DE202006000119U1 - Finger ring physiological measuring assembly for e.g. heartbeat or oxyhaemaglobin has a housing around a detector and microprocessor - Google Patents

Abstract

A physiological measuring assembly consists of a finger ring with a housing (10) around a detector and microprocessor. The detector receives and processes signals arising from physiological measurements.

Description

The The invention relates to a physiological measuring device Operation, and in particular a measuring device, the ring-like design is, the meter mainly off one in a ring-like housing built-in measuring detector and in a ring-like housing built-in microprocessor, so that the measuring device according to the invention for Determining data from a physiological process can be used can.

conventional Measuring instruments for one physiological process, such. Pulse rate detector or oxyhemoglobin detector, are relatively big and not suitable for take away. Nowadays, many people realize that Fitness of the body important is. To keep fit or to become, many people do sports. But it is for Herzkarnke people very dangerous Doing sports without paying attention to certain physiological processes. These are training equipment developed, which are provided with a pulse rate detector, so that the users of the training equipment to improve their body condition their Monitor pulse rate can.

Conventional oxyhemoglobin detectors basically consist of a finger gauges detector and an analyzer to perform medical diagnostics, e.g. B. by measuring the arterial oxygen saturation (SaO ₂ ) in the blood for rapid detection of heart attacks, inter alia, diseases.

According to the state Three types of pulse rate detectors are known in the art. The The first type of pulse rate detector is an infrared sensor, which is the Blood circulation on the finger or earlobe can measure. The second Type of pulse rate detector is an electrocardiogram (ECG), the can measure the blood circulation in the hand area. The third kind of pulse rate detector is a chest electrocardiogram that records the pulse rate of the bloodstream can measure on the chest.

Of the Infrared sensor is the most widely used pulse rate detector. such Pulse-rate detectors are either in a hand-reachable one Form or formed in a wristwatch. When using puts the User points his finger to the glass window of the infrared sensor, with the infrared sensor counteracts the blood circulation, which is easy can be influenced by the pulse. This kind of infrared detector is very easily influenced by movement, whereby the result can not be measured accurately. Because the User constantly measuring his finger on the glass window of the Must put infrared sensor, This type of infrared sensor is very impractical for the user. The other type of infrared sensor has a earlobe worn on it measuring detector and an analyzer on, wherein the measuring detector connected by means of a cable to the built-in a training device analyzer is. In exercises on the training device However, the user is disturbed by the cable. In addition, this type of training device with infrared sensor not suitable for take away.

The second type of pulse rate detector is a cardiograph, the electric signal from the pulse rate and blood circulation at the hand area or best can measure on the chest. In general, this type of pulse rate detector Available in fitness clubs or gyms. When measuring, the user must two metal sheets with both hands touch or put on two fingers, so that the pulse rate detector can read the data of the physiological process. During the Measurement must the Users stand still and wait at least a few seconds. That is very impractical for the user.

The third type of heart rate monitor is a chest electrocardiogram that can measure the blood circulation in the chest. In 7 are an electrode belt 70 and a wristwatch 72 shown. The electrode belt 70 is worn on the chest of the user, the electrode belt 70 having an electrode-provided belt and a signal transmitter. The watch 72 has a signal receiver corresponding to the signal receiver. This type of chest electrocardiogram (Chest-electrode ECG system) has good accuracy. When measuring, the user must wear the electrode belt 70 and the wristwatch 72 wear at the same time. Because the electrode belt 70 must be worn directly on the skin, the electrode belt 70 very easily by electromagnetic waves, such. As mobile phones, television, computers, etc., are disturbed. Because these types of pulse rate detectors usually operate in the same frequency range as cell phones, the heart rate monitor signals could cause interference if one or more mobile phone users are near (about 80 cm or 2.5 feet). Elsewhere is the electrode belt 70 strapped around the chest, which is very uncomfortable for the user during the exercise.

