Source: https://patents.google.com/patent/WO2017158237A1/en
Timestamp: 2018-10-23 16:38:20
Document Index: 647655834

Matched Legal Cases: ['art 7', 'art 7', 'art 7', 'art 7', 'art 7', 'art 7', 'art 7', 'art 13', 'arts 26', 'art 26', 'art 30', 'art 34', 'art 7', 'art 7', 'art 13', 'art 7', 'art 13', 'art 13', 'art 7', 'art 13', 'art 7', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13', 'art 13']

WO2017158237A1 - Mobile device for measuring electrical biosignals - Google Patents
Mobile device for measuring electrical biosignals Download PDF
WO2017158237A1
WO2017158237A1 PCT/FI2017/050168 FI2017050168W WO2017158237A1 WO 2017158237 A1 WO2017158237 A1 WO 2017158237A1 FI 2017050168 W FI2017050168 W FI 2017050168W WO 2017158237 A1 WO2017158237 A1 WO 2017158237A1
PCT/FI2017/050168
A mobile device (1) for measuring at least one electrical biosignal. The device (1) comprises a first input (4) and a second input (5), a measuring circuit part (7) for providing an output signal indicating the electrical biosignal to be measured, the measuring circuit part (7) comprising a first input (8) and a second input (9), and a charging circuit part (13) for charging a rechargeable battery (3) inserted in the device (1), the charging circuit part (13) comprising a first input (14) and a second input (15). The first input (8) of the measuring circuit part (7) and the first input (14) of the charging circuit part (13) are connected to the first input (4) of the mobile device (1) and the second input (9) of the measuring circuit part (7) and the second input (15) of the charging circuit part (13) are connected to the second input (5) of the mobile device (1).
The present invention relates to a mobile device for measuring at least one electrical biosignal. BACKGROUND OF THE INVENTION
The mobile heart rate monitoring device or the mobile electrocardiogram device often has a rechargeable battery that is recharged through pins or a connector such as micro USB connector. In many devices a battery charger may be connected to the device while using the device. However, a faulty battery charger may then expose the user of the device to line voltages through the ECG contacts unless costly line isolation circuitry is used. Usage of the device during charging can also be prevented with a circuitry that detects if the device is connected to a charger and resets the microcontroller or powers down the electronics while connected to the charger. However, this alone does not prevent charging of the device while connected to human body. BRIEF DESCRIPTION OF THE INVENTION
The invention is characterized by the features of the independent claims. A mobile device for measuring at least one electrical biosignal comprises a first input and a second input, a measuring circuit part for providing an output signal indicating the electrical biosignal to be measured and comprising a first input and a second input as well as a charging circuit part for charging a re- chargeable battery inserted in the device, the charging circuit part comprising a first input and a second input. Further in the mobile device the first input of the measuring circuit part and the first input of the charging circuit part are connected to the first input of the mobile device and the second input of the measuring circuit part and the second input of the charging circuit part are connected to the second input of the mobile device.
In the mobile device disclosed there are common inputs both for measuring the electrical biosignal to be measured and for recharging the battery of the mobile device. This means that charging of the battery of the mobile device may be easily prevented at the same time when the mobile device is in active op- eration and measuring the electrical biosignal of the user of the device, because either a measurement operation or a charging operation may be in use at a time. Thereby a possibly faulty battery charger device may not expose the user of the mobile device to line voltages through the measurement electrode contacts. The number of physical ports or contacts of the mobile device is also minimized, whereby system costs are reduced and immunity of the mobile device to humid or wet conditions is increased, since ports or contacts penetrating a device cover increase a risk to short circuits and failure to water leakages.
Some embodiments of the invention are disclosed in dependent claims. In an embodiment an additional circuitry is used that detects if the de- vice is connected to a charger and resets or powers down a microcontroller or a microprocessor of the device during recharging. This gives additional safety by preventing running of a measurement algorithm while the device is connected to the battery charger device. An additional benefit is that a reset action without additional pins or switches is provided in case normal operation of the micropro- cessor is for some reason disturbed during usage. Such reasons can be, e.g., electrical shocks, processor malfunction or firmware bugs that cause the algorithm to halt.
