This document describes a heart prescreening device developed using a low-power MSP430 microcontroller. The device aims to provide cardiac screening in rural areas by non-invasively analyzing heart sounds. It uses signal processing techniques to extract and classify heart sounds into normal or abnormal categories. The system architecture incorporates adaptive denoising algorithms and physiological considerations for analysis. A prototype was developed using a Texas Instruments MSP430 microcontroller due to its low-power capabilities. Preliminary results found the device could help determine cardiac conditions and be used by paramedics for rural healthcare screening.
In this paper designing of a battery operated portable single channel electroencephalography (EEG) signal acquisition system is presented. The advancement in the field of hardware and signal processing tools made possible the utilization of brain waves for the communication between humans and computers. The work presented in this paper can be said as a part of bigger task, whose purpose is to classify EEG signals belonging to a varied set of mental activities in a real time Brain Computer Interface (BCI). Keeping in mind the end goal is to research the possibility of utilizing diverse mental tasks as a wide correspondence channel in the middle of individuals and PCs. This work deals with EEG based BCI, intent on the designing of portable EEG signal acquisition system. The EEG signal acquisition system with a cut off frequency band of 1-100 Hz is designed by the use of integrated circuits such as low power instrumentation amplifier INA128P, high gain operational amplifiers LM358P. Initially the amplified EEG signals are digitized and transmitted to a PC by a data acquisition module NI DAQ (SCXI-1302). These transmitted signals are then viewed and stored in the LAB VIEW environment. From a varied set of experimental observation it can be said that the system can be implemented in the acquisition of EEG signals and can stores the data to a PC efficiently and the system would be of advantage to the use of EEG signal acquisition or even BCI application by adapting signal processing tools.
Biomedical Parameter Transfer Using Wireless Communicationijsrd.com
In spite of the improvement of communication link and despite all progress in advanced communication technologies, there are still very few functioning commercial wireless monitoring systems, which are most off-line, and there are still a number of issues to deal with. Therefore, there is a strong need for investigating the possibility of design and implementation of an interactive real-time wireless communication system. In this paper, a generic real-time wireless communication system was designed and developed for short and long term remote patient-monitoring applying wireless protocol. The primary function of this system is to monitor the temperature and Heart Beat of the Patient and the Data collected by the sensors are sent to the Microcontroller. The Microcontroller transmits the data over the air. At the receiving end a receiver is used to receive the data and it is decoded and fed to Microcontroller, which is then displayed over the LCD display. If there is a dangerous change in patient's status an alarm is also sounded. The paper deals with the design and development of hardware and software for temperature and heartbeat measurement of a patient over LCD.
In this paper designing of a battery operated portable single channel electroencephalography (EEG) signal acquisition system is presented. The advancement in the field of hardware and signal processing tools made possible the utilization of brain waves for the communication between humans and computers. The work presented in this paper can be said as a part of bigger task, whose purpose is to classify EEG signals belonging to a varied set of mental activities in a real time Brain Computer Interface (BCI). Keeping in mind the end goal is to research the possibility of utilizing diverse mental tasks as a wide correspondence channel in the middle of individuals and PCs. This work deals with EEG based BCI, intent on the designing of portable EEG signal acquisition system. The EEG signal acquisition system with a cut off frequency band of 1-100 Hz is designed by the use of integrated circuits such as low power instrumentation amplifier INA128P, high gain operational amplifiers LM358P. Initially the amplified EEG signals are digitized and transmitted to a PC by a data acquisition module NI DAQ (SCXI-1302). These transmitted signals are then viewed and stored in the LAB VIEW environment. From a varied set of experimental observation it can be said that the system can be implemented in the acquisition of EEG signals and can stores the data to a PC efficiently and the system would be of advantage to the use of EEG signal acquisition or even BCI application by adapting signal processing tools.