The The object of the invention is to provide another measuring device for a to create physiological process that has the above disadvantages of usual Eliminated measuring instruments.

These The object is achieved by the device specified in claim 1; advantageous Further developments and refinements of the invention and their applications are given in the subclaims.

Thus, according to the invention proposed a measuring device, the ring-shaped housing, a measuring detector and a microprocessor and for detecting data a physiological process can be used.

Especially are in the annular housing formed a measuring detector and a microprocessor built in, so that the meter according to the invention For determining data from the physiological process can be used. The meter is from the user) on the finger, so that a physiological Receive signal from the measuring detector and can be forwarded to the microprocessor. Thus, the Data of the physiological process after processing by the Microprocessor are displayed.

embodiments The invention will be explained in more detail below with reference to the drawing. It demonstrate:

1 a perspective view of a measuring device according to the invention;

2 a rear view of the measuring device according to the invention 1 ;

3 a side view of the measuring device according to the invention 1 ;

4 a perspective side view of the measuring device according to the invention 1 showing that a light source is disposed on one of the two side parts of the housing;

5 a perspective side view of the measuring device according to the invention 1 showing that a light receiver is arranged on the other side part of the housing;

6 a schematic block diagram of the measuring device according to the invention;

7 a representation of the third type of conventional pulse-beat detector in use.

First, on the 1 to 5 Referenced. An embodiment according to the invention is shown. As can be seen from the figures, the measuring device according to the invention comprises a ring-like housing 10 , a push button 20 , a display device 30 , a power supply unit 40 , a measuring detector 50 and a microprocessor 60 ,

The housing 10 is ring-shaped and has a round top 12 and two curved and oppositely formed side parts 14 on, facing each other at the top 12 are arranged. The two side parts 14 are made of soft material, such. As rubber or plastic. Because the case 10 the measuring device according to the invention is designed as a normal ring, the meter can be easily worn by the (r) on the user's finger.

The housing 10 is at least with a push button 20 provided for switching on and off, starting, stopping or programming. According to the 4 and 5 is the measuring device according to the invention in this embodiment with two push buttons 20 provided on both sides of the side panels 14 and on opposite sides at the top 12 are arranged.

The display device 30 is on the case 10 appropriate. In this embodiment, the display device is 30 at the top 12 arranged.

The power supply unit 40 is in the case 10 built-in. In this embodiment, the power supply unit 40 in the shell 12 installed, the power supply unit 40 a lid 42 which is at the top 12 of the housing 10 the display device 30 opposite is attached.

The measuring detector 50 is in the case 10 built-in. In this embodiment, the measuring detector 50 in the side panels 14 of the housing 10 arranged. The measuring detector 50 is an infrared radiation detector. In this embodiment, the measuring detector 50 a light source 51 and a light receiver 53 on, being the light source 51 and the light receiver 53 opposite each other on the two side panels 14 are attached. The light source 51 can be an LED (Light Emitting Diode, LED). The light receiver 53 For example, it can convert light into electricity. The light source 51 and the light receiver 53 are, for example, a pair of light emitting diode and photo transistor (PN photo-transistor), wherein the measuring detector 50 may be a pulse rate detector or an oxyhemoglobin detector.

The light source 51 the pulse-beat detector can emit a wavelength of 940 nm infrared radiation while the light receiver 53 can receive the light signals and convert them into electrical signals. The light is emitted by an LED, passes through the finger and is then from the light receiver 53 receive. When the light radiation is sent into the tissue and passes through the finger, the light radiation is partially absorbed by the bone and tissue and reflected therefrom and partially transmitted and from the light receiver 53 receive. With the pulse beat, the blood quantity in the pulse artery is alternately changed, whereby also the of the light receiver 53 emp The amount of light commensurate with the rhythm of the pulse, which coincides with the heartbeat rhythm, changes, so that the pulse or heartbeat can be detected and displayed by appropriate signals.