The mobile device 1 may for example be a heart rate monitor for measuring a heart rate of a user of the device 1, in which case the electrical bio- signal to be measured describes the heart rate of the user of the device 1. Alternatively the mobile device 1 may be a mobile electrocardiogram device for measuring an electrocardiogram (EKG) of the user of the device 1, in which case the electrical biosignal to be measured describes the electrical activity of the heart of the user of the device 1. Alternatively the mobile device 1 may be a mobile electro- myogram device for measuring an electromyogram (EMG) of the user of the device 1, in which case the electrical biosignal to be measured describes the electrical activity of muscles of the user of the device 1. Alternatively the mobile device 1 may be a mobile electroencephalogram device for measuring an electroencephalogram (EEG) of the user of the device 1, in which case the electrical biosignal to be measured describes the electrical activity of the brain of the user of the device 1. In addition, the mobile device may detect any electrical functions of the body, for example the electrical activity of organs such as eye, stomach, liver etc. The mobile device may also be used for measuring the electrical properties of the body,e.g. the bioimpedance of the body. The signals describing the electrical activ- ities of the organs or the electrical properties of the body are also electrical bio- signals that may be measured with the device 1.
It is also possible to use the device, instead of measuring a biosignal, to drive an electrical signal to the body to activate the neural or muscular system, through, e.g., transcutaneous electrical nerve stimulation - TENS, functional elec- trical stimulation - FES, or electrical muscle stimulation - EMS.
Alternatively to the devices and the electrical biosignals to be measured as listed above, the mobile device 1 may be intended to measure some other electrical biosignal or electrical properties of the user of the device 1. In the following description disclosing some embodiments of the mobile device 1, it is as- sumed that the mobile device 1 is intended to measure the electrocardiogram (EKG) of the user of the device 1.
The internal circuit 2 comprises a first input 4 being a first input 4 of the mobile device 1. In the embodiments disclosed the first input 4 is a positive input 4. The voltage level in the first input 4 may be five volts when a battery charger device 26 is connected to the mobile device 1, for example. The internal circuit 2 comprises also a second input 5 being a second input 5 of the mobile de- vice 1. In the embodiments disclosed the second input 5 is a negative input 5 or a lower voltage level input 5, i.e. an input connected to a lower voltage level in the mobile device 1. The second input 5 may thus be grounded, in which case the voltage level in the second input 5 is zero volt. Alternatively the second input 5 may be a virtual ground input having a voltage level less than the voltage level in the first input 4. According to an embodiment the voltage level in the second input 5 is 1 - 4 volts for example. The internal circuit 2 further comprises a measurement signal output 6, through which a measurement signal indicating the electrical biosignal to be measured is supplied to an analog-to-digital converter and via a radio communication circuitry out of the mobile device 1 for further analysis and/or representa- tion. The analog-to-digital conventer is shown schematically with a box denoted with a reference sign 38a and the radio communication circuitry is shown schematically with a box denoted with a reference sign 38b.
The internal circuit 2 comprises a measuring circuit part 7 for retrieving the signal indicating the electrical biosignal to be measured. The measure- ment signal describing the electrical biosignal to be measured is connected by the wearable sensor module 18 which is attached to the user of the device 1 to the mobile device 1 as described later in more detail. The measuring circuit part 7 comprises a first input 8 and a second input 9. The first input 8 of the measuring circuit part 7 is connected to the first input 4 of the mobile device 1, and the sec- ond input 9 of the measuring circuit part 7 is connected to the second input 5 of the mobile device 1. The measuring circuit part 7 thus receives through the inputs 4, 5 of the internal circuit 2 an electrical signal from the wearable sensor module 18 connected to the mobile device 1, which electrical signal contains, possibly together with many other unrelated signals and measurement noise, a signal por- tion that describes the electrical biosignal to be measured.
The measuring circuit part 7 of Figures 2 and 3 comprises a measurement filter 10 and an amplifier 11 connected in series with the measurement filter 10. The measurement filter 10 is a circuit that retrieves the signal portion, i.e. in a case of the electrocardiogram measurement the electrocardiogram signal, actually describing or indicating only the electrical biosignal from the measurement signal received from the wearable sensor module 18 through the inputs 4, 5 of the internal circuit 3, which measurement signal may also contain noise or other unrelated signal portions. The amplifier 11 amplifies the signal retrieved by the measurement filter 10 for an analog-to-digital conversion and to a transmission of the retrieved signal out of the mobile device 1. The digital signal may be transmitted out of the mobile device 1 via a wired transmission but preferably wire- lessly using local area network or Bluetooth radio.
