Optical transmitter having multiple optical sources and a method to activate the same

I claim: 1. An optical transmitter operable between a power saving mode and an operating mode, comprising: a transmitter module including a plurality laser diodes (LDs), an LD driver for driving the LDs electrically, and a thermo-electric cooler (TEC) for mounting the LDs and the LD driver thereon; a TEC controller to set temperatures of the LDs in a target temperature by driving the TEC; an ambient temperature sensor to sense an ambient temperature of the transmitter module; and a micro-control-unit (MCU) configured to control the TEC controller and the LD driver, wherein the MCU, when the optical transmitter changes from the power saving mode to the operating mode, first activates the TEC controller when the ambient temperature sensed by the ambient temperature sensor is higher than the target temperature in advance to activation of the LD driver, but first activates the LD driver when the ambient temperature is lower than the target temperature in advance to activation of the TEC controller. 2. The optical transmitter of claim 1 , wherein the MCU determines a delay time from the activation of the TEC controller to the activation of the LD driver based on a difference between the ambient temperature and the target temperature at a beginning of the change from the power saving mode to the operating mode. 3. The optical transmitter of claim 2 , further comprising a memory to store a relation between the delay time and the difference between the ambient temperature and the target temperature, wherein the MCU determines the delay time based on the difference between the ambient temperature and the target temperature. 4. The optical transmitter of claim 3 , wherein the delay time linearly increases against the difference between the ambient temperature and the target temperature, and wherein the memory stores a slope of a linear relation of the delay time against the difference between the ambient temperature and the target temperature. 5. The optical transmitter of claim 3 , wherein the delay time linearly increases against the difference between the ambient temperature and the target temperature but saturates when the difference exceeds an upper limit or less than a lower limit, and wherein the memory stores a slope of a linear relation of the delay time against the difference between the ambient temperature and the target temperature, the upper limit, and the lower limit. 6. The optical transmitter of claim 1 , wherein the MCU, when the ambient temperature is higher than the target temperature, first activates the TEC controller with a temporary target temperature lower than the target temperature as the target temperature, and subsequently activates the LD driver by replacing the temporary target temperature with the target temperature when the temperatures of the LDs become within a preset range around the temporary target temperature. 7. The optical transmitter of claim 5 , wherein the temporary target temperature is lower than the target temperature but higher than a temperature when the TEC controller flows a TEC current substantially equal to a TEC current at the target temperature without activating the LD driver. 8. A method to change an optical transmitter from a power saving mode to an operating mode, the optical transmitter comprising a transmitter module including a plurality of laser diodes (LDs), an LD driver configured to drive the LDs electrically, and a thermo-electric cooler (TEC) that mounts the LDs and the LD driver thereon, the method comprising steps of: sensing an ambient temperature of the transmitter module; comparing the ambient temperature with a target temperature of the LDs; and when the ambient temperature is higher than the target temperature, first activating the TEC controller in advance to activation of the LD driver, but, when the ambient temperature is lower than the target temperature, first activating the LD driver in advance to activation of the TEC controller. 9. The method of claim 8 , wherein the activation of the LD driver is delayed by a delay time from the activation of the TEC controller depending on a difference between the ambient temperature and the target temperature. 10. The method of claim 9 , wherein the step of activating the TEC controller or the LD driver includes steps of reading a relation between the delay time and the difference between the ambient temperature and the target temperature from the memory prior to the activation of the TEC controller or the LD driver, and second activating the LD driver or the TEC controller delayed by the delay time determined by the relation between the delay time and the difference between the ambient temperature and the target temperature. 11. The method of claim 8 , wherein the step of first activating the TEC controller when the target temperature is lower than the ambient temperature includes steps of, first activating the TEC controller by a temporary target temperature that is lower than the target temperature but higher than a temperature at which the TEC controller flows a TEC current substantially equal to a TEC current at the target temperature without activating the LD driver, second activating the LD driver when the ambient temperature becomes within a present range around the temporary target temperature, and revising the temporary target temperature by the target temperature. 12. The optical transmitter of claim 8 , further includes a step of activating a bias current source to provide bias currents to respective LDs after the temperatures of the LDs become within a preset range around the target temperature.