NL1024860C2 - System is for recording electrical signals occurring in living body and has at least two electrodes for obtaining first analogue signal corresponding with electrical signal occurring in living body - Google Patents

Abstract

The system (1) is for recording electrical signals occurring in a living body and has at least two electrodes (2a,2b) for obtaining a first analogue signal corresponding with an electrical signal occurring in a living body. An analogue/digital convertor receives a second analogue signal corresponding with the first such signal and converts the second analogue signal into a digital signal. A microvolt in the first analogue signal corresponds with a microvolt in the second analogue signal and the analogue/digital conversion unit carries out at least one 18 bits analogue/digital conversion. The system has a micro-controller (5) and a feed (4) for control of the electrodes.

Description

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Title: A system and method for registering electrical signals that occur in a living body.

The invention relates to a system for recording electrical signals occurring in a living body, the device comprising: at least two electrodes for obtaining a first analog signal corresponding to an electrical signal occurring in the living body ; and an analog / digital (A / D) conversion device that is adapted to receive a second analog signal corresponding to the first analog signal and to convert the second analog signal into a digital signal.

Such a system is known per se from practice and is often used in determining, for example, brain activity.

Electrical signals that occur in brains have a magnitude of the order of microvolts. In order to be able to adequately analyze such signals, these signals must be provided. To this end, the known system is equipped with an analog amplifier which amplifies the first analog signal for the purpose of obtaining the second analog signal which is subsequently fed into the A / D conversion device for conversion to a digital signal. Such an amplifier is often at least an analog amplifier capable of amplifying by a factor of 500-1000. A problem is that the required amplifiers are very expensive. 25 The following applies: the higher the required gain, the more expensive the amplifier. The purchase and use of such a known system is therefore only reserved to a few. As a result, the system often finds application only in the medical world where the necessity of purchasing and using these costly systems is required. Another problem is that amplifiers can introduce noise into the second analog signal, which can make analyzing the signal more difficult.

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It is an object of the invention to provide a system which from a functional point of view at least corresponds to the known system but can be implemented more cheaply.

This object of the invention has been achieved with a system according to the invention which is characterized in that a microvolt in the first analog signal is substantially similar to a microvolt in the second analog signal and the A / D conversion device is arranged for outputting of at least an 18 bit AID conversion.

No expensive amplifier 10 is required with a system according to the invention. After all, the AID conversion device in a system according to the invention is sufficiently capable of effectively "amplifying" the second analog signal when converting to a digital signal such that the signal can be processed and / or analyzed by interested parties.

After all, 18 bits correspond to 56,000 image lines. One image line then corresponds to 1 millivolt. This sensitivity is already sufficient, for example, for an ElectroCardioGram (ECG) application. It is noted that the conversion proceeds very accurately and that any bits that clearly have nothing to do with the signal can easily be removed. This provides a well-digitized signal. Preferably, it holds that the A / D conversion device is adapted to perform at least a 20-bit A / D conversion. In this case it is possible to reliably quantify ElectroEncephaloGram (EEG) signals. Such an A / D conversion device is nowadays much cheaper than an analog amplifier as used in the known systems and therefore it is possible to design the system according to the invention much cheaper than the known system. This makes it possible to use such systems in many other environments and for other purposes than in medical and medical purposes respectively. In this context, one may think, for example, of studying sport and learning processes in more detail with the aid of registering electrical signals occurring during sport and learning processes in the body. Furthermore, with the fact that the analog amplifier is superfluous, the source of noise associated with the analog amplifier has become eliminable. This allows higher quality and purer signals to be obtained.

Furthermore, conditioning of the signal can take place digitally (for example in the PC). Analog filters and the like are not required. Generally, the input range of such an A / D conversion device of a system according to the invention is relatively large, in the order of 2.5 Volts. This offers the advantage that the A / D conversion device does not become saturated quickly. This allows reliable quantification of DC offsets.

In a special embodiment, it holds that the second signal is un-amplified relative to the first signal. In this case, certainly no expensive amplifier is required, at most a very cheap amplifier that compensates for loss of the strength of the signal during the formation of the second signal from the first signal due to a certain form of signal transmission.

It may even be the case that the second signal is attenuated relative to the first signal. This can for instance take place during the formation of the second signal from the first signal by a certain form of signal transmission. The signal does not have to undergo a serious attenuation so that the use of, for example, an 18, 24, 28 or 32-bit A / D converter can still be sufficient for further processing of the signal.

