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Basic Continuous Time Signals01:22

Basic Continuous Time Signals

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Basic continuous-time signals include the unit step function, unit impulse function, and unit ramp function, collectively referred to as singularity functions. Singularity functions are characterized by discontinuities or discontinuous derivatives.
The unit step function, denoted u(t), is zero for negative time values and one for positive time values, exhibiting a discontinuity at t=0. This function often represents abrupt changes, such as the step voltage introduced when turning a car's...
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BIBO stability of continuous and discrete -time systems01:24

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System stability is a fundamental concept in signal processing, often assessed using convolution. For a system to be considered bounded-input bounded-output (BIBO) stable, any bounded input signal must produce a bounded output signal. A bounded input signal is one where the modulus does not exceed a certain constant at any point in time.
To determine the BIBO stability, the convolution integral is utilized when a bounded continuous-time input is applied to a Linear Time-Invariant (LTI) system....
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Sampling Continuous Time Signal01:11

Sampling Continuous Time Signal

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In signal processing, a continuous-time signal can be sampled using an impulse-train sampling technique, followed by the zero-order hold method. Impulse-train sampling involves the use of a periodic impulse train, which consists of a series of delta functions spaced at regular intervals determined by the sampling period. When a continuous-time signal is multiplied by this impulse train, it generates impulses with amplitudes corresponding to the signal's values at the sampling points.
In the...
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Linear time-invariant Systems01:23

Linear time-invariant Systems

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A system is linear if it displays the characteristics of homogeneity and additivity, together termed the superposition property. This principle is fundamental in all linear systems. Linear time-invariant (LTI) systems include systems with linear elements and constant parameters.
The input-output behavior of an LTI system can be fully defined by its response to an impulsive excitation at its input. Once this impulse response is known, the system's reaction to any other input can be...
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Continuous -time Fourier Transform01:11

Continuous -time Fourier Transform

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The Fourier series is instrumental in representing periodic functions, offering a powerful method to decompose such functions into a sum of sinusoids. This technique, however, necessitates modification when applied to nonperiodic functions. Consider a pulse-train waveform consisting of a series of rectangular pulses. When these pulses have a finite period, they can be accurately represented by a Fourier series. Yet, as the period approaches infinity, resulting in a single, isolated pulse, the...
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Basic Discrete Time Signals01:16

Basic Discrete Time Signals

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The unit step sequence is defined as 1 for zero and positive values of the integer n. This sequence can be graphically displayed using a set of eight sample points, showing a step function starting from n=0 and remaining constant thereafter.
The unit impulse or sample sequence is mathematically expressed as zero for all n values except at n=0, where it is one. The unit impulse sequence, denoted by δ(n), is the first difference of the unit step sequence, while the unit step sequence u(n) is...
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Exotic Synchronization in Continuous Time Crystals Outside the Symmetric Subspace.

Parvinder Solanki1, Midhun Krishna2, Michal Hajdušek3,4

  • 1University of Basel, Department of Physics, Klingelbergstrasse 82, CH-4056 Basel, Switzerland.

Physical Review Letters
|January 29, 2025
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Summary
This summary is machine-generated.

Researchers explored continuous time crystals (CTCs) beyond symmetric subspaces. Including asymmetric subspaces in spin systems leads to multistability, initial state-dependent dynamics, and exotic synchronization phenomena like chimera states.

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Area of Science:

  • Condensed Matter Physics
  • Quantum Dynamics
  • Nonlinear Systems

Background:

  • Continuous time crystals (CTCs) are a novel phase of matter exhibiting periodic behavior in time.
  • Research has primarily focused on CTCs within the symmetric subspace of spin systems.
  • The stability and dynamics of CTCs outside the symmetric subspace remain largely unexplored.

Purpose of the Study:

  • To investigate the effect of asymmetric subspaces on the dynamics of continuous time crystals (CTCs).
  • To explore emergent phenomena in driven dissipative spin systems when including asymmetric subspaces.
  • To analyze the impact of multistability on synchronization and nonlinear dynamics in ensembles of CTCs.

Main Methods:

  • Theoretical investigation of a driven dissipative spin model.
  • Inclusion of asymmetric subspaces in the analysis of CTC dynamics.
  • Examination of coupled identical CTCs to study synchronization regimes.

Main Results:

  • The inclusion of asymmetric subspaces leads to multistability in CTC dynamics.
  • Dynamics become dependent on the initial state of the system.
  • Exotic synchronization regimes, including chimera states and cluster synchronization, emerge in coupled CTCs.
  • Other nonlinear phenomena like oscillation death and signatures of chaos are observed.

Conclusions:

  • Asymmetric subspaces significantly alter CTC dynamics, introducing multistability and initial state dependence.
  • The study reveals novel synchronization patterns and nonlinear phenomena in driven dissipative spin systems.
  • This work expands the understanding of CTCs beyond the symmetric subspace, opening new avenues for research.