Biomedical Parameter Transfer Using Wireless Communicationijsrd.com
In spite of the improvement of communication link and despite all progress in advanced communication technologies, there are still very few functioning commercial wireless monitoring systems, which are most off-line, and there are still a number of issues to deal with. Therefore, there is a strong need for investigating the possibility of design and implementation of an interactive real-time wireless communication system. In this paper, a generic real-time wireless communication system was designed and developed for short and long term remote patient-monitoring applying wireless protocol. The primary function of this system is to monitor the temperature and Heart Beat of the Patient and the Data collected by the sensors are sent to the Microcontroller. The Microcontroller transmits the data over the air. At the receiving end a receiver is used to receive the data and it is decoded and fed to Microcontroller, which is then displayed over the LCD display. If there is a dangerous change in patient's status an alarm is also sounded. The paper deals with the design and development of hardware and software for temperature and heartbeat measurement of a patient over LCD.
DSP Applications in medical field:Hearing aid, ECG, Blood pressure monitor.
Noise filtering,Fast fourier transform and Bandpass & FIR filter on matlab.
Transmission of arm based real time ecg for monitoring remotely located patienteSAT Publishing House
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
DSP Applications in medical field:Hearing aid, ECG, Blood pressure monitor.
Noise filtering,Fast fourier transform and Bandpass & FIR filter on matlab.
Transmission of arm based real time ecg for monitoring remotely located patienteSAT Publishing House
IJRET : International Journal of Research in Engineering and Technology is an international peer reviewed, online journal published by eSAT Publishing House for the enhancement of research in various disciplines of Engineering and Technology. The aim and scope of the journal is to provide an academic medium and an important reference for the advancement and dissemination of research results that support high-level learning, teaching and research in the fields of Engineering and Technology. We bring together Scientists, Academician, Field Engineers, Scholars and Students of related fields of Engineering and Technology
Opleiding voor VOKA op 13/5/2013. Social Media Marketing.
Werkt social media nu eigenlijk wel voor mijn onderneming? Hoe kan ik eraan beginnen en waar zit de meerwaarde tegenover andere media? We geven u praktische tips, structuur en strategie voor uw bedrijf. Deze tweedaagse workshop biedt u een handleiding naar een professionele aanpak.
Inhoud
- Adverteren en traffic genereren
* Facebook Ads
- Viral marketing via Facebook
* Apps en hun effect - case study's
* Campagnes opstellen en doelen bereiken
* Resultaten en Facebook Insights
- Social media in de firma
* Strategie
* Doelen
* Policy
* Resultaten en ROI
- Een concreet plan opstellen en group discussion
Doelgroep
Zaakvoerders, marketing managers en communicatieverantwoordelijken die willen inzetten op de nieuwe social media
Uw trainer
Kevin Heylen, expert conversation management en marketing en zaakvoerder - Think Tomorrow.
Het is een jonge onderneming met specialisatie in nieuwe media en online technologie. De twee oprichters Kevin en Emma verdienden reeds hun sporen in de marketingwereld en bloggen voor verscheidene marketingplatformen.
International Journal of Engineering Research and Applications (IJERA) is an open access online peer reviewed international journal that publishes research and review articles in the fields of Computer Science, Neural Networks, Electrical Engineering, Software Engineering, Information Technology, Mechanical Engineering, Chemical Engineering, Plastic Engineering, Food Technology, Textile Engineering, Nano Technology & science, Power Electronics, Electronics & Communication Engineering, Computational mathematics, Image processing, Civil Engineering, Structural Engineering, Environmental Engineering, VLSI Testing & Low Power VLSI Design etc.
HUMAN HEALTH MONITORING SYSTEM IN ABNORMAL CONDITION USING MSP 430 TO REMOTE...ijiert bestjournal
In hospital during the treatment of patient,doctor should have to monitor patient�s physiological information. Like,Physiological signal such as Heart beats,Blood s ugar (glucose),Body Temperature. Different chronic diseases like di abetes,congestive heart failure and also other diseases required to monitor physiological signa l of patient. Because we are not able to completely cure this chronicle diseases only to way to cure this diseases is to keep monitoring signals related to this di seases and control them. In this paper,proposed system in which different sensors are us ed to collect the physiological signals from patient and transfer this physiological measuremen t signals to pers onal computer of doctor or other paramedical staff. So this way patient can be analyzed by doctors from central observation canter. In this system we are taki ng three physiological si gnals from like Blood sugar (glucose),Body Temperature,Heart rate and transfer this physiological signals using communication module to the personal computer of observation center. Thus it reduce doctor work load and give more accurate result.