The light source 51 From the oxyhemoglobin detector can emit a wavelength of 660 nm red radiation or 940 nm infrared radiation, wherein the light receiver 53 the light signals can be received and converted into the electrical signals. The blood is composed of the blood fluid (plasma) and the blood corpuscles, with 99% of the blood cells being erythrocytes. The color of the blood is based on the blood pigment (hemoglobin). As part of the bloodstream, the blood is used to transport 97% oxygen from the lungs into the tissues and leads waste products such as carbon dioxide and urinary substances from the tissues into the excretory organs (lungs or kidneys). At high oxygen pressure oxygen is deposited, hemoglobin becomes bright red oxyhemoglobin. At low oxygen pressure, this releases its oxygen and turns into dark red reduced hemoglobin. Here, the arterial oxygen saturation (SaO ₂ ) is brought to a simple formula. SaO ₂ = CHbO ₂ / (CHbO ₂ + CHb)

CHbO ₂ is the density of oxyhemoglobin, where CHb is the density of reduced hemoglobin. Arterial oxygen saturation (SaO ₂ ) is clearly measured on the basis of the different absorption spectra of CHbO ₂ and CHb. For measurement, the oxyhemoglobin detector sends the measuring detector 50 two wavelengths of light radiation into the tissue of the user, so that the different absorptions subjected light radiation partly to the AC component (AC, AC) and partly contribute to the DC component (DC, direct current). Due to the different absorption spectra of the red radiation and the infrared radiation, the densities of CHbO ₂ and CHb in the blood can be detected and measured. The microprocessor 60 For example, the signals obtained from the transmitted light of the two wavelengths undergoing different absorption and reflection can be processed into arterial oxygen saturation data.

In the 6 a block diagram of the measuring device according to the invention is shown. The measuring detector 50 has a transmission unit 52 a signal processing unit 54 and an analog-to-digital converter 56 on, the transmission unit 52 the information from the measuring detector 50 convert and to the signal processing unit 54 can forward. The signal processing unit 54 can process the edited data to the analog-to-digital converter 56 transmit the data electronically and on to the microprocessor 60 can forward.

The microprocessor 60 can from the measuring detector 50 processing received and forwarded data from the physiological process, so that the measuring device can be used for determining data of the physiological process. In this embodiment, the microprocessor includes 60 a driver unit 62 for switching the display device 30 is provided.

In use, the meter according to the invention is carried on the finger by the user. Will the push button 20 is pressed, the meter is turned on and the physiological signals from the measuring detector are received and passed on to the microprocessor. The data from the physiological process from the user is displayed by the processing of the microprocessor. The upper and lower limits of the pulse rate from the meter can be pre-programmed. When the pulse rate exceeds or falls below the upper and lower limits, respectively, the display device 30 displays a warning signal to the user. In addition, the meter has the function of a sports watch. It is very convenient for the user when exercising.

