Seamless metallic outer shell of an electrical connector having inward bulges

What is claimed is: 1. An electrical connector comprising: an insulative housing having a base; a center conductor secured to the insulative housing; and a metallic shell secured to the insulative housing and surrounding the center conductor, the metallic shell including a sleeve having a lower part secured to the base of the insulative housing and an upper part extending upwardly beyond the base of the insulative housing; wherein the insulative housing is insert-molded with the center conductor and the metallic shell; and the sleeve of the metallic shell is formed as a seamless structure. 2. The electrical connector as claimed in claim 1 , wherein the seamless structure of the sleeve is formed by a metal drawing process. 3. The electrical connector as claimed in claim 1 , wherein the upper part of the sleeve has a plurality of inward bulges. 4. The electrical connector as claimed in claim 3 , wherein the upper part has a chamfer at an upper inner edge thereof immediately adjacent to the inward bulges so as to obtain a feel of smooth transition from the chamfer to the inward bulges during mating with a complementary electrical connector. 5. The electrical connector as claimed in claim 1 , wherein the insulative housing has a post extending upward from the base, and the center conductor has a pair of contact arms positioned in a hole of the post. 6. A method of making electrical connectors comprising steps of: providing a first metal sheet unitarily formed with a plurality of center conductors in matrix; providing a second metal sheet unitarily formed with a plurality of metallic shells in matrix wherein each metallic shell includes a seamless sleeve via a corresponding drawing process; stacking the first metal sheet and the second metal sheet together in a vertical direction to have the center conductors aligned and surrounded within the corresponding sleeves, respectively; and providing a plurality of insulative housings each integrally formed with both the corresponding center conductor and the corresponding metallic shell via insert-molding to form each corresponding connector; wherein the center conductor is linked to the first metal sheet via a first linking bar while the metallic shell is linked to the second metal sheet via a second linking bar, the first linking bar is not aligned or overlapped with the second linking bar in the vertical direction, and the second linking bar includes three parts spaced from one another with ninety-degree intervals. 7. The method as claimed in claim 6 , further including a step of removing said the first linking bar originally linked to the center conductor and the second linking bar originally linked to the metallic shell from the respective housing for each connector. 8. The method as claimed in claim 6 , wherein the second metal sheet is stacked upon the first metal sheet. 9. The method as claimed in claim 6 , wherein an upper part of the sleeve includes a plurality of inward bulges. 10. The method as claimed in claim 6 , wherein the matrix defined in the first metal sheet is of M×N, and both M and N are integers greater than two. 11. A method of making electrical connectors, comprising the steps of: providing a first metal sheet unitarily formed with a plurality of center conductors in a matrix; providing a second metal sheet unitarily formed with a plurality of metallic shells in a matrix wherein each metallic shell includes a seamless sleeve via a corresponding drawing process; stacking the first metal sheet and the second metal sheet together in a vertical direction to have the center conductors aligned and surrounded within the corresponding sleeves, respectively; and providing a plurality of insulative housings each integrally formed with both the corresponding center conductor and the corresponding metallic shell via insert-molding to form each corresponding connector; wherein the matrix defined in the first metal sheet is of M×N and both M and N are integers greater than two.