ECG SIGNAL ACQUISITION, FEATURE EXTRACTION AND HRV ANALYSIS USING BIOMEDICAL ...IAEME Publication
This Paper contains the complete process of ECG/EKG signal Acquisition from
hardware to its analysis using LabVIEW and Biomedical Workbench. Hardware of ECG
has the amplification, filtering and conversion of analog ECG data to digital by using
Arduino Uno. The acquisition part deal with acquiring the hardware data to analyzable
file format into pc. Here 6-channel ADC in Arduino Uno with LabVIEW interface is used
for conversion. Now the acquired ECG data is processed and analyzed with biomedical
workbench that provides the various features of ECG signal processing. This system is
very easy to implement and cost effective
Elderly care is one of the many applications
supported by real-time activity recognition systems. We have
slightly modified the project based on suggestions of the previous
examiner and replaced the RFID Card with NFC.Studies show
that aged persons experience steady decline in cognitive, visual
and physical functions caused by different age-related diseases.
New applications are under active development to provide daily
support for elderlies with different types and degrees of
impairments.
An Efficient Design and FPGA Implementation of JPEG Encoder using Verilog HDLijsrd.com
Image compression is the reduction or elimination of redundancy in data representation in order to achieve reduction in storage and communication cost. For this we use the simple computational method, 2D-DCT, using two 1D-DCT performed on matrix of (8X8). The DCT is a technique that converts a signal from spatial domain to frequency domain. Here we first convert the image into minimum code units. Then 2-D DCT is applied on each block. Then further process of Quantization, Zig-Zag approach and encoding is applied on the processed data. The architecture uses 3049 slices, 2,457 LUT, 46 I/Os of Xilinx Spartan-3 XC3S1600.
An Implementation of Embedded System in Patient Monitoring Systemijsrd.com
This paper deals with the measuring of multi-parameter to measure ECG, temperature, evoked potential, respiration rate which uses sensors to measure the patient condition continuously in ICU. For each parameter it uses separate sensors .this multi-channel parameter uses special type of sensors called infracted rays (IR) which are not harmful to human body. All this signals are collected from the patient's body then it is send to the computer and it is diagnosed by the doctor .It reduces the work for the doctors and it gives accurate values. If any abnormalities in the patient's body it produces alarm and it alerts the doctors. This paper also deals with online videography i.e the doctors can view the patient's condition anywhere from the hospital's. Results are stored in the secondary storage system in computer for future reference. the results are obtained in the form of graph, waveforms.
An Implementation of Embedded System in Patient Monitoring System
Fn2410141018
1. A.Lavanya, Sireesh Babu/ International Journal of Engineering Research and Applications
(IJERA) ISSN: 2248-9622 www.ijera.com
Vol. 2, Issue 4, July-August 2012, pp.1014-1018
Development of Heart Prescreening Device using low Power
MSP430 device
A.Lavanya*, Sireesh Babu**
*M.Tech student, ECE.Dept, PKSK college
**ASSOC.prof, ECE.Dept , PKSK college
Abstract-
Inventions are done keeping oppurtunities ratio is 3:10 000 and is highly biased toward urban
and expectations of developing economies in terms areas, thus creating a rural urban divide in cardiac
of health care. The designed system is a point-of- healthcare. The designed device also enables a
care (POC) device that can send heart-care paramedic to contribute significantly in rural
services to the rural areas and can install urban healthcare in case of unavailability of a trained
methodologies in healthcare delivery.The product physician, and in prescreening programs.
design uses several innovations including the
effective use of adaptive and multiresolution The presently available electronics
signal-processing techniques for acquisition, stethoscopes like HD Medical-HDfono and 3M
denoising, segmentation, and characterization of Stethos are aimed for educational and training
the heart sounds (HS) and murmurs using an purposes. In literature, reference of devices for
ultralow-power embedded Mixed Signal cardiac prescreening and diagnosis using HS are
Processor. The device is able to provide indicative rare.
