Methods for reducing optical beat interference by continuously varying laser temperatures and related optical network units

What is claimed is: 1 . A method of reducing optical beat interference at a receiver in a fiber optic network that has a plurality of optical network units communicating with the receiver over a common optical transmission path, the method comprising: controlling an output of a first temperature control system that establishes an operating temperature of a first laser that is included in a first of the optical network units so that the operating temperature of the first laser varies according to a first continuous function that has a first amplitude and a first frequency; and controlling an output of a second temperature control system that establishes an operating temperature of a second laser that is included in a second of the optical network units so that the operating temperature of the second laser varies according to a second continuous function that has a second amplitude and a second frequency, wherein the first continuous function is different than the second continuous function, the first amplitude is different than the second amplitude, and/or the first frequency is different than the second frequency. 2 . The method of claim 1 , wherein the first continuous function varies the operating temperature of the first laser from a first nominal temperature, wherein the first nominal temperature is a base temperature adjusted by a first temperature offset, and wherein the second continuous function varies the operating temperature of the second laser from a second nominal temperature, wherein the second nominal temperature is the base temperature adjusted by a second temperature offset. 3 . The method of claim 2 , wherein the first temperature offset is selected to be within a first predefined range and the second temperature offset is selected to be within a second predefined range that is different than the first predefined range. 4 . The method of claim 3 , wherein the first temperature offset is randomly selected within the first predefined range and the second temperature offset is randomly selected within the second predefined range. 5 . The method of claim 3 , wherein the first predefined range and the second predefined range partially overlap. 6 . The method of claim 1 , wherein the first amplitude is different from the second amplitude and the first frequency is different from the second frequency. 7 . The method of claim 6 , wherein the first and second amplitudes are randomly selected within a predetermined range and/or the first and second frequencies are randomly selected within a predetermined range. 8 . The method of claim 1 , wherein the first continuous function is one of a sinusoidal function or a sawtooth function. 9 . The method of claim 1 , wherein the first continuous function is the same type of function as the second continuous function. 10 . An optical network unit, comprising: a laser adapted to generate an optical signal having a given wavelength at a given temperature; a temperature control system that is thermally coupled to the laser that establishes an operating temperature of the laser; and a controller that is configured to set the operating temperature of the laser at a predefined base temperature and to automatically vary the operating temperature of the laser within a predefined range from the base temperature pursuant to a continuous function that has a first amplitude and a first frequency. 11 . The optical network unit of claim 10 , wherein the laser is a first laser, the continuous function comprises a first continuous function and the base temperature comprises a first base temperature, and wherein a first amplitude of the first continuous function is different than a second amplitude of a second continuous function that is used to automatically vary an operating temperature of a second laser of a second optical network unit within a predefined range from a second base temperature, wherein the second laser communicates over a common optical fiber with the first laser. 12 . The optical network unit of claim 11 , wherein the first base temperature comprises the sum of a common base temperature and a first temperature offset, the second base temperature comprises the sum of the common base temperature and a second temperature offset, and wherein the first temperature offset is different from the second temperature offset. 13 . The optical network of claim 10 , wherein the laser is a first laser, the continuous function comprises a first continuous function and the base temperature comprises a first base temperature, and wherein a first frequency of the first continuous function is different than a second frequency of a second continuous function that is used to automatically vary an operating temperature of a second laser of a second optical network unit within a predefined range from a second base temperature, wherein the second laser communicates over a common optical fiber with the first laser. 14 . The optical network of claim 11 , wherein a first frequency of the first continuous function is different than a second frequency of a second continuous function. 15 . The optical network of claim 10 , wherein the temperature control system comprises a thermoelectric cooler. 16 . A method of reducing optical beat interference in a fiber optic network that has a plurality of optical network units having lasers that transmit at a common nominal wavelength to communicate with a shared receiver over a common optical transmission path, the method comprising: providing a temperature control system at each optical network unit that is thermally coupled to the respective laser at each optical network unit; using the temperature control systems to establish operating temperatures of the respective lasers; automatically varying the thermal output of each of the temperature control systems according to respective continuous functions in order to automatically vary the operating temperature of each of the lasers, wherein at least one of the continuous function, the amplitude of the continuous function and/or the frequency of the continuous function used to vary the thermal output of the temperature control system that establishes the operating temperature of the laser of a first of the optical network units differs from the respective continuous function, the amplitude of the continuous function and/or the frequency of the continuous function used to vary the thermal output of the temperature control system that establishes the operating temperature of the laser of a second of the optical network units. 17 . The method of claim 16 , further comprising assigning a base temperature to the laser of each of the optical network units, wherein at least some of the lasers are assigned different base temperatures, and wherein automatically varying the thermal output of each of the temperature control systems according to respective continuous functions in order to automatically vary the operating temperature of each of the lasers comprise automatically varying the thermal output of each of the temperature control systems according to respective continuous functions in order to automatically vary the operating temperature of each of the lasers about the respective base temperature for each of the lasers. 18 . The method of claim 16 , wherein the amplitude and/or the frequency of at least some of the continuous functions are selected to be within a respective predefined amplitude range or a predefined frequency range. 19 . The method of claim 17 , wherein the amplitude and/or the frequen