The configuration of the measuring circuit part 7 may vary from that disclosed in Figures 2 and 3 depending on the electrical biosignal to be measured, for example. The internal circuit 2 of the mobile device 1 also comprises a charging circuit part 13 having parts 26a, 30 and 34 for recharging the rechargeable battery 3 of the mobile device 1. According to an embodiment, part 26a is a battery charging chip, e.g. MAX1555, part 30 is a switching element that may be a me- chanical or solid-state switch but preferably a P-channel MOSFET transistor, part 34 is a diode.The charging circuit part 7 comprises a first input 14 and a second input 15.
In the mobile device 1 disclosed above the first input 8 of the measuring circuit part 7 and the first input 14 of the charging circuit part 13 are both connected to the first input 4 of the mobile device 1, and the second input 9 of the measuring circuit part 7 and the second input 15 of the charging circuit part 13 are connected to the same second input 5 of the mobile device 1. To be more precise, in the embodiments disclosed the first input 14 of the charging circuit part 13 is combined with the first input 8 of the measuring circuit part 7, that are con- nected together to the first input 4 of the mobile device 1, and the second input 15 of the charging circuit part 13 is combined with the second input 9 of the measuring circuit part 7, that are connected together to the first input 4 of the mobile device 1.
For actually connecting the mobile device 1 to the wearable sensor module 18 and to the battery charger device 26 the mobile device 1 comprises a first connector element 16 connected to the first input 4 of the internal circuit 2 and a second connector element 17 connected to the second input 5 of the inter- nal circuit 2 of the mobile device 1. The first 16 and the second 17 connector elements in the device 1 connect the device 1 both mechanically and electrically to the wearable sensor module 18 and the battery charger device 26 through counterpart connector elements in the wearable sensor module 18 and the battery charger device 26. The wearable sensor module 18 and the battery charger device 26 are described shortly next with reference to Figure 1.
The wearable sensor module 18 comprises a first measuring electrode 19 and a second measuring electrode 20 that are brought into contact with a skin of the user of the mobile device 1. The wearable sensor module 18 of Figure 1 comprises a strap 21 to which the measuring electrodes 19, 20 are attached to, and the strap 21 is to be put around a body of the user of the mobile device 1 by using a band 21a. Instead of the strap 21 a shirt, a cap or other piece of clothing could also provide a foundation for the measuring electrodes 19, 20. The wearable sensor module 18 further comprises a first connector element 22 to which the first measuring electrode 19 is connected through a first signal line 24 and a second connector element 23 to which the second measuring electrode 20 is connected through a second signal line 25.
The battery charger device 26 comprises a plug 27 through which the battery charger device 26 may be connected to a power supply for recharging the battery 3 in the mobile device 1. In the embodiment of the battery charger device 26 of Figure 1 the plug 27 is a USB-port plug which may be connected to a USB- port in a portable computer, for example. Other kind of battery charger devices, like the ones comprising a voltage transformer, may also be applied. The battery charger device 26 further comprises a first connector element 28 and a second connector element 29 through which the battery charger device 26 may be connected to the mobile device 1.
When the battery 3 of the mobile device 1 is to be recharged, the mobile device 1 is unfastened from the wearable sensor module 18 and the first con- nector element 16 of the mobile device 1 is connected to the first connector element 28 of the battery charger device 26 and the second connector element 17 of the mobile device 1 is connected to the second connector element 29 of the battery charger device 26. The connection between the connector elements 16, 17 in the mobile device 1 and the connector elements 28, 29 in the battery charger de- vice 26 provide both the mechanical and the electrical connection between the mobile device 1 and the battery charger device 26. After the battery 3 of the mobile device 1 is recharged, the mobile device 1 is unfastened from the battery charger device 26 and the mobile device 1 may be started to use again.
As stated above, the mobile device 1 disclosed comprises common in- puts both for measuring the signal describing or containing a signal indicating the electrical biosignal to be measured and for recharging the battery of the mobile device.