Preferably, it holds that the A / D conversion device is adapted to perform a 24-bit, 28-bit or even a 32-bit A / D conversion.

Here, the higher the number of bits, the stronger the amplification of the signal that can be carried out by the A / D converter during the conversion of the second analog signal to the digital signal.

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The invention will now be explained with reference to a drawing. It shows:

Figure 1 shows diagrammatically a first embodiment of a system according to the invention.

Figure 1 shows a system 1 for recording electrical signals that occur in a living body. System 1 is provided with at least two electrodes 2a, 2b for obtaining a first analog signal that corresponds to an electrical signal occurring in the living body. The system 1 is also provided with an analog / digital (A / D) conversion device which is adapted to receive a second analog signal corresponding to the first analog signal and to convert the second analog signal into a digital signal. In use, the electrodes will each be arranged spaced apart against or substantially against a living body from which electrical signals must be obtained. Upon the occurrence of an electrical signal in that living body (not shown), a first analog signal based on that electrical signal will be generated in the living body with the aid of the electrodes. The electrodes 2a, 2b send this first analog signal to the A / D converter. This can for instance take place in that the electrodes 2a are connected to the A / D conversion device 3 by means of an electrically conductive wire. Thus, the electrode 2b can also be connected to the A / D conversion means by means of an electrically conductive wire. device 3. However, it is also possible that, in an alternative variant, the electrodes are adapted to wirelessly send the first analog signal to the A / D conversion device 3. In practice, the A / D conversion device receives a second analog signal corresponding to the first analog signal. In the system according to the invention, it holds that one microvolt in the first analog signal substantially corresponds to one microvolt in the second analog signal. Furthermore, it holds that the A / D conversion device is adapted to perform at least one 18-bit A / D conversion. It is possible that the second signal is un-amplified relative to the first signal. The second signal may optionally be slightly attenuated relative to the first signal.

Preferably, the system furthermore comprises a circuit controller 5 and 5 and a power supply 4, for example for controlling the electrodes 2a, 2b when use is made of active electrodes. We will come back to this later. The microcontroller 5 can also be adapted to analyze a digital signal that is fed to the microcontroller in use from the A / D converter. Furthermore, it preferably applies that the system 1 is provided with a screen (not shown) for displaying a digital signal corresponding to the electrical signal occurring in the body. When an 18-bit A / D conversion device is used, 256,000 image lines are formed. An image line can then correspond to 1 millivolt. It is also possible that the 15 A / D conversion device is arranged to perform at least a 20-bit, 24-bit, or 28-bit A / D conversion. Even a 32-bit A / D conversion is not excluded. When an 18-bit converter is used, the sensitivity is good enough to obtain an electrocardiogram (ECG) suitable for analysis using the system according to the invention. When the system according to the invention comprises a 20-bit A / D conversion device, it is possible to obtain an electroencephalogram (EEG) obtained therewith and to be able to quantify it reliably. With a 24-bit, 28-bit, or even a 32-bit A / D conversion device, a gain occurring during the conversion can be much more favorable, which can also lead to other applications.

The system may be provided with a processing device, not shown for processing a digital signal corresponding to the electrical signal occurring in the body. The processing device can optionally be included in the A / D conversion device 3 or vice versa. It is also possible that the processing device is included in the microcontroller or vice versa. As already stated, the system can be adapted to wirelessly transform the first analog signal into the second analog signal. It is also possible that the signal is transmitted wirelessly from the AID conversion device 3 to a processing device (not shown) or to a screen, also not shown. The display and the processing device can of course form one integrated whole. The display, the processing device and the AID conversion device can thus also form an integrated whole. The system can further be arranged for determining physiological signals and processing these physiological signals in conjunction with the electrical signals occurring in the body.

