When referencing this material, please cite at least one of the following publications:
- Jezewski J, Matonia A, Kupka T, Roj D, Czabanski R. >Determination of the fetal heart rate from abdominal signals: evaluation of beat-to-beat accuracy in relation to the direct fetal electrocardiogram. Biomedical Engineering/Biomedizinische Technik 2012 Jul;57(5):383-394. doi:10.1515/bmt-2011-0130.
- Matonia A, Jezewski J, Kupka T, Horoba K, Wrobel J, Gacek A. The influence of coincidence of fetal and maternal QRS complexes on fetal heart rate reliability. Medical & Biological Engineering & Computing 2006;44(5):393-403.
- Kotas M, Jezewski J, Horoba L, Matonia A. Application of spatio-temporal filtering to fetal electrocardiogram enhancement. Computer Methods and Programs in Biomedicine. 2011 Oct;104(1):1-9.
- Kotas M, Jezewski J, Matonia A, Kupka T. Towards noise immune detection of fetal QRS complexes. Computer Methods and Programs in Biomedicine. 2010 Mar;97(3):241-256.
Please also include the standard citation for PhysioNet:
Goldberger AL, Amaral LAN, Glass L, Hausdorff JM, Ivanov PCh, Mark RG, Mietus JE, Moody GB, Peng C-K, Stanley HE. PhysioBank, PhysioToolkit, and PhysioNet: Components of a New Research Resource for Complex Physiologic Signals. Circulation 101(23):e215-e220 [Circulation Electronic Pages; http://circ.ahajournals.org/content/101/23/e215.full]; 2000 (June 13).
The research material included in the Abdominal and Direct Fetal Electrocardiogram Database contains multichannel fetal electrocardiogram (FECG) recordings obtained from 5 different women in labor, between 38 and 41 weeks of gestation. The recordings were acquired in the Department of Obstetrics at the Medical University of Silesia, by means of the KOMPOREL system for acquisition and analysis of fetal electrocardiogram (ITAM Institute, Zabrze, Poland). Each recording comprises four differential signals acquired from maternal abdomen and the reference direct fetal electrocardiogram registered from the fetal head.
The configuration of the abdominal electrodes comprised four electrodes placed around the navel, a reference electrode placed above the pubic symphysis and a common mode reference electrode (with active-ground signal) placed on the left leg. To reduce the skin impedance, the areas under the Ag-AgCl electrodes were abraded. In all cases, the scalp electrode was placed for a clinical indication and all women consented to participate in this study.
The acquisition of direct fetal electrocardiogram was carried out with a typical spiral electrode, commonly used in a direct FECG channel of popular fetal monitors. The R-wave locations were automatically determined in the direct FECG signal by means of on-line analysis applied in the KOMPOREL system. These locations were then verified (off-line) by a group of cardiologists, resulting in a set of reference markers precisely indicating the R-wave locations. The markers have been stored together with the direct and indirect FECG signals in EDF/EDF+ format.
The provided recordings constitute an excellent material for testing and evaluation of efficacy of new FECG processing techniques, e.g. algorithms for suppression of maternal electrocardiogram in abdominal signals or for detection of fetal QRS complexes. In the authors' studies (1-4 above), these recordings were used to evaluate the accuracy of fetal heart rate measurement and to estimate its influence on the quantification of the beat-to-beat fetal heart rate (FHR) variability.
- Signals recorded in labor, between 38 and 41 weeks of gestation
- Four signals acquired from maternal abdomen
- Direct electrocardiogram recorded simultaneously from fetal head
- Positioning of electrodes was constant during all recordings
- Ag-AgCl electrodes (3M Red Dot 2271) and abrasive material to improve skin conductance (3M Red Dot Trace Prep 2236)
- Bandwidth: 1Hz - 150Hz (synchronous sampling of all signals)
- Additional digital filtering for removal of power-line interference (50Hz) and baseline drift
- Sampling rate: 1 kHz
- Resolution: 16 bits
- Input ranges are included in the records in EDF format
Name Last modified Size Description
Parent Directory - r10.edf 02-Aug-2012 07:16 2.9M digitized signals r08.edf 02-Aug-2012 07:15 2.9M digitized signals r07.edf 02-Aug-2012 07:15 2.9M digitized signals r04.edf 02-Aug-2012 07:15 2.9M digitized signals r01.edf 02-Aug-2012 07:14 2.9M digitized signals local.css 28-Oct-2015 19:53 3.1K r08.edf.qrs 02-Aug-2012 07:16 1.3K verified beat annotations r10.edf.qrs 02-Aug-2012 07:16 1.3K verified beat annotations r01.edf.qrs 02-Aug-2012 07:14 1.3K verified beat annotations r04.edf.qrs 02-Aug-2012 07:15 1.3K verified beat annotations r07.edf.qrs 02-Aug-2012 07:15 1.3K verified beat annotations SHA256SUMS 12-Dec-2012 14:36 1.0K SHA1SUMS 12-Dec-2012 14:36 678 MD5SUMS 12-Dec-2012 14:36 574 RECORDS 12-Dec-2012 14:35 40 list of record names ANNOTATORS 06-Aug-2012 20:43 30 list of annotators DOI 21-Sep-2015 14:00 0
If you would like help understanding, using, or downloading content, please see our Frequently Asked Questions.
If you have any comments, feedback, or particular questions regarding this page, please send them to the webmaster.
Comments and issues can also be raised on PhysioNet's GitHub page.
Updated Friday, 28 October 2016 at 18:58 BRST