Abstract: Build environments for software can be constructed. For example, a computing device can receive a file indicating a first software component to be installed in a build environment and a second software component to be built in the build environment. The computing device can perform a first setup phase for creating part of the build environment by causing the first software component to be installed in the build environment. The computing device can also determine that the first setup phase is complete. Based on determining that the first setup phase is complete, the computing device can perform a second setup phase for completing the build environment by causing the second software component to be built in the build environment.

Abstract: Build environments for software can be constructed. For example, a computing device can receive a file indicating a first software component to be installed in a build environment and a second software component to be built in the build environment. The computing device can perform a first setup phase for creating part of the build environment by causing the first software component to be installed in the build environment. The computing device can also determine that the first setup phase is complete. Based on determining that the first setup phase is complete, the computing device can perform a second setup phase for completing the build environment by causing the second software component to be built in the build environment.

Abstract: Build environments for software can be constructed. For example, a computing device can receive a file indicating a first software component to be installed in a build environment and a second software component to be built in the build environment. The computing device can perform a first setup phase for creating part of the build environment by causing the first software component to be installed in the build environment. The computing device can also determine that the first setup phase is complete. Based on determining that the first setup phase is complete, the computing device can perform a second setup phase for completing the build environment by causing the second software component to be built in the build environment.

Abstract: Build environments for software can be constructed. For example, a computing device can receive a file indicating a first software component to be installed in a build environment and a second software component to be built in the build environment. The computing device can perform a first setup phase for creating part of the build environment by causing the first software component to be installed in the build environment. The computing device can also determine that the first setup phase is complete. Based on determining that the first setup phase is complete, the computing device can perform a second setup phase for completing the build environment by causing the second software component to be built in the build environment.

Abstract: In a method for controlling an electromagnetic valve, the temperature of the valve is detected, and activation of and/or the current feed to the valve are performed as a function of the temperature of the valve.

Abstract: In a device for controlling an electromagnetic valve, input device(s) write a multitude of measured values for the current and/or the voltage into a first memory to represent a characteristic. Analysis device(s) perform a state analysis and/or a change-over-time analysis. On the basis of the state analysis and/or the change-over-time analysis, evaluation device(s) correct at least one control variable, which characterizes the control, and write it into a second memory. Control device(s) control an output stage on the basis of the control variables.

Abstract: A procedure for checking the functionality of an electric heating device (10) with at least one PTC-element (13, 14) is suggested. The electric heating device (10) is operated at a battery voltage. When controlling the heating device (10) it is impinged with a current and at least one measuring value is detected, which represents the current that flows through the heating device. The measuring value for the current is compared to at least one reference value with a default tolerance width while considering the battery voltage. In the case of a measuring value that deviates from the reference value an error can be assumed.

Abstract: In a method for controlling an electromagnetic valve, the temperature of the valve is detected, and activation of and/or the current feed to the valve are performed as a function of the temperature of the valve.

Abstract: A fill level detection apparatus (23) is introduced for ascertaining a fill level in a storage tank (19) for a liquid reducing agent for use in an exhaust gas aftertreatment device (3), having a fill level detector (21) and a driving and evaluating unit (22), which are connected to each other with electrical lines (47a, 47b, 47c) and with respect to DC-currents are decoupled from each other by capacitors (45), which are connected in series with said electrical lines, and with respect to AC-currents are coupled with each other. Said fill level detection apparatus is thereby characterized in that the capacitors (45) are disposed as part of the fill level detector (21) separated from the driving and evaluating unit (22) by the electrical lines (47a, 47b, 47c).

Abstract: A procedure for checking the functionality of an electric heating device (10) with at least one PTC-element (13, 14) is suggested. The electric heating device (10) is operated at a battery voltage. When controlling the heating device (10) it is impinged with a current and at least one measuring value is detected, which represents the current that flows through the heating device. The measuring value for the current is compared to at least one reference value with a default tolerance width while considering the battery voltage. In the case of a measuring value that deviates from the reference value an error can be assumed.

Abstract: In a device for controlling an electromagnetic valve, input device(s) write a multitude of measured values for the current and/or the voltage into a first memory to represent a characteristic. Analysis device(s) perform a state analysis and/or a change-over-time analysis. On the basis of the state analysis and/or the change-over-time analysis, evaluation device(s) correct at least one control variable, which characterizes the control, and write it into a second memory. Control device(s) control an output stage on the basis of the control variables.