diagnosis of cardiac conditions and classify a In the present study, we use a Texas
subject into either normal, abnormal, ischemic, or Instruments’ Mixed Signal Processor (TI-MSP
valvular abnormalities category. Preliminary results 430) based handheld device to innovate and
generated by the prototype states the applicability develop a Point-of-Care (POC) heart care and
of the device as a rescreening tool that can be used patient monitoring system that can be used for
by paramedics in rural outreach programs. It is also noninvasive cardiac screening. This system is
found from the feedback of medical proffessional utilized in determining human subjects susceptible
that they can helpful in determining congenital to cardiac ailments or showing early symptoms,
heart diseases. This system aims to determine a thus mitigating early diagnosis and enabling a
framework for utilization of automated HS analysis demographic study of cardiac cases. In future we
system for community healthcare and healthcare plan to integrate the system with Microsoft CE-
inclusion. SQL-based patient database management system
and haptic interfaces using Microsoft Windows CE
Index Terms—Adaptive signal processing, for easy operation.
biomedical signal processing, cardiovascular
system, data acquisition. II. SYSTEM ARCHITECTURE
Cardiology is a grand challenge in healthcare
I. INTRODUCTION and has inspired in envisioning the design concept
MEDICAL practitioners use cardiac with several intended benefits including low cost
auscultation for an objective clinical screening of semi real-time analysis of data, door to door
cardiac conditions and prediagnosis. It is, however, recording services enabled by mobile or
noted that a real-time system for the same is ultramobile devices, demographic data
conspicuously lacking in development. The prediagnostic input, and expert intervention in case
nonstationary nature of cardiac signals also makes of emergency through GSM/GPRS networks.
the generation of a robust system for heart sound
(HS) analysis difficult. Diagnosing heart diseases A. Target Specifications
using stethoscope and ECG are two fundamental Several technological innovations are built in
approaches due their efficiency, simplicity, and into the system prototype: 1) development based on
noninvasiveness [1]–[3]. HS auscultation highly ultralow-power embedded processors (TI-MSP
depends on the hearing ability, skill, and 430); 2) expert intervention of medical
experience of a cardiologist [1]. In real time, lung practitioners by remote monitoring at tertiary
sounds interfere with the HS making it noisy, healthcare centers; 3) the system incorporates state
which leads to increased difficulty in diagnosis of of the art-denoising algorithms suited for field use
heart diseases using signal-analysis techniques. An in the rural nonclinical setup; 4) the data analysis is
integrated HS analysis tool thus becomes vital to based on physiological considerations and medical
assist the cardiologist [2]. Study shows that in domain knowledge has been employed for
developing countries, cardiologist-to-population classifying the signal in four preliminary classes
1014 | P a g e
2. A.Lavanya, Sireesh Babu/ International Journal of Engineering Research and Applications
(IJERA) ISSN: 2248-9622 www.ijera.com
Vol. 2, Issue 4, July-August 2012, pp.1014-1018
that includes normal and three abnormal conditions
(see Fig. 1).
Finally, when the signal is fed into TI-
MSP430, it samples the analog input, applies the
signal-processing algorithms, and separates the HS
signal from the lung sound accordingly. The signal
is segmented for each beat and clustered based on
its frequency and temporal features.
B. Hardware Platform: TI-MSP 430 and Its
We aim to optimize the device capabilities Advantages in Embedded Applications
both in vivo and in vitro by making the design and The internal architecture of TI-MSP 430 comprises
development cycles flexible and adaptive. As of multiple analog and digitalmodules through
depicted in Fig. 2, TI-MSP430 is the heart of the which CPU can communicate with the external
system; it handles the role of data acquisition as interfaces and devices. Several features make the
well as signal processing for the input composite TI-MSP430 suitable for low-power and portable
signal. The preamplification unit consists of a low- applications. The CPU is small and efficient with a
pass filter (LPF) and high-pass filter (HPF) circuit. large number of registers. Several low-power
This LPF–HPF circuit in combination with the operating modes reduce power consumption and
amplification unit forms the signal conditioning extend battery life. There is a wide choice of
block that performs the primary filtering operation clocks: from the low-frequency watch crystal to
to delimit the unnecessary components of the input high-frequency digitally controlled oscillator
signal. It also amplifies the signal of interest to an (DCO). The hardware module provides RS232 and
extent so that it can be properly gated to the input RS485 for communicating with computer, audio
of TI-MSP430 [3]. It is, however, not able to inputs and outputs, switching applications, etc., to
deinterlace the overlapped heart and lungs sounds make the system versatile.