This means firstly, that charging of the mobile device 1 may be easily prevented at the same time when the mobile device 1 is connected to the weara- ble sensor module 18, i.e. the charging of the mobile device 1 is prevented at the same time when the mobile device 1 is in operation and measuring the electrical biosignal of the user of the device 1, because either a measurement operation or a charging operation may be in use at a time. Thereby a possibly faulty battery charger device may not expose the user of the mobile device 1 to line voltages through the measurement electrode contacts.
As stated above, the connector elements 16, 17 in the mobile device 1 and the connector elements 22, 23 in the wearable sensor module 18 or the connector elements 28, 29 in the battery charger device 26 provide both the mechanical and the electrical connection between the mobile device 1 and the wearable sensor module 18 or the battery charger device 26. That kind of connection may be implemented for example with snap fasteners. The connector elements 16 and 17 can also be part of a single electromechanical connector that snaps on a re- ceptable connector in the wearable sensor module 18 and the battery charger device 26. The connectors in mobile device 1 and the wearable sensor module 18 can have a multitude of other connector elements for connecting to other sensor elements in the wearable sensor module 18, e.g. to other ECG electrodes or to a temperature sensor. The connector elements 28 and 29 may likewise be incorporated in a single connector to which the connector in mobile device 1 is attached.
Referring to Figure 2 again, the charging circuit part 13 of the mobile device 1 comprises a switching element 30 that is connected both to the first sig- nal input 4 of the mobile device 1 and to the second signal input 5 of the mobile device 1. The switching element 30 detects a presence of the battery charger device 26 whereby the switching element 30 is configured to switch the charging circuit part 13 on a low-impedance on-state for charging the battery 3 of the mobile device 1. When the battery charger device 26 is removed from the mobile device 1, the switching element 30 is configured to switch the charging circuit part 13 back to a high-impedance off-state for the measurement of the at least one electrical biosignal.
When the battery charger device 26 is connected to the mobile device 1, the battery charger device 26 will thus be connected between the switching element 30 and the diode 34 in the charging circuit part 13, whereby the switch- ing element 34 activates and allows a charging current flow in the charging circuit part 13 and the battery 3 is started to be recharged. When the battery charger device 26 is disconnected from the mobile device 1, the switching element 30 deactivates and a current flow in the charging circuit part 13 is prevented. The switching element 30 thus provides a kind of a detection circuit which automatically detects whether a battery charger device 26 is connected to the mobile de- vice 1 or not and correspondingly either allows or disallows a current flow in the charging circuit part 13.
When the battery charger device 26 is connected to the mobile device 1 the transistor 37 switches to the low-impedance on-state for allowing a current flow in the charging circuit part 13. When the battery charger device 26 is disconnected from the mobile device 1 the transistor 3 switches back to the high- impedance off-state for preventing the current flow in the charging circuit part 13.
Switching element may be a mechanical or solid-state relay controlled by a microprocessor of the mobile device 1. In this embodiment, the input of a voltage comparator is connected to the input 4 of the mobile device 1. The output of the voltage comparator is given to the microprocessor. When the battery charger device 26 is connected to the mobile device 1, the voltage comparator detects that the input 4 of the mobile device 1 is at a high charging voltage and supplies a signal to the processor that closes the switching element 30 and a charging current flows onto the battery charging chip 26a. When the mobile de- vice 1 is measuring the electrical biosignal, the voltage comparator detects that the voltage level of the input 4 of the mobile device 1 is low and thereby the processor opens the switching element 30.
1. A mobile device (1) for measuring at least one electrical biosignal, the device (1) comprising
a measuring circuit part (7) for providing an output signal indicating the electrical biosignal to be measured, the measuring circuit part (7) comprising a first input (8) and a second input (9),
a charging circuit part (13) for charging a rechargeable battery (3) inserted in the device (1), the charging circuit part (13) comprising a first input
(14) and a second input (15), c h a r a c t e r i z e d in that
the mobile device (1) comprises a first input (4) and a second input
(5), and that
the first input (14) of the charging circuit part (13) is combined with the first input (8) of the measuring circuit part (7), the first input (8) of the measuring circuit part (7) and the first input (14) of the charging circuit part (13) be- ing connected to the first input (4) of the mobile device (1), and the second input
(15) of the charging circuit (13) part is combined with the second input (9) of the measuring circuit part (7), the second input (9) of the measuring circuit part (7) and the second input (15) of the charging circuit part (13) being connected to the second input (5) of the mobile device (1), and that
the charging circuit part (13) comprises a switching element (30) for switching the charging circuit part (13) to a low-impedance on-state for charging the rechargeable battery (3) inserted in the mobile device (1) and to a high- impedance off-state for the measurement of the at least one electrical biosignal.
