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About 8 results
  • 5.3: The RLC Circuit
    https://math.libretexts.org/Courses/Mission_College/Math_4B%3A_Differential_Equations_(Kravets)/05%3A_Applications_of_Linear_Second_Order_Equations/5.03%3A_The_RLC_Circuit
    This section is about RLC circuits, the electrical analogs of spring-mass systems.
  • 5.3: The RLC Circuit
    https://math.libretexts.org/Under_Construction/Purgatory/Differential_Equations_and_Linear_Algebra_(Zook)/05%3A_Applications_of_Linear_Second_Order_Equations/5.03%3A_The_RLC_Circuit
    This section is about RLC circuits, the electrical analogs of spring-mass systems.
  • 5.3: The RLC Circuit
    https://math.libretexts.org/Courses/Chabot_College/Math_4%3A_Differential_Equations_(Dinh)/05%3A_Applications_of_Linear_Second_Order_Equations/5.03%3A_The_RLC_Circuit
    In this section we consider the RLC circuit, which is an electrical analog of a spring-mass system with damping.
  • 6.3: The RLC Circuit
    https://math.libretexts.org/Bookshelves/Differential_Equations/Elementary_Differential_Equations_with_Boundary_Value_Problems_(Trench)/06%3A_Applications_of_Linear_Second_Order_Equations/6.03%3A_The_RLC_Circuit
    In this section we consider the RLC circuit, which is an electrical analog of a spring-mass system with damping.
  • 6.3: The RLC Circuit
    https://math.libretexts.org/Courses/Cosumnes_River_College/Math_420%3A_Differential_Equations_(Breitenbach)/06%3A_Applications_of_Linear_Second_Order_Equations/6.03%3A_The_RLC_Circuit
    The battery or generator in Figure 6.3.1 creates a difference in electrical potential E=E(t) between its two terminals, which we’ve marked arbitrarily as positive and negative. (We could just as w...The battery or generator in Figure 6.3.1 creates a difference in electrical potential E=E(t) between its two terminals, which we’ve marked arbitrarily as positive and negative. (We could just as well interchange the markings.) We’ll say that E(t)>0 if the potential at the positive terminal is greater than the potential at the negative terminal, E(t)<0 if the potential at the positive terminal is less than the potential at the negative terminal, and E(t)=0 if the potential is the…
  • 5.3: The RLC Circuit
    https://math.libretexts.org/Courses/Mission_College/Math_4B%3A_Differential_Equations_(Reed)/05%3A_Applications_of_Linear_Second_Order_Equations/5.03%3A_The_RLC_Circuit
    This section is about RLC circuits, the electrical analogs of spring-mass systems.
  • 6.3: The RLC Circuit
    https://math.libretexts.org/Courses/Monroe_Community_College/MTH_225_Differential_Equations/06%3A_Applications_of_Linear_Second_Order_Equations/6.03%3A_The_RLC_Circuit
    This section is about RLC circuits, the electrical analogs of spring-mass systems.
  • 5.8: The RLC Circuit
    https://math.libretexts.org/Courses/Red_Rocks_Community_College/MAT_2561_Differential_Equations_with_Engineering_Applications/05%3A_Linear_Second_Order_Equations/5.08%3A_The_RLC_Circuit
    This section is about RLC circuits, the electrical analogs of spring-mass systems.

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