for which wavelet-based denoising is introduced in
the processing unit. Postamplification unit C. Hardware Implementation
comprises the signal conditioning block that The schematic of the system including the
performs the filtering operation to remove the steps for implementation of the algorithms has been
unnecessary region of the input signal and depicted in Fig. 3. The HPF-LPF circuit designed
amplifies the signal of interest. The in the present instrumentation consists of a 4th
signalprocessing algorithms are implemented on order Butterworth Low Pass Filter (cut-off ∼ 1000
the TI-MSP430 to minimize lung sounds, ambient Hz) and a 4th order Butterworth High Pass Filter
noise, and acoustical distortions. (cutoff ∼ 20 Hz). The Sallen-Key Topology is used
for filter design because of its inherent gain
accuracy. Moreover, Butterworth filter provides a
satisfactorily flat pass-band magnitude response
and attenuation of∼ −3 db at the cut-off frequency
(see Fig. 4).
The implementations of the algorithms are
carried out in the IAR workbench (V 5.4), using
1015 | P a g e
3. A.Lavanya, Sireesh Babu/ International Journal of Engineering Research and Applications
(IJERA) ISSN: 2248-9622 www.ijera.com
Vol. 2, Issue 4, July-August 2012, pp.1014-1018
“C” language given its simplicity and versatility in instead of being derived separately, consists of a
embedded programming. The programs are delayed version of the primary (input) signal. The
compiled in the TI-MSP430 IAR C/C++ compiler. delay is provided to decorrelate the noise signal so
Both A/D and D/A operations are performed in low that the adaptive filter (used as a linear prediction
power mode (LPM0) that draws a power∼ 95μA. filter) cannot predict the noise signal while easily
This feature of the program reduces the power predicting the signal of interest. Thus, the output
consumption at the time of A/D and D/A will contain only the signal of interests, which will
conversions. The CPU only commands over the be again subtracted from the desired signal and the
filtering program during which the TI-MSP430 error signal will then be used to adapt the filter
switches from low power mode to active mode (I ∼ weights to minimize the error.We implement the
600 μA). ALE model using the least mean square (LMS)
algorithm and the recursive least square (RLS)
algorithm.
B. Wavelet-Based Denoising
It is observed that orthogonal wavelet
transform compresses the energy in a signal into
few large components, whereas the noise is
disorderly and characterized by small coefficients
scattered throughout the transform. We can neglect
these smaller coefficients from the wavelet-
decomposed details, and thus, reduce the noise
[10]. In DWT, the energy content is concentrated in
larger wavelet coefficients from that we can easily
reconstruct back the original signal.
In the first stage of algorithm, all the
1) SureShrink: Sureshrink is a smoothness
proper settings for ADC, DAC and port 6 are
adaptive algorithm and works at multiple
initialized. The ADC process is established by
levels of wavelet decomposition and uses the
setting the ADC12SC bit. The sample values are
principle of Stain’s unbiased risk estimator
fed to the input of the filter algorithm. For faster
(SURE) for risk estimates [11]. For our
operation, the filtering process is executed with
application, we modified the SureShrink
high clock frequency. The filtered signal data is
algorithm and parameterized the equations to
accumulated in the DAC12_1 data register for D/A
reduce computational cost.
operation. The process continues iteratively, and
whenever a sample value comes to the input buffer
2) BayesShrink: BayesShrink is a wavelet
of the filter it modifies its array, performs filtering
shrinkage method that has emerged much
operation and channelizes the result to the
earlier and is outperformed by newer emergent
DAC12_1 data register. DAC output can be
techniques. The same is, however, included in
obtained at the port 6.6 pin and is been gated to the
the study because of its computational cost
LCD for visual inspection.
efficiency that make it better suited for fast
real-time and embedded operations.
III. SIGNAL DENOISING AND
SEGMENTATION C. Segmentation of HSs
There are severalsignal-processing The signals are decomposed to level 5
schemes requiring a separate noise reference for using Daubachis 6 (db6) wavelets. The detail
denoising of HS adaptively. This study is based on coefficients of levels 4, 5, and 6 are used for the
approaches where single channel is required for HS calculation of Shannon’s entropy. The subbands are
denoising. In designing the embedded device, we scaled and added up to give a partial
have used two classes of algorithms for denoising: reconstruction.
