DaubechiesI. Orthonormal bases of compactly supported wavelets. Comm Pure Appl Math1988; 41: 909–996.
2.
DuffyFHIyerVGSurwilloWW. Clinical Electroencephalography and Topographic Brain Mapping. New York: Springer Verlag; 1989.
3.
GrossmannAKronland-MartinetRMorletJ. Reading and understanding continuous wavelet transforms. In: CombesJMGrossmannATchamitchianP, (eds). Wavelets, Time-frequency Methods and Phase Space. New York: Springer; 1989; 2–20.
4.
SenhadjiLDillensegerJLWendlingFRochaCKinieA. Wavelet analysis of EEG for three-dimensional mapping of epileptic events. Ann Biomed Eng1995; 23: 543–552.
5.
GoelzHRoeslerFRoederBHennighausenE. Segregation of spatiotemporal components of auditory event related potentials. In: WitteHZwienerUSchackBDoeringA (eds). Quantitative and Topological EEG and MEG Analysis. Jena: Druckhaus Mayer Verlag; 1997; 3: 238–241.
6.
SchiffSJAldroubiAUnserMSatoS. Fast wavelet transform of EEG. Electroencephalogr Clin Neurophysiol1994; 91: 442–445.
MallatSZhongS. Characterization of signals from multiscale edges. IEEE Trans Pattern Anal Mach Intell1992; 14: 710–732.
9.
BerknerKWellsRO. A new hierarchical scheme for approximating the continuous wavelet transform with applications to edge detection. IEEE Sig Proc Letters1999; 6: 193–195.
10.
MallatSZhangZ. Matching pursuits with time-frequency dictionaries. IEEE Trans Sig Proc1993; 41: 3397–3415.
11.
DurkaPJBlinowskaKJ. Analysis of EEG transients by means of matching pursuit. Ann Biomed Eng1995; 23: 608–611.
12.
ZygierewiczJBlinowskaKJDurkaPJSzelenbergerWNiemcewiczSAndrosiukW. High resolution study of sleep spindles. Clin Neurophysiol1999; 110: 2136–2147.
13.
HughesJR. EEG in Clinical Practice. Boston, Mass: Butter-worth; 1982.
14.
GotmanJGloorP. Automatic recognition of interictal epileptic activity in the human scalp EEG. Electroencephalogr Clin Neurophysiol1976; 41: 513–529.
GloverJRRaghavanNKtonasPYFrostJD. Context-based automated detection of epileptogenic sharp transients in the EEG: Elimination of false positives. IEEE Trans Biomed Eng1989; 36: 519–527.
17.
DingleAAJonesRDCarrollGJFrightWR. A multistage system to detect epileptiform activity in the EEG. IEEE Trans Biomed Eng1993, 40: 1260–1268.
18.
JonesRDDingleAACarrollGJ. A system for detecting epileptiform discharges in the EEG: Real-time operation and clinical trial. Proc 18th Ann Int Conf IEEE Eng Med Biol Soc, Amsterdam; 1996.
19.
WebberWRSLittBWilsonKLesserRP. Practical detection of epileptiform discharges EDs in the EEG using an artificial neural network: A comparison of raw and parameterized EEG data. Electroencephalogr Clin Neurophysiol1994; 91: 194–204.
JamesCJJonesRDBonesPJCarrollGJ. Detection of epileptiform discharges in the EEG by a hybrid system comprising mimetic, self-organized artificial neural network, and fuzzy logic stages. Clin Neurophysiol1999; 110: 2049–2063.
22.
UnserM. Fast Gabor-like windowed Fourier and continuous wavelet transform. IEEE Sig Proc Lett1994; 1: 76–79.
23.
KalayciTOezdamarO. Wavelet preprocessing for automated neural network detection of EEG spikes. IEEE Eng Med Bio Mag1995; 14: 160–166.
24.
ClarenconDRenaudinMGourmelonP. Real-time spike detection in EEG signals using the wavelet transform and a dedicated digital signal processor card. J Neurosci Meth1996; 70: 5–14.
25.
D'AttelisCEIsaacsonSISirneRO. Detection of epileptic events in electroencephalograms using wavelet analysis. Ann Biomed Eng1997; 25: 286–293.
26.
GoelzHJonesRDBonesPJ. Continuous wavelet transform for the detection and classification of epileptiform activity in the EEG. Proc 21st Ann Int Conf of IEEE Eng Med Biol Soc, Atlanta, USA; 1999.
27.
MallatS. Multifrequency channel decompositions of images and wavelet models. IEEE Trans Acoust Speech Signal Process1989; 37: 2091–2110.
28.
UnserMAldroubiA. A review of wavelets in biomedical applications. Proc IEEE1996; 84: 626–638.
