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Once the crack growth rate at an initiated SCC is determined, it can be used by the performance assessment to determine the time to through-wall more » penetration for the waste package. This paper presents the development of the SDFR crack growth rate model based on technical information in the literature as well as experimentally determined crack growth rates developed specifically for Alloy UNS-N in environments relevant to high level radioactive-waste packages of the proposed Yucca Mountain radioactive-waste repository.

In addition, a seismic damage related SCC crack opening area density model is briefly described. Similar records in OSTI. GOV collections:. Full Record Other Related Research. If the settings are inconsistent with the connected driver, an error message will be generated and the parameters will not be saved to the LED driver If the model number of the configured driver is ordered, the parameters can be programmed into the appropriate base model driver at the factory and shipped to the customer either for installation or for use as a sample.

The programmed LED driver can also be labeled with the programmed parameters. If the model number entered is within the specification of the currently connected LED driver , the currently connected driver can then be reconfigured per the specifications of the selected model number.

If the selected model number is outside the specification of the currently connected driver, the base model number field will be highlighted, alerting the user that the selected model number is outside the specifications of the currently connected driver.

The user can then select a different model number or restart by connecting a different base model driver. The GUI screen display also allows the user to specify the form factor, i. Specifically, the phase control input may be either a two-wire electronic-low voltage ELV phase-control input or a three-wire phase-control input. In addition, the LED driver may be operable to be responsive to a combination of control inputs.

For example, one LED driver may be configured to be operable to receive control inputs from both the communication bus via the communication circuit and three-wire phase control dimming signals via the phase control input circuit A safety rating may be displayed in response to the selections made.

According to an alternative embodiment, the desired safety rating may be entered by the user. In addition, the screen will show an image of the selected mechanical form factor of the driver at The configuration process is typically started after the user has downloaded the configuration program, connected the LED driver to the programming device , and applied power to the LED driver per steps , , of FIG.

Then at step , the programming device retrieves the base model number from the LED driver Additionally, at step , the programming device may be operable to retrieve other parameters from the LED driver such as output type, control input type, or mechanical form factor in the event that the LED driver had already been programmed or manufactured with some parameters. As the user makes various parameter selections at step , the model number displayed on the GUI display screen may also update in response to those parameter selections.

As the user enters portions of the model number on the GUI display at step , the parameter information corresponding to the entered model number are also displayed on the GUI screen display , and further settings may be eliminated depending on the portion of the model number entered into the GUI software. Alternatively, if the user decides not to change the connected LED driver at step , then the user may change any of the incompatible selections via steps - At this point, the process ends.

However, in the event that the user evaluates the recently programmed LED driver and determines that the driver is not operating as expected, the user may easily repeat the process in order to make any additional modifications to the LED driver The process is executed by the control circuit of the LED driver once communication has been established between the programming device and the LED driver i. At step , the control circuit retrieves the base model number from the memory The base model number may be saved to the memory during the initial manufacturing process of the LED driver At step , the output type i.

Next at step , all of the data that was retrieved from the memory is sent to the programming device such that it can be displayed on the GUI display screen i. The control circuit then waits at step to receive new parameters from the programming device , and once the new parameters are received, they are stored in the memory at step before the process ends.

Thus, the configuration program allows the user to program the LED driver to a desired current for a constant current driver or desired voltage for a constant voltage driver and change the current or voltage as desired, until the desired parameters, such as desired light output, are achieved either by visual observation or by feedback from the sensor that may be connected to the user's computer.

In the factory, one of the basic model drivers can then be programmed to the selected specifications and the memory contents locked to those settings by preventing further changes to the target voltage or current stored in the microprocessor's memory.

In the factory, the driver can be labeled with the selected specifications, i. Underwriters Laboratory UL. Thus, an optimized LED driver can be configured. This configuration can be achieved to optimize the lighting system driven by the driver.

In addition, a single LED driver can be easily and quickly reconfigured multiple times to evaluate the overall performance of the lighting system. Furthermore, the computer can identify the particular model number of the LED driver associated with the configured parameters.

This model number driver can then be either ordered by the user for installation or a sample can be ordered for testing at the installation location. Accordingly, the development tool according to the present invention allows the user to configure an LED driver to the optimized configuration necessary for a particular application. This also minimizes the number of LED drivers that the factory needs to stock.

