Electromagnetic interference (EMI) shielding device and method for use in an optical communications system

What is claimed is: 1. A Z-pluggable optical communications module (OCM) comprising: a generally rectangular module housing, the module housing being configured to be inserted through an opening formed in a front panel of a box in a Z-direction of an X, Y, Z Cartesian Coordinate system, wherein the box houses an optical communications system; a first circuit board disposed within the housing; at least one parallel optical communications module (POCM) mounted on the first circuit board, said at least one POCM having a plurality of channels, each of the channels being either a transmit channel for transmitting optical data signals or a receive channel for receiving optical data signals; first ends of optical fibers of an optical fiber cable being connected to said at least one POCM, wherein the first ends are received in the module housing through an opening formed in a first end of the module housing; and an electromagnetic interference (EMI) shielding device fixedly secured to or integrally formed in the first end of the module housing such that when the module housing is fully inserted through the opening formed in the front panel of the box in the Z-direction of the X, Y, Z Cartesian Coordinate system, the EMI shielding device abuts the front panel and surrounds the opening to form an EMI seal about the opening that prevents, or at least helps prevent, EMI from escaping from the module housing through the opening. 2. The Z-pluggable OCM of claim 1 , wherein the EMI shielding device comprises a plurality of interconnected portions, and wherein each portion of the EMI shielding device is a non-segmented portion. 3. The Z-pluggable OCM of claim 2 , wherein each non-segmented portion is a round such that the abutment of each of the portions with the front panel constitutes a continuous line contact between the respective portion and the front panel. 4. The Z-pluggable OCM of claim 3 , wherein each of the non-segmented portions is made of a thin piece of metal that is rounded to form the respective rounds, and wherein each round has spring characteristics that allow the round to deform when the round abuts a surface such that the deforming round conforms to the abutting surface. 5. The Z-pluggable OCM of claim 1 , wherein the EMI shielding device remains in sliding abutment with the front panel even as the Z-pluggable OCM is moved in upward or downward Y-directions of the X, Y, Z Cartesian Coordinate system. 6. An optical communications system comprising: a system housing having at least a bottom panel and a front panel, the front panel residing in an X-Y plane that is orthogonal to a forward Z-direction and to a reverse Z-direction; a plurality of Z-pluggable OCMs disposed within respective openings formed in the front panel of the system housing, each Z-pluggable OCM including a respective module housing having a respective electromagnetic interference (EMI) shielding device fixedly secured to or integrally formed in a first end of the respective module housing that comes into abutment with the front panel when the module housing is fully inserted into the respective opening formed in the front panel, and wherein each respective EMI shielding device surrounds the respective opening to form an EMI seal about the respective opening that prevents, or helps prevent, EMI from escaping from the module housing through the opening. 7. The optical communications system of claim 6 , wherein each EMI shielding device is also in abutment with at least one adjacent EMI shielding device. 8. The optical communications system of claim 7 , wherein each EMI shielding device comprises a plurality of interconnected portions, and wherein each portion of the respective EMI shielding device is a non-segmented portion. 9. The optical communications system of claim 8 , wherein each non-segmented portion is a round such that the abutment of each of the portions with the front panel constitutes a continuous line contact between the respective portion and the front panel. 10. The optical communications system of claim 9 , wherein each of the non-segmented portions is made of a thin piece of metal that is rounded to form the respective rounds, and wherein each round has spring characteristics that allow the round to deform when the round abuts a surface such that the deforming round conforms to the abutting surface. 11. The optical communications system of claim 6 , wherein the EMI shielding devices remain in sliding abutment with the front panel even as the Z-pluggable OCMs are moved in upward or downward Y-directions of the X, Y, Z Cartesian Coordinate system. 12. A method for performing electromagnetic interference (EMI) shielding in an optical communications system, the method comprising: providing a Z-pluggable optical communications module (OCM) comprising a generally rectangular module housing configured to be inserted through an opening formed in a front panel of a box in a Z-direction of an X, Y, Z Cartesian Coordinate system, wherein a first circuit board is disposed within the module housing and at least one parallel optical communications module (POCM) is mounted on the first circuit board said at least one POCM having a plurality of channels, each of the channels being either a transmit channel for transmitting optical data signals or a receive channel for receiving optical data signals, and wherein first ends of optical fibers of an optical fiber cable are connected to said at least one POCM and are received into the module housing through an opening formed in a first end of the module housing, and wherein an electromagnetic interference (EMI) shielding device is fixedly secured to or integrally formed in the first end of the module housing; and fully inserting the module housing through the opening formed in the front panel of the box in the Z-direction of the X, Y, Z Cartesian Coordinate system until the EMI shielding device abuts the front panel, and wherein the EMI shielding device surrounds the opening to form an EMI seal about the opening that prevents, or at least helps prevent, EMI from escaping from the module housing through the opening. 13. The method of claim 12 , wherein the EMI shielding device comprises a plurality of interconnected portions, and wherein each portion of the EMI shielding device is a non-segmented portion. 14. The method of claim 13 , wherein each non-segmented portion is a round such that the abutment of each of the portions with the front panel constitutes a continuous line contact between the respective portion and the front panel. 15. The method of claim 14 , wherein each of the non-segmented portions is made of a thin piece of metal that is rounded to form the respective rounds, and wherein each round has spring characteristics that allow the round to deform when the round abuts a surface such that the deforming round conforms to the abutting surface. 16. The method of claim 12 , wherein the EMI shielding device remains in sliding abutment with the front panel even as the Z-pluggable OCM is moved in upward or downward Y-directions of the X, Y, Z Cartesian Coordinate system. 17. A method for performing electromagnetic interference (EMI) shielding in an optical communications system, the method comprising: providing a plurality of Z-pluggable optical communications modules (OCMs), each Z-pluggable OCM comprising a generally rectangular module housing configured to be inserted through an opening formed in a front panel of a box in a Z-direction of an X, Y, Z Cartesian Coordinate system, wherein each module housing has a first circuit board disposed within the module hou