• 1. Das erfindungsgemäße Meßgerät ist relativ klein konstruiert und wird beim Benutzen von dem(r) Benutzerin) am Finger getragen, so dass das Meßgerät viel praktischer als herkömmliche Meßgeräte ist.
• 2. Das erfindungsgemäße Meßgerät ist ringartig ausgebildet und kann somit beim Benutzen von dem(r) Benutzerin) einfach am Finger getragen werden, so dass das Meßgerät viel praktischer zum Benutzen konstruiert ist.
• 3. Das erfindungsgemäße Meßgerät ist zimmlich klein konstruiert, so dass das Meßgerät zum Mitnehmen geeignet ist.
• 4. Das erfindungsgemäße Meßgerät ist ringartig ausgebildet. Der(ie) Benutzerin) kann das Meßgerät während der Übungen in die Tasche legen oder einfach am Finger tragen, ohne die Übungsfreiheit zu beeinträchtigen.
• 5. Das erfindungsgemäße Meßgerät wird beim Benutzen von dem(r) Benutzerin) am Finger getragen. Weil der Finger bei den Übungen nicht erschüttert wird, kann es die Daten vom physiologischen Vorgang besser als herkömmliche Meßgeräte ermitteln.
• 6. Das erfindungsgemäße Meßgerät ist relativ klein und sehr praktisch konstruiert, so dass das Meßgerät sehr bequem zu tragen ist.
• 7. Die obere und untere Grenzen der Pulsfrequenz vom erfindungsgemäßen Meßgerät können vorher programmiert werden. Wenn die Pulsfrequenz die obere bzw. untere Grenze über- bzw. unterschritten wird, zeigt die Anzeigevorrichtung 30 dem(er) Benutzerin) ein Warnsignal an. Dadurch ist das Meßgerät sehr praktisch für den(ie) Benutzerin) zur Beobachtung von seiner(ihrer) Körperkondition.
• 8. Das erfindungsgemäße Meßgerät weist die Funktion einer Sportuhr auf. Es ist sehr praktisch für den(ie) Benutzerin) beim Sporttreiben.
• 9. Das erfindungsgemäße Meßgerät ist kompakt konstruiert und weist keine Anschlußleitung oder Kabel auf, so dass das Meßgerät viel praktischer und besser als herkömmliche Meßgeräte in der Handhabung ist.
• 10. Mehrere Leute können gleichzeitig jeweils ein erfindungsgemäßes Meßgerät tragen, ohne dass sich die Funktion der jeweiligen erfindungsgemäßen Meßgeräte untereinander beeinträchtigen.

According to the above descriptions, the measuring device according to the invention has the following advantages for a physiological process

• 1. The measuring device according to the invention is constructed relatively small and is worn in the use of the (r) on the user's finger, so that the meter is much more practical than conventional measuring instruments.
• 2. The measuring device according to the invention is ring-shaped and thus can be easily worn on the finger when using by the user, so that the measuring device is constructed much more practical for use.
• 3. The measuring device according to the invention is designed zimlich small, so that the meter is suitable to take away.
• 4. The measuring device according to the invention is designed like a ring. The user may place the meter in the bag during exercise or simply wear it on the finger without impairing exercise freedom.
• 5. The measuring device according to the invention is worn on the finger when being used by the user. Because the finger is not shaken during the exercises, it can determine the data from the physiological process better than conventional measuring instruments.
• 6. The measuring device according to the invention is relatively small and constructed very practical, so that the meter is very comfortable to wear.
• 7. The upper and lower limits of the pulse rate of the meter according to the invention can be programmed in advance. When the pulse rate exceeds or falls below the upper and lower limits, respectively, the display device 30 displays a warning signal to the user. This makes the meter very convenient for the user to observe his (her) body condition.
• 8. The measuring device according to the invention has the function of a sports watch. It is very convenient for the user when exercising.
• 9. The measuring device according to the invention is compact in construction and has no connecting line or cable, so that the meter is much more practical and better than conventional measuring instruments in the handling.
• 10. Several people can simultaneously carry a measuring device according to the invention without the function of the respective measuring devices according to the invention interfering with one another.

The Application of the meter for a physiological process is versatile and the construction methods mentioned are only examples. Thus, the objects of the invention are achieved.

The The invention thus relates to a measuring device for a physiological process, and in particular a measuring device which is ring-shaped is, and built into a ring-like housing measuring detector and one in a ring-like housing built-in microprocessor, so that the meter according to the invention used to determine data from a physiological process can be. The meter is from the user) on the finger, whereby a physiological Signal from the measuring detector received and passed on to the microprocessor. Then be Data of physiological process of processing by Microprocessor displayed by this.