According to the present invention, the factory needs only stock a limited number of basic LED drivers in different power ranges, for example, three, each in a different power range, plus a limited number of different physical form factor variations, e. The factory accordingly need stock only eighteen base models of driver that is three output ranges times three form factors times two control inputs for a total of eighteen base models.

Then, using the tool according to the present invention, the appropriate base model can be programmed with the desired voltage and current specifications, as selected in the field. Those voltage and current specifications can then be locked in so that they cannot be altered and the driver can be labeled with the final model according to the programmed settings.

These specifications can also be used for UL approval. Although the present invention has been described in relation to particular embodiments thereof, many other variations and modifications and other uses will become apparent to those skilled in the art. It is preferred, therefore, that the present invention be limited not by the specific disclosure herein, but only by the appended claims. What is claimed is: 1. A load control circuit for controlling the amount of power delivered to an electrical load, the load control circuit comprising: a regulation transistor adapted to be coupled in series with the load to control the magnitude of a load current conducted through the load, so as to control the amount of power delivered to the load; and.

The load control circuit of claim 1 , further comprising: a control circuit operatively coupled to the regulation transistor for controlling the regulation transistor to operate in the linear region to thus adjust the magnitude of the load current through the load in response to the first load current feedback signal.

The load control circuit of claim 2 , wherein the feedback circuit generates a second load current feedback signal representative of the magnitude of the load current, the first and second load current feedback signals characterized by respective first and second gains applied to the magnitude of the load current, the first gain different than the second gain, the control circuit operable to determine the magnitude of the load current in response to both the first and second load current feedback signals.

The load control circuit of claim 3 , wherein the control circuit only uses the first load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is greater than a first threshold voltage, and only uses the second load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is less than a second threshold voltage.

The load control circuit of claim 4 , wherein the control circuit combines the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages.

The load control circuit of claim 5 , wherein the control circuit uses a weighted sum of the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages.

The load control circuit of claim 6 , wherein weighting factors of the weighted sum of the first and second load current feedback signals are functions of the magnitude of the second load current feedback signal. The load control circuit of claim 6 , wherein weighting factors of the weighted sum of the first and second load current feedback signals are functions of the amount of elapsed time since the magnitude of the second load current feedback signal transitioned across either of the first and second threshold voltages.

The load control circuit of claim 4 , wherein the second gain is greater than the first gain. The load control circuit of claim 9 , wherein the first gain is approximately one. The load control circuit of claim 4 , wherein the control circuit combines the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between first and second threshold voltages.

The load control circuit of claim 12 , wherein the control circuit is operable to: generate a current control signal for controlling the regulation transistor to operate in the linear region to thus control the magnitude of the load current conducted through the load;. The load control circuit of claim 13 , wherein the control circuit is further operable to wait for a second delay time after rendering the gain-adjustment transistor non-conductive, and resume controlling the regulation transistor in response to the magnitude of the load current at the end of the second delay time.

The load control circuit of claim 14 , further comprising: a filter circuit coupled in series between the control circuit and a gate of the regulation transistor, the filter circuit operable to receive the current control signal from the control circuit, the filter circuit referenced to a source of the regulation transistor.

The load control circuit of claim 12 , wherein the control circuit is operable to control the regulation transistor using a pulse-width modulation technique to adjust the amount of power delivered to the load, the control circuit rendering the gain-adjustment transistor non-conductive and conductive during a valley of the pulse-width modulated load current when the instantaneous magnitude of the load current is approximately zero amps.

The LED driver of claim 17 , wherein the control circuit uses only the first load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is greater than a first threshold voltage, and uses only the second load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is less than a second threshold voltage.

The LED driver of claim 18 , wherein the control circuit combines the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages. The LED driver of claim 19 , wherein the control circuit uses a weighted sum of the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages.

The LED driver of claim 20 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the magnitude of the second load current feedback signal. The LED driver of claim 20 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the amount of elapsed time since the magnitude of the second load current feedback signal transitioned across either of the first and second threshold voltages.

The LED driver of claim 17 , wherein the LED drive circuit further comprises a regulation transistor adapted to be coupled in series with the load to control the magnitude of the load current conducted through the load, the control circuit operatively coupled to the regulation transistor for controlling the regulation transistor to operate in the linear region to thus adjust the magnitude of the load current through the load in response to the first load current feedback signal.

The LED driver of claim 24 , wherein the control circuit is operable to: generate a current control signal for controlling the regulation transistor to operate in the linear region to thus control the magnitude of the load current conducted through the LED light source;.

