Method of optimized gear selection on high speed directional shifts

What is claimed is: 1. A method for machine velocity change gear selection in a work machine having a power source and a transmission configured to be shifted to a plurality of first gears for causing the work machine to move in a first direction due to power from the power source, and to be shifted to a plurality of second gears for causing the work machine to move in a second direction opposite the first direction due to the power from the power source, wherein each of the plurality of first gears and the plurality of second gears has a corresponding end of shift velocity of the work machine when the transmission is shifted into the one of the plurality of first gears or one of the plurality of second gears, the method comprising: determining at a controller of the work machine a current velocity of the work machine moving in the first direction based on information transmitted in a speed sensor signal from a speed sensor of the work machine; determining at the controller a maximum velocity change for the work machine from the current velocity, wherein the maximum velocity change is determined based on a maximum amount of energy that may be expended by components of the transmission to change a velocity of the work machine without increasing a current temperature of a relevant component of the transmission above a clutch limit temperature above which the transmission may experience a failure mode; selecting at the controller a machine velocity change target gear from the plurality of first gears and the plurality of second gears that has the greatest difference between the current velocity of the work machine and the end of shift velocity of the selected one of the plurality of first gears or one of the plurality of second gears that is not greater than the maximum velocity change; detecting at the controller a directional shift command input by an operator at an input direction control of the work machine; and causing the transmission to execute a shift to the machine velocity change target gear in response to detecting the direction shift command at the controller. 2. The method for machine velocity change gear selection of claim 1 , wherein the current velocity, the maximum velocity change and the end of shift velocity have units of revolutions per minute for a transmission output of the transmission. 3. The method for machine velocity change gear selection of claim 1 , comprising: detecting at the controller actuation of an input gear control of the work machine with a command to one of upshift and downshift from a current one of the plurality of first gears; and determining the current velocity of the work machine based on a sensed velocity of the work machine in response to detecting actuation of the input gear control. 4. The method for machine velocity change gear selection of claim 1 , wherein determining the maximum velocity change for the work machine comprises: determining at the controller a percent grade of a work surface over which the work machine is moving in the first direction based on information transmitted in a grade sensor signal from a grace sensor of the work machine; and determining the maximum velocity change based on the maximum amount of energy, wherein the maximum velocity change decreases when the percent grade of the work surface causes the work machine to move downhill in the first direction and uphill in the second direction. 5. The method for machine velocity change gear selection of claim 4 , wherein the maximum velocity change increases when the percent grade of the work surface causes the work machine to move uphill in the first direction and downhill in the second direction. 6. The method for machine velocity change gear selection of claim 1 , wherein determining the maximum velocity change for the work machine comprises: determining at the controller a percent grade of the work surface over which the work machine is moving in the first direction; and retrieving at the controller the corresponding maximum velocity change for the percent grade of the work surface from a table of data stored at a memory of the controller, wherein the table of data contains machine velocity change limits having a plurality of stored percent grades of a work surface over which the work machine is moving and, for each of the plurality of stored percent grades, corresponding maximum velocity changes for directional shifts from the first direction to the second direction, and from the second direction to the first direction, wherein the corresponding maximum velocity changes are previously determined based on the maximum amount of energy and the plurality of stored percent grades. 7. The method for machine velocity change gear selection of claim 1 , wherein determining the maximum velocity change for the work machine comprises: determining at the controller a mass of the work machine; and determining the maximum velocity change based on the maximum amount of energy, wherein the maximum velocity change decreases when the mass of the work machine increases and the maximum velocity change increases when the mass of the work machine decreases. 8. The method for machine velocity change gear selection of claim 1 , wherein determining the maximum velocity change for the work machine comprises: determining at the controller a current oil temperature of oil within a drive train component; and determining the maximum velocity change based on the maximum amount of energy, wherein the maximum velocity change decreases when the current oil temperature increases and the maximum velocity change increases when the current oil temperature decreases. 9. A work machine, comprising: a power source; a transmission operatively connected to the power source, the transmission configured to be shifted to a plurality of first gears for causing the work machine to move in a first direction due to power from the power source, and to be shifted to a plurality of second gears for causing the work machine to move in a second direction opposite the first direction due to the power from the power source, wherein each of the plurality of first gears and the plurality of second gears has a corresponding end of shift velocity of the work machine when the transmission is shifted into the one of the plurality of first gears of one of the plurality of second gears; a speed sensor operatively connected to one of the power source and the transmission, the speed sensor transmitting a speed sensor signal with a speed value; a controller operatively connected to the speed sensor, wherein: the controller is programmed to determine a current velocity of the work machine in the first direction based on the speed value of the speed sensor signal, the controller is programmed to determine a maximum velocity change for changing a velocity of the work machine from the current velocity, wherein the maximum velocity change is determined based on a maximum amount of energy that may be dissipated by components of the transmission to change the velocity of the work machine without increasing a current temperature of a relevant component of the transmission above a clutch limit temperature above which the transmission may experience a failure mode, and the controller is programmed to select a target gear from the plurality of first gears and the plurality of second gears that has the greatest difference between the current velocity of the work machine and the end of shift velocity of the selected one of the plurality of first gears or one of the plurality of second gears that is not greater than the maximum velocity change. 10. The work machine of claim 9 , wherein the current velocity, the maximum velocity change and the end of shift velo