2. A mobile device as claimed in claim 1, c h a r a c t e r i z e d in that the measuring circuit part (7) comprises a measurement filter (10) for retrieving an output signal indicating the electrical biosignal to be measured and an amplifier (11) for amplifying the retrieved signal indicating the electrical biosignal to be measured.
3. A mobile device as claimed in claim 1, c h a r a c t e r i z e d in that the switching element (30) is a transistor (37), whereby a source (S) of the transistor (37) is connected to a first input (4) of the mobile device (1), a gate (G) of the transistor (37) is connected to the second input (5) of the mobile device (1) and a drain (D)of the transistor (37) is connectable to a current supply for charging the rechargeable battery (3), the transistor (37) switching to the low- impedance on-state in response to the current supply being connected to the mo- bile device (1).
4. A mobile device as claimed in any one of the preceding claims, c h a r a c t e r i z e d in that
the mobile device (1) comprises a first connector element (16) con- nected to the first input (4) of the mobile device (1) and a second connector element (17) connected to the second input (5) of the mobile device (1), the first connector element (16) and the second connector element (17) configured to provide both a mechanical and an electrical connection between the mobile device (1) and a wearable sensor module (18) or a battery charger device (26) con- nectable to the mobile device (1).
5. A mobile device as claimed in any one of the preceding claims, c h a r a c t e r i z e d in that the mobile device (1) comprises a microcontroller (40) arranged to execute a firmware arranged to control operations in the mobile device (1), and that the charging circuit part (13) is arranged to provide a reset signal (39) the state of which is arranged to change when the mobile device (1) is connected to a battery charger device (26), the reset signal (39) being used to reset and/or stop the microcontroller (40).
6. A mobile device as claimed in claim 5, c h a r a c t e r i z e d in that the reset signal (39) is realized by using an element, such as a MOSFET transistor, arranged to sense a state of a signal that is arranged to activate in response to the battery charger device (26) being connected to the mobile device (1), thus activating the reset signal (39) to reset and/or stop the microcontroller (40).
7. A mobile device as claimed in any one of the preceding claims, c h a r a c t e r i z e d in that the mobile device (1) is at least one of the follow- ing: a heart rate monitor for measuring a heart rate, an electrocardiogram device for measuring an electrocardiogram (EKG), an electromyogram device for measuring an electromyogram (EMG), an electroencephalogram device for measuring an electroencephalogram (EEG).
8. A wearable sensor module (18) connectable to the mobile device (1) as claimed in any one of claims 1 to 7, the wearable sensor module (18) comprising
at least one pair of measurement electrodes (19, 20) for measuring a signal describing at least one electrical biosignal to be measured, and
a first connector element (22) and a second connector element (23) connectable to the first (16) and the second (17) connector elements of the mobile device (1) for connecting the wearable sensor module (18) both mechanically and electrically to the mobile device (1).
9. A battery charger device (26) connectable to the mobile device (1) as claimed in any one of claims 1 to 7, the battery charger device (26) comprising a first connector element (28) and a second connector element (29) connectable to the first (16) and the second (17) connector elements of the mobile device (1) for connecting the battery charger device (26) both mechanically and electrically to the mobile device (1).
10. Use of a mobile device (1) as claimed in any one of claims 1 - 7 to drive an electrical signal to a body of a user of the device (1) to activate a neural or muscular system or to measure electrical properties.
PCT/FI2017/050168 2016-03-15 2017-03-14 Mobile device for measuring electrical biosignals WO2017158237A1 (en)
FI20165214 2016-03-15
WO2017158237A1 true true WO2017158237A1 (en) 2017-09-21
US20150364018A1 (en) * 2014-06-13 2015-12-17 Google Inc. Multipurpose contacts for delivering electro-haptic feedback to a wearer
FI127038B (en) 2017-10-13 application