1) adaptive signalprocessing algorithms, and 2)
multiresolution signal processing using wavelets The normalized Shannon’s entropy is
[9]. calculated from the signal and is used to generate
the signal envelope. The same is then passed to a
peak detector. The subbands are scaled up and
A. Adaptive Line Enhancer added to give a partial reconstruction that amplifies
The adaptive line enhancer is a system that is the S1–S2 factors. In case we have a detected peak,
used frequently in biological signal processing to we pass on the data to a boundary-calculation
extract the desired biosignal from the background algorithm else recalculate the peak points by
wideband noise [4]–[8]. Its reference signal, readjusting the threshold adaptively. Other entropy
1016 | P a g e
4. A.Lavanya, Sireesh Babu/ International Journal of Engineering Research and Applications
(IJERA) ISSN: 2248-9622 www.ijera.com
Vol. 2, Issue 4, July-August 2012, pp.1014-1018
measures are being employed and evaluated of the HS and its temporal properties. The valvular
including fuzzy entropy, Kapur’s entropy, and disorders can be easily picked up by identifying the
approximate entropy measures. The measures for murmurs in the segmented HS. When concomitant
envelop detection presents an interesting ECG–PCG signal recordings are studied, we can
comparison, however, the same lies beyond the find the evidence of atrial fibrillation. Ischemic
scope of the present article (see Fig. 5). heart diseases can be diagnosed when there is an
early or late heart failure, S3 Gallop, or a loud P2
IV. PERFORMANCE EVALUATION (loud P2 often indicates a pulmonary
The data were acquired in situ using the hypertension); an atrial septal defect is indicated by
instrumentation designed. Total 72 samples were a split of second HS. Coronary stenosis is generally
obtained from 17 volunteers. The evaluation is known to produce sounds due to turbulent flow of
based on the comparison of the power spectral blood in the occluded arteries. Normally, the
density (PSD) of the signals both at the input of the sounds are masked and are not audible clearly
systems and the output of the systems for LMS- during the systolic phase but the same can be
ALE and RLS-ALE, and wavelet methods. picked up by precision sensors during the relatively
HSrecover and NOISE reduction are computed in quiet diastolic phase [5]. The extraction of useful
terms of percentages (see Table I) information from the diastolic sounds associated
with coronary occlusions using the adaptive signal-
processing algorithms and the use of clinical
examination variables can yield encouraging
results. The signals are highly attenuated and
complex so high precision microphones are
required to detect the sound signals. The feature
vectors extracted from the diastolic sounds
analyzed, in addition, other physical examination
variables like pulse rate, ambient/body temperature,
and patient details are registered using the system
that can be used by fuzzy and neural network
classifiers located at a remote server to validate the
results and minimize false detections.
The clustering of the systolic and the
diastolic segments are done with the help of K-
means algorithm♠ [12], where K = 2, a fuzzy
inference engine† is used to incorporate the data
from the other peripherals (see Table II for results).
The frequency features were determined with
where xHS (n) is the original HS, xhs noi (n) is reference to the S1 and S2 peaks determined using
theHS corrupted with noise signal, and y(n) is the the entropy plots (see Fig. 5).
output recovered signal after application of the
filtering techniques. It is evident that LMS and
BayesShrink algorithms are able to recover the HS
signal from wideband noisy background with
sufficient accuracy. However, the performance of
the SureShrink and RLS-ALE algorithm is much
better than the LMS-ALE and BayesShrink. The e-
General Medical and the Texas Heart Institute
online datasets were also employed for validation
of the methods using synthetically added white
Gaussian noise (see Fig. 6).
V. CLASSIFICATION AND ITS
CLINICAL SIGNIFICANCE
The system is designed to classify the signals
into: 1) abnormal and 2) normal classes at the
onset. The abnormal classes once screened are
further classified into: 1) valvular heart diseases
(VHD), 2) ischemic heart disease (IHD), and 3)
abnormal undetermined (AbU). The
subclassification is based on frequency signatures
1017 | P a g e
5. A.Lavanya, Sireesh Babu/ International Journal of Engineering Research and Applications
(IJERA) ISSN: 2248-9622 www.ijera.com
Vol. 2, Issue 4, July-August 2012, pp.1014-1018
[2] R. M. Rangayyan, Biomedical Signal
Analysis: A Case-Study Approach. New
York: IEEE Press/Wiley, 2002.