Claims (20)

Measuring instrument comprising a ring-like housing ( 10 ), a measuring detector ( 50 ) and a microprocessor ( 60 ), characterized in that the housing ( 10 ) is portable on the finger that the measuring detector ( 50 ) in the housing ( 10 ), wherein the measuring detector ( 50 ) for receiving signals is provided that the microprocessor ( 60 ) from the measuring detector ( 50 ) can process received and forwarded signals of a physiological process, so that the measuring device can be used for determining data of the physiological process. Measuring device according to claim 1, characterized in that the measuring detector ( 50 ) a light source ( 51 ) and a light receiver ( 53 ) having. Measuring instrument according to claim 2, characterized in that the light source ( 51 ) an LED (light-emitting diode) and the light receiver ( 53 ) is a photo transistor. Measuring device according to claim 2, characterized in that the measuring detector ( 50 ) is an infrared radiation detector. Measuring device according to claim 2, characterized in that the measuring detector ( 50 ) is a pulse rate detector or an oxyhemoglobin detector. Measuring device according to claim 5, characterized in that the measuring detector ( 50 ) is an oxyhemoglobin detector that can emit light of two wavelengths so that the microprocessor ( 60 ) can process the signals obtained from the transmitted light of the two wavelengths to data of the arterial oxygen saturation. Measuring device according to claim 6, characterized in that one of the two from the oxyhemoglobin detector emitted wavelengths a 660 nm red radiation is while the other wavelength one 940 nm infrared radiation is. Measuring device according to claim 5, characterized in that the measuring detector ( 50 ) is a pulse-rate detector that can emit light of a wavelength, and that the microprocessor ( 60 ) can process the signals received from the transmitted light of one wavelength to data of the frequency of the pulse. Measuring device according to claim 8, characterized in that emitted by the pulse-beat detector wavelength a 940 nm infrared radiation is. Measuring device according to claim 8, characterized in that the meter has the function of a sports watch having. Measuring device according to claim 8, characterized in that the upper and lower limits of the frequency the pulse on the meter before can be programmed. Measuring instrument according to one of claims 1 to 11, characterized in that the housing ( 10 ) of the measuring instrument is a top ( 12 ) and two side parts ( 14 ), wherein the light source ( 51 ) and the light receiver ( 53 ) of the measuring detector ( 50 ) in the side parts ( 14 ) are installed. Measuring instrument according to claim 12, characterized in that the upper part ( 12 ) is formed round, wherein the two side parts ( 14 ) are bent and facing each other at the top ( 12 ) are mounted. Measuring device according to claim 12, characterized in that the housing ( 10 ) of the measuring instrument at least one push button ( 20 ) having. Measuring instrument according to claim 14, characterized in that the housing ( 10 ) of the meter two pushbuttons ( 20 ), which are opposite to each other at the top ( 12 ) are mounted. Measuring device according to claim 12, characterized in that the measuring device is a display device ( 30 ), which on the housing ( 10 ) is attached. Measuring instrument according to claim 16, characterized in that the display device ( 30 ) at the top ( 12 ) of the housing ( 10 ) and that the microprocessor ( 60 ) one for driving the display device ( 30 ) provided driver unit ( 62 ) having. Measuring device according to Claim 12, characterized in that the measuring device has a power supply unit ( 40 ) having. Measuring device according to claim 18, characterized in that the power supply unit ( 40 ) in the upper part ( 12 ) of the housing ( 10 ), wherein the power supply unit ( 40 ) a lid ( 42 ), which at the upper part ( 12 ) of the housing ( 10 ) of the display device ( 30 ) is mounted opposite one another. Measuring device according to Claim 1, characterized in that the measuring device has a transmission unit ( 52 ), a signal processing unit ( 54 ) and an analog-to-digital converter ( 56 ), wherein the transmission unit ( 52 ) the information from the measuring detector ( 50 ) and to the signal processing unit ( 54 ) that the signal processing unit ( 54 ) the processed data to the analog-to-digital converter ( 56 ), so that the analog-to-digital converter ( 56 ) convert the data electronically and on to the microprocessor ( 60 ).