}$is the right context of the candidate; and(D) determining that the to-be-tested segment has a named-entity if the confidence measure is greater than a predefined threshold, wherein the confidence measure is expressed by a log likelihood ratio,$\mathrm{LLR}\left(O\begin{array}{c}L,x\\ L,1\end{array},O\begin{array}{c}C,y\\ C,1\end{array},O\begin{array}{c}R,z\\ R,1\end{array}\right)=\log \frac{P\left(O\begin{array}{c}L,x\\ L,1\end{array},O\begin{array}{c}C,y\\ C,1\end{array},O\begin{array}{c}R,z\\ R,1\end{array}|H_0\right)}{P\left(O\begin{array}{c}L,x\\ L,1\end{array},O\begin{array}{c}C,y\\ C,1\end{array},O\begin{array}{c}R,z\\ R,1\end{array}|H_1\right)}.$2. The method as claimed in claim 1, wherein the text window has a plurality of random variables.3. The method as claimed in claim 2, wherein the random variables have the candidate and its left and right contexts, and the named-entity of the to-be-tested segment corresponds to the candidate.4. The method as claimed in claim 3, wherein the text window is$O=\left(o\begin{array}{c}L,x\\ L,1\end{array},o\begin{array}{c}C,y\\ C,1\end{array},o\begin{array}{c}R,z\\ R,1\end{array}\right).$5. The method as claimed in claim 4, wherein in step (D), the confidence measure is determined by using Neyman-Pearson Lemma.6. The method as claimed in claim 1, wherein a named-entity model (NE model) is used to determine log$P\left(o_{L,1}^{L,x},o_{\mathrm{C1}}^{C,y},o_{R,1}^{R,z}|H_0\right),$where$P\left(O\begin{array}{c}L,x\\ L,1\end{array},O\begin{array}{c}C,y\\ C,1\end{array},O\begin{array}{c}R,z\\ R,1\end{array}|H_0\right)$approximates to$P_0\left(o_{L,1}^{L,x},o_{\mathrm{C1}}^{C,y},o_{R,1}^{R,z}\right),$and$P_0\left(o_{L,1}^{L,x},o_{\mathrm{C1}}^{C,y},o_{R,1}^{R,z}\right)$approximates to$P_0\left(o_{L,1}^{L,x}\right)P_0\left(o_{\mathrm{C1}}^{C,y}\right)P_0\left(o_{R,1}^{R,z}\right).$7. The method as claimed in claim 6, wherein$P_0\left(o_{L,1}^{L,x}\right)$approximates to$\prod _{i=1}^x{P}_0\left(o_{L,i}|o_{L,i-N+1}^{L,i-1}\right),$and$P_0\left(o_{L,i}|o_{L,i-N+1}^{L,i-1}\right)$equals to$\{\begin{array}{ccc}{P}_0\left(o_{L,i}|o_{L,1}^{L,i-1}\right),& \mathrm{if}N>1\mathrm{and}i>1& \mathrm{and}i-N\le 0\\ P_0\left(o_{L,i}\right),& \mathrm{if}N=1\mathrm{or}i=1& \end{array},$where N is a positive integer.8. The method as claimed in claim 6, wherein$P_0\left(o_{R,1}^{R,z}\right)$approximates to$\prod _{i=1}^2{P}_0(o_{R,i}o_{R,i-N+1}^{R,i-1}),$and$P_0(o_{R,i}o_{R,i-N+1}^{R,i-1})$equals to$\{\begin{array}{cc}{P}_0\left(o_{R,i}o_{R,1}^{R,i-1}\right),& \mathrm{if}N>1\mathrm{and}i>1\mathrm{and}i-N\le 0\\ P_0\left(o_{R,i}\right),& \mathrm{if}N=1\mathrm{or}i=1\end{array},$where N is a positive integer.9. The method as claimed in claim 6, wherein$P_0\left(o_{C,1}^{C,y}\right)$equals to$\sum _T{P}_0\left(T\right),$and$\sum _T{P}_0\left(T\right)$approximates to$\underset{T}{\max }{P}_0\left(T\right)=\underset{T}{\max }\prod _{A\to \alpha \in T}^{}{P}_0\left(\alpha |A\right),$where T is a possible parsing tree, and A→α is a rule in the parsing tree T.10. The method as claimed in claim 9, wherein the NE model$S_{\mathrm{NE}}\left(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}\right)\mathrm{is}\sum _{i=1}^x\log P_0\left(o_{L,i}|o_{L,i-N+1}^{L,i-1}\right)+\sum _{i=1}^z\log P_0\left(o_{R,i}|o_{R,i-N+1}^{R,i-1}\right)+\underset{T}{\max }\sum _{A->\alpha \in T}^{}\log P_0\left(\alpha |A\right).$11. The method as claimed in claim 1, wherein an anti-named-entity model (anti-NE model) is used to determine$P\left(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}|H_1\right),$where$P(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}H_1)\mathrm{is}{P}_1\left(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}\right),P_1\left(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}\right)$approximates to$\prod _{i=1}^x{P}_1(o_{L,i}o_{L,i-N+1}^{L,i-1})\times \prod _{i=1}^y{P}_1(o_{C,i}o_{C,i-N+1}^{C,i-1})\times \prod _{i=1}^z{P}_1(o_{R,i}o_{R,i-N+1}^{R,i-1}),$and N is a positive integer.12. The method as claimed in claim 11, wherein o_R,j equals to o_C,y+j if j=0, −1, −2, . . . , o_C,j equals to o_L,x+j if j=0, −1, −2, . . . , and$P_1\left(o_{L,i}o_{L,i-N+1}^{L,i-1}\right)$equals to$\{\begin{array}{cc}{P}_1\left(o_{L,i}o_{L,1}^{L,i-1}\right),& \mathrm{if}N>1\mathrm{and}i>1\mathrm{and}i-N\le 0\\ P_1\left(o_{L,i}\right),& \mathrm{if}N=1\mathrm{or}i=1\end{array}.$13. The method as claimed in claim 11, wherein the anti-NE model$S_{\mathrm{anti}-\mathrm{NE}}\left(o_{L,1}^{L,x},o_{C,1}^{C,y},o_{R,1}^{R,z}\right)\mathrm{is}\sum _{i=1}^x\log P_1\left(o_{L,i}|o_{L,i-N+1}^{L,i-1}\right)+\sum _{i=1}^y\log P_1\left(o_{C,i}|o_{C,i-N+1}^{C,i-1}\right)+\sum _{i=1}^z\log P_1\left(o_{R,i}|o_{R,i-N+1}^{R,i-1}\right).$14. The method as claimed in claim 1, wherein the candidate$o_{C,1}^{C,y}$is composed of random variables o_c,1, o_c,2 . . . , and o_c,y, where y is the number of characters of the candidate.15. The method as claimed in claim 1, wherein the left context$o_{L,1}^{L,x}$is composed of random variables o_L,1, o_L,2 . . . , and o_L,x, where x is the number of characters of the left context.16. The method as claimed in claim 1, wherein the right context$o_{R,1}^{R,z}$is composed of random variables o_R,1, o_R,2 . . . , and o_R,z, where z is the number of characters of the right context.17. The method as claimed in claim 2, wherein each random variable is a Chinese character.18. The method as claimed in claim 2, wherein each random variable is an English word.