Duplex ceramic filter

What is claimed: 1 . A waveguide duplexer comprising: a plurality of septa formed by a union of a first dielectric block and a second dielectric block, the plurality of septa comprising a first septum and a second septum; a plurality of windows defined by the first dielectric block and the second dielectric block, wherein a first window of the plurality of windows is further defined by the first septum and the second septum; a loop in communication with the first window and configured to transmit energy from a first port to the first window; a second port configured to receive, based on a width of the septa, the transmitted energy at a first distal end of the waveguide duplexer; and a third port configured to receive, based on the width of the septa, the transmitted energy at a second distal end of the waveguide duplexer. 2 . The waveguide duplexer of claim 1 , wherein the first septum is defined by a first width, the second septum is defined by a second width, and an input loading of the waveguide duplexer is based on the second width. 3 . The waveguide duplexer of claim 1 , wherein the loop is an inductive loop. 4 . The waveguide duplexer of claim 1 , wherein the first dielectric block comprises a first 4-pole filter and the second dielectric block comprises a second 4-pole filter. 5 . The waveguide duplexer of claim 1 , wherein a width of the first septum is equal to a width of the second septum. 6 . The waveguide duplexer of claim 1 , wherein a width of the first septum is different from a width of the second septum. 7 . The waveguide duplexer of claim 1 , wherein the first dielectric block comprises a first coupling structure and the second dielectric block comprises a second coupling structure, and the plurality of septa are formed by the union of the first coupling structure and the second coupling structure. 8 . The waveguide duplexer of claim 2 , wherein the first dielectric block comprises a first longitudinal surface comprising the first coupling structure, a second longitudinal surface, and a top surface, and the second dielectric block comprises a first longitudinal surface comprising the second coupling structure, a second longitudinal surface, and a top surface, and is coupled to the first dielectric block via respective first longitudinal surfaces. 9 . The waveguide duplexer of claim 2 , wherein the first coupling structure comprises a metallic coating disposed along an exterior of the first dielectric block and the second coupling structure comprises a metallic coating disposed along an exterior of the second dielectric block. 10 . The waveguide duplexer of claim 1 , wherein the transmitted energy is a radio frequency signal. 11 . The waveguide duplexer of claim 1 , wherein the first dielectric block comprises a ceramic and the second dielectric block comprises a ceramic. 12 . The waveguide duplexer of claim 1 , wherein the waveguide duplexer comprises an E-plane filter. 13 . A method of minimizing return loss of a transmission of a radio frequency (RF) signal, the method comprising: receiving an RF signal by a waveguide duplexer comprising a plurality of septa formed by a union of a first dielectric block and a second dielectric block, the plurality of septa comprising a first septum and a second septum, a plurality of windows defined by the first dielectric block and the second dielectric block, wherein a first window of the plurality of windows is further defined by the first septum and the second septum; transmitting, by a loop, the RF signal from a first port to the first window; receiving, at a second port based on a width of the septa, the transmitted RF signal at a first distal end of the waveguide duplexer; and receiving, at a third port based on the width of the septa, a returned RF signal at a second distal end of the waveguide duplexer. 14 . The method of claim 13 , wherein the loop is an inductive loop in communication with the first window. 15 . The method of claim 13 , wherein the loop is a capacitive probe in communication with the first window. 16 . The method of claim 13 , wherein a frequency of the transmitted RF signal is greater than a minimum transmission frequency and less than a maximum transmission frequency. 17 . The method of claim 13 , wherein the first dielectric block comprises a first 4-pole filter and the second dielectric block comprises a second 4-pole filter. 18 . A communication system comprising: a printed circuit board comprising input pads, first output pads, and second output pads; and a waveguide duplexer comprising: a plurality of septa formed by a union of a first dielectric block and a second dielectric block, the plurality of septa comprising a first septum and a second septum; a plurality of windows defined by the first dielectric block and the second dielectric block, wherein a first window of the plurality of windows is further defined by the first septum and the second septum; and an inductive loop configured to transmit energy from the input pads to the first window, wherein the first output pads are configured to receive, based on a width of the septa, the transmitted energy at a first distal end of the waveguide duplexer and the second output pads are configured to receive, based on the width of the septa, the transmitted energy at a second distal end of the waveguide duplexer. 19 . The communication system of claim 18 , wherein a width of the first septum is equal to a width of the second septum. 20 . The communication system of claim 18 , wherein a width of the first septum is different from a width of the second septum.