The LED driver of claim 23 , wherein the control circuit is operable to control the regulation transistor using a pulse-width modulation technique to adjust the intensity of the LED light source, the control circuit rendering the gain-adjustment transistor non-conductive and conductive during a valley of the pulse-width modulated load current when the instantaneous magnitude of the load current is approximately zero amps. The LED driver of claim 17 , wherein the maximum load current is at least approximately one thousand times larger than the minimum load current.

A load control circuit for controlling the amount of power delivered to an electrical load, the load control circuit comprising: a regulation transistor adapted to be coupled in series with the load to control the magnitude of a load current conducted through the load, so as to control the amount of power delivered to the load;.

The load control circuit of claim 28 , wherein the control circuit uses only the first load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is greater than a first threshold voltage, and uses only the second load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is less than a second threshold voltage. The load control circuit of claim 29 , wherein the control circuit combines the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages.

The load control circuit of claim 30 , wherein the control circuit uses a weighted sum of the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages. The load control circuit of claim 31 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the magnitude of the second load current feedback signal.

The load control circuit of claim 31 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the amount of elapsed time since the magnitude of the second load current feedback signal transitioned across either of the first and second threshold voltages.

The load control circuit of claim 30 , wherein the second gain is greater than the first gain. The load control circuit of claim 34 , wherein the first gain is approximately one.

The load control circuit of claim 28 , wherein the control circuit combines the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between first and second threshold voltages.

The load control circuit of claim 28 , where the load control circuit is able to control the amount of power delivered to the load from a minimum load current to a maximum load current, the maximum load current at least approximately one thousand times larger than the minimum load current. The load control circuit of claim 38 , wherein the control circuit is further operable to wait for a second delay time after rendering the gain-adjustment transistor non-conductive, and resume controlling the regulation transistor in response to the magnitude of the load current at the end of the second delay time.

The load control circuit of claim 39 , further comprising: a filter circuit coupled in series between the control circuit and a gate of the regulation transistor, the filter circuit operable to receive the current control signal from the control circuit, the filter circuit referenced to a source of the regulation transistor. The load control circuit of claim 38 , wherein the control circuit is operable to control the regulation transistor using a pulse-width modulation technique to adjust the amount of power delivered to the load, the control circuit rendering the gain-adjustment transistor non-conductive and conductive during a valley of the pulse-width modulated load current when the instantaneous magnitude of the load current is approximately zero amps.

The load control circuit of claim 38 , wherein the regulation transistor comprises a FET. The load control circuit of claim 38 , where the load control circuit is able to control the amount of power delivered to the load from a minimum load current to a maximum load current, the maximum load current at least approximately one thousand times larger than the minimum load current.

A method of controlling the amount of power delivered to an electrical load, the method comprising: controlling the magnitude of a load current conducted through the load, so as to control the amount of power delivered to the load;. The method of claim 44 , further comprising: using only the first load current feedback signal to determine the magnitude of the load current when the magnitude of the second load current feedback signal is greater than a first threshold voltage; and.

The method of claim 45 , wherein calculating the magnitude of the load current in response to combining both the first and second load current feedback signals further comprises combining the first and second load current feedback signals when the magnitude of the second load current feedback signal is between the first and second threshold voltages.

The method of claim 46 , wherein combining the first and second load current feedback signals further comprises using a weighted sum of the first and second load current feedback signals to determine the magnitude of the load current when the magnitude of the second load current feedback signal is between the first and second threshold voltages. The method of claim 47 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the magnitude of the second load current feedback signal.

The method of claim 47 , wherein the weighting factors of the weighted sum of the first and second load current feedback signals are functions of the amount of elapsed time since the magnitude of the second load current feedback signal transitioned across either of the first and second threshold voltages.

The method of claim 45 , wherein the second gain is greater than the first gain. The method of claim 50 , wherein the first gain is approximately one. A method of controlling the amount of power delivered to an electrical load, the method comprising: controlling the magnitude of a load current conducted through the load by controlling a regulation transistor coupled so as to conduct the load current to operate in the linear region, so as to control the amount of power delivered to the load;.

The method of claim 52 , further comprising: waiting for a second delay time after rendering the gain-adjustment transistor non-conductive; and. The method of claim 52 , further comprising: controlling the regulation transistor using a pulse-width modulation technique to adjust the amount of power delivered to the load; and.

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