It is furthermore possible that the system comprises at least three electrodes, namely 2a, 2b and 2c. In this way a much purer image can be obtained of electrical signals occurring in the living body. For example, it is possible to place the electrodes 2a and 2b against the head and to place the electrodes 2c against, for example, an ear lobe. The electrodes 2a and 2b register a signal that is provided with a lot of noise. However, this noise can also be measured with electrodes 2c. It is then possible to filter the noise from the signal obtained with the help of the electrodes 2a and 2b by using the signal obtained with the help of the electrodes 2c. Electrode 2c is also referred to as reference electrode. Although it is possible that the two electrodes 2a, 2b are passive, it holds that the two electrodes 2a, 2b are preferably active. For example, the microcontroller 5 can exert a stabilizing effect on obtaining the first analog signal. To this end, in use, the microcontroller 5 controls the power supply 4. The power supply 4 can also be connected to the AID conversion device for supplying electrical energy. In that case the power supply will usually receive at least one transformer. Such an activation of measuring electrodes is known per se. It is also possible that the power supply 4 is connected to the electrodes 2a, 2b without the power supply 4 being supported by the microcontroller 5.

The system can be accommodated in hardly striking clothing. In this way, possibly during normal functioning, an image can be obtained of the electrical signals occurring in the living body. The electrodes can for instance be incorporated in a hair band. The first analog signal can optionally be wirelessly transformed into the second analog signal.

Use is preferably made of AID conversion devices which do not comprise an instrumentation amplifier at the input. An A / D conversion device with such an instrumentation amplifier free input for receiving the second analog signal has a sufficiently high CMMR (Common mode correction), and is less expensive than an AID conversion device with an instrumentation amplifier at the input.

The invention is in no way limited to the exemplary embodiment shown. For example, it is possible that many more electrodes than shown are arranged for transmitting a first analog signal to the AID converter which receives a second analog signal corresponding to the first analog signal.

It is also possible that the system is provided with a video and / or audio device for respectively being able to combine visual observations in the behavior of a person and / or being able to combine sounds or statements produced by a person, with electrical signals occurring in the body, for example the brain of the person.

Such embodiments are each understood to fall within the framework of the invention.

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Claims (15)

What is claimed is: 1. A system for recording electrical signals occurring in a living body, the system comprising: at least two electrodes for obtaining a first analog signal corresponding to an electrical signal occurring in the living body; and an analog / digital (A / D) conversion device which is adapted to receive a second analog signal corresponding to the first analog signal and to convert the second analog signal into a digital signal, characterized in that a microvolt in the first analog signal substantially corresponds to a microvolt in the second analog signal and the A / D conversion device is arranged to perform at least an 18-bit A / D conversion. A system according to claim 1, characterized in that the second signal is un-amplified relative to the first signal. A system according to claims 1 and 2, characterized in that the second signal is attenuated relative to the first signal. A system according to claim 1, 2 or 3, characterized in that the A / D conversion device is arranged for performing at least one 20-bit A / D conversion. A system according to any one of the preceding claims, characterized in that the A / D conversion device is adapted to perform at least a 24-bit A / D conversion. 6. A system according to any one of the preceding claims, characterized in that the A / D conversion device is arranged for performing at least a 28-bit A / D conversion. A system according to any one of the preceding claims, characterized in that the system comprises at least three electrodes. 102 48 60 A system according to claim 7, characterized in that two electrodes are passive and one electrode comprises a reference electrode. A system according to claim 7, characterized in that two electrodes are active and one electrode comprises a reference electrode. 5 A system according to any one of the preceding claims, characterized in that the system further comprises a microcontroller for controlling the electrodes. 11. System as claimed in any of the foregoing claims, characterized in that the system is further provided with a screen for displaying a digital signal corresponding to the electrical signal occurring in the body. 12. A system according to any one of the preceding claims, characterized in that the system is furthermore provided with processing device for processing a digital signal corresponding to the electrical signal occurring in the body. A system according to any one of the preceding claims, characterized in that the system is adapted to wirelessly transform the first signal into the second signal. A system according to any one of the preceding claims, characterized in that the system is also adapted to determine physiological signals and to process these signals in conjunction with the electrical signals occurring in the body Method for recording electrical signals occurring in a living body, the method comprising: obtaining a first analog signal with at least two electrodes corresponding to an electrical signal occurring in the living body; receiving a second analog signal corresponding to the first analog signal with the aid of an analog / digital (A / D) conversion device; 1024860 ♦ and converting the second analog signal into a digital signal with the aid of the analog / digital (A / D) conversion device, characterized in that a microvolt in the first analog signal substantially corresponds to a microvolt in the second analog signal and that converting the second analog signal into a digital signal comprises at least an 18-bit A / D conversion. 1024860