[3] L. Cromwell, F. J.Weibell, and E. A.
Pfeiffer, Biomedical Instrumentation
&Measurements, 2nd ed. Cromwell: Books,
1980.
[4] M. Kompis and E. Russi, “Adaptive heart-
noise reduction of lung sounds recorded by a
single microphone,” in Proc. 14th Ann. Int.
Conf. IEEE EMBS, 2003, pp. 2416–2419.
[5] Y. M. Akay, M. Akay, W. Welkowitz, J. L.
Semmlow, and J. B . Kostis, “Noninvasive
acoustical detection of coronary artery
disease: a comparative study of signal
processing methods,” IEEE Trans. Biomed.
Eng., vol. 40, no. 6, pp. 571–578, Jun. 1993.
[6] V. K. Iyer, P. A. Ramamoorthy, H. Fan, and
Y. Ploysongsang, “Reduction of heart
sounds from lung sounds by adaptive
filtering,” IEEE Trans. Biomed. Eng., vol.
33, no. 12, pp. 1141–1148, Dec. 1986.
The applicability of the system can further [7] L. J. Hadjileontiadis and S.M. Panas,
be extended to pediatric heart care and can be used “Adaptive reduction of heart sounds from
for early detection of ventricular septal defect lung sounds using fourth-order statistics,”
(VSD), bicuspid aortic valve disorders and patent IEEE Trans. Biomed. Eng., vol. 44, no. 7,
ductus arteriosus (PDA). As per statistics, 2–5 pp. 642–348, Jul. 1997.
children are detected with congenital heart defects [8] W. K. Ma, Y. T. Zhang, and F. S. Yang, “A
per 1000 live births. Hence, use of a noninvasive fast recursive-least-squares adaptive notch
and safe methodology, i.e., auscultation, for filter and its applications to biomedical
identification of these conditions can provide a signals,” in Medical and Biological Eng.
paradigm shift in pediatric and neonatal healthcare. Comput., Springer, vol. 37, no. 1, Jan. 1999.
[9] T. R. Reed,N. E. Reed, and P. Fritzson,
VI. CONCLUSION “Heart sound analysis for symptom
The presence of any abnormality in the detection and computer-aided diagnosis,”
subject’s heart alters the temporal domain signature Simul. Modeling Pract. Theory, vol. 12, pp.
of the HS, and accordingly, it can be sensed by the 129–146, 2004.
device. These latent changes in the signal are [10] D. L. Donoho and I.M. Johnstone,
monitored in a real-time basis after processing on “Adapting to unknown smoothness via
TI-MSP430. The system has a special color scheme wavelet shrinkage,” J. Amer. Statist. Assoc.,
to indicate a patient risk; further, a networked vol. 90, p. 1200, Dec. 1995.
cardiologist is alerted for any abnormalities in the [11] F. Luisier, T. Blu, and M. Unser, “A new
recorded HS. This system design facilitates the use SURE approach to image denoising:
as a POC device owing to its properties of Interscale orthonormalwavelet
portability and real-time operation. It is primarily thresholding,” IEEE Trans. Image Proc., vol.
aimed to identify the population suffering from 16, no. 3, pp. 593–606, Mar. 2007.
various heart ailments through sufficient screening [12] Z. Syed, D. Leeds, D. Curtis, F. Nesta, R. A.
enabling early detection leading to timely Levine, and J. Guttag, “A framework for the
diagnosis, and targeted remedial measures. The analysis of acoustical cardiac signals,” IEEE
methodology thus developed is the core technology Trans. Biomed. Eng., vol. 54, no. 4, pp.
for a rural heart care delivery and diagnosis system 651–662, Apr. 2007.
in form of an embedded handheld device, which
can be carried to the village households ensuring
sustainable healthcare delivery.
REFERENCES
[1] Morton E. Travel, “Cardiac auscultation: A
glorious past- but does it have a future?,”
Circulation, vol. 93, pp. 1250–1253, 1996.
1018 | P a g e