Aalborg Universitet Converters
Aalborg Universitet Converters

LTC1569-7 - Linear Technology
LTC1569-7 - Linear Technology

D.S. Lymar, T.C. Neugebauer, and D.J. Perreault, “Coupled-Magnetic Filters with Adaptive Inductance Cancellation,” 2005 IEEE Power Electronics Specialists Conference , June 2005, pp. 590-600.
D.S. Lymar, T.C. Neugebauer, and D.J. Perreault, “Coupled-Magnetic Filters with Adaptive Inductance Cancellation,” 2005 IEEE Power Electronics Specialists Conference , June 2005, pp. 590-600.

D.S. Lymar, T.C. Neugebauer, and D.J. Perreault, “Coupled-Magnetic Filters with Adaptive Inductance Cancellation,” IEEE Transactions on Power Electronics , Vol. 21, No. 6, pp. 1529-1540, Nov. 2006.
D.S. Lymar, T.C. Neugebauer, and D.J. Perreault, “Coupled-Magnetic Filters with Adaptive Inductance Cancellation,” IEEE Transactions on Power Electronics , Vol. 21, No. 6, pp. 1529-1540, Nov. 2006.

EC2314 DIGITAL SIGNAL PROCESSING UNIT – I - INTRODUCTION
EC2314 DIGITAL SIGNAL PROCESSING UNIT – I - INTRODUCTION

The CCB external hardware interfaces
The CCB external hardware interfaces

Aalborg Universitet Optimal Design of High-Order Passive-Damped Filters for Grid-Connected Applications
Aalborg Universitet Optimal Design of High-Order Passive-Damped Filters for Grid-Connected Applications

M. Zhu, D.J. Perreault, V. Caliskan, T.C. Neugebauer, S. Guttowski, and J.G. Kassakian, “Design and Evaluation of Feedforward Active Ripple Filters,” IEEE Transactions on Power Electronics , March 2005, pp. 276-285.
M. Zhu, D.J. Perreault, V. Caliskan, T.C. Neugebauer, S. Guttowski, and J.G. Kassakian, “Design and Evaluation of Feedforward Active Ripple Filters,” IEEE Transactions on Power Electronics , March 2005, pp. 276-285.

The external hardware interfaces of the CCB.
The external hardware interfaces of the CCB.

The CCB external hardware interfaces
The CCB external hardware interfaces

A low-power magnitude detector for analysis of transient
A low-power magnitude detector for analysis of transient

T.C. Neugebauer and D.J. Perreault, “Parasitic Capacitance Cancellation in Filter Inductors,” 2004 IEEE Power Electronics Specialists Conference, Aachen, Germany, June 2004, pp. 3102-3107.
T.C. Neugebauer and D.J. Perreault, “Parasitic Capacitance Cancellation in Filter Inductors,” 2004 IEEE Power Electronics Specialists Conference, Aachen, Germany, June 2004, pp. 3102-3107.

Verilog-A Language
Verilog-A Language

LTC1569-6 - Linear Phase, DC Accurate, Low Power, 10th Order Lowpass Filter
LTC1569-6 - Linear Phase, DC Accurate, Low Power, 10th Order Lowpass Filter

technical manual
technical manual

LTC1569-6 - Linear Phase, DC Accurate, Low Power, 10th Order
LTC1569-6 - Linear Phase, DC Accurate, Low Power, 10th Order

DO D as BF256 A. B,C
DO D as BF256 A. B,C

Adaptive Systems in Digital Communication Designs
Adaptive Systems in Digital Communication Designs

Lecture 6: Parallel Resonance and Quality Factor
Lecture 6: Parallel Resonance and Quality Factor

Main dipole circuit simulations
Main dipole circuit simulations

power quality: harmonics in power systems
power quality: harmonics in power systems

SECTION 5-5: FREQUENCY TRANSFORMATIONS
SECTION 5-5: FREQUENCY TRANSFORMATIONS

LTC1060 - Linear Technology
LTC1060 - Linear Technology

LTC1562-2 - Very Low Noise, Low Distortion Active RC Quad Universal Filter
LTC1562-2 - Very Low Noise, Low Distortion Active RC Quad Universal Filter

LTC1562-2 - Linear Technology
LTC1562-2 - Linear Technology

Kolmogorov–Zurbenko filter



The Kolmogorov–Zurbenko (KZ) Filter was first proposed by A. N. Kolmogorov and formally defined by Zurbenko[1]. It is a series of iterations of a moving average filter of length m, where m is a positive, odd integer number. The KZ filter belongs to the class of Low-pass filters. The KZ filter has two parameters, the length m of the moving average window and the number of iterations k of the moving average itself. It also can be considered as a special window function designed to eliminate spectral leakage.