PL233729B1 - Method for the broadcast transmission for the Bluetooth Low Energy transmitters - Google Patents

Description

The present invention relates to a broadcast transmission method for Bluetooth Low Energy transmitters, which is mainly used in the study of locomotive movements, sports or monitoring vital functions during sleep.

Monitoring systems using teletransmission are increasingly used. The rapid development of such solutions can also be noticed on the market of mobile devices. Monitoring the body parameters introduces a new quality of life and allows you to react quickly, for example in health or life-threatening situations. The use of radio interfaces is, however, directly related to their energy demand. In the case of using mobile devices or designing battery-powered teletransmission systems, the current consumption related to the process of sending and receiving data is important, therefore it is desirable to develop new transmission methods, thanks to which it will be possible to reduce the energy demand of the device, extend the device's operation and at the same time increase the durability of the cells supply.

Methods for transmitting information and data are known from the prior art.

Among others, from the patent description PL175102 a solution is known which uses grouping of receivers in order to receive service information. The information is transmitted on the carrier signal in time frames that are divided into time intervals. In turn, groups of receivers are assigned to time intervals. Time intervals are used to synchronize many devices during operation. This method does not allow the transmission of additional information.

From the patent description PL181627 it is known a solution that uses a video signal to transmit additional data on television channels. Although the invention allows for the transmission of additional data, it requires the introduction of additional hardware infrastructure in relation to the standard hardware base by means of which the transmission is carried out. The method of transmission also does not allow for energy savings for the transmitter.

From the patent description PL180677 a solution is known which uses binary strings in order to transmit the identification number. The transmission method for radiotelephony systems uses BCD coding of the identification number, and the resulting binary string is processed with the Hagelbarger code. The method of transmission requires a synchronization sequence and allows neither the transmission of additional information nor energy savings during transmission.

From the patent description PL182269 there is known a solution that uses a telecommunications network for transmission between adapters. The method performs the transmission of information between a digital adapter connected to the telecommunications network switch via a digital interface, in particular via an ISDN type digital interface, and an analog adapter connected to the telecommunication network switch via an analog interface. This method, due to the infrastructure used, does not take into account radio transmission, sending additional information, or energy savings during the transmission process.

From the patent description PL183088 it is known a solution that uses digitally encoded radio signals, which in addition to the information part also include a protocol-related part. The transmission of the information part begins before the processing of the radio signal portion relating to the protocol, during this processing, possibly simultaneously therewith. In addition, information transmission is performed with single bits, and each information bit is assigned a frequency bundle. This method of transmission does not take into account the transmission of additional information or energy savings during the transmission process.

From the patent description PL188864 there is known a solution which uses the delay of the transmission of audiovisual information in order to transmit digital television information. The method uses a predetermined and introduced delay time for the transmission of the audiovisual information broadcast on each of the channels, whereby a real-time event message relating to broadcasting a live event program on at least one channel is introduced into the data stream of at least one other channel. channel. The introduced delay in information transmission does not allow for energy savings during the transmission process.

The solutions known from the prior art enable the transmission of various types of information and data, however, they do not allow the simultaneous transmission of additional information and saving the energy necessary for the transmission process.

Discrete transmission has been used in computer technology for many years. The data is fragmented and transmitted as such. Among mobile devices, Wi-Fi and Bluetooth radio interfaces are particularly popular, which perform discrete transmission in the aforementioned manner.

PL 233 729 B1

The transmission of data contained in standardized frames ensures high transfer, security and enables the use of effective teletransmission methods. Pulse transmission in broadcast mode is particularly energy-efficient. A radio transmitter configured in this way is referred to as a Beacon. The energy efficiency of such systems is due to the fact that they do not transmit continuously, but with a defined time interval. The amount of data that can be transmitted with this method is related to the frequency of transmission of the broadcast frames. This method is usually used to transmit the permanent identifier of the transmitting device, but the transmitted data can be modified, which allows for the transmission of additional information. Then, the amount of data that can be transmitted is related to the transmission frequency of the broadcast frames. Thus, by limiting the number of transmission cycles per time unit, energy savings can be achieved, thanks to which the radio interface will function effectively in battery-powered systems. Additionally, when transmitting in broadcast mode - (called advertising in the Bluetooth Low Energy specification) - there is no need to perform authentication procedures between the transmitter and the receiver, which simplifies the transmission format and reduces the amount of energy needed for it. Especially BLE (Bluetooth Low Energy) technology is characterized by reduced energy demand. With the use of modern BLE interfaces during transmission, the current consumption is usually from a few to a dozen or so. With the appropriate configuration of the BLE interface, its continuous operation is possible even in years. A broadcast in the Bluetooth Low Energy (BLE) standard is usually used to transmit a permanent identifier of the transmitting device. The amount of data sent in broadcast frames is significantly limited, however, by using the method of the present invention, the amount of information transmitted during transmission can be significantly increased while maintaining or even reducing power consumption. Moreover, the method according to the invention also enables data related to variable information to be stored in broadcast frames.

The aim of the present invention is to develop a broadcast transmission method for Bluetooth Low Energy transmitters, which will allow the transmission of additional information, for example, about the monitored body functions without the need to modify the standard transmission frame and the computing power requirement. At the same time, the method is to enable saving the energy necessary for broadcasting, which will allow its use, in particular, in battery-powered devices.

The essence of the invention is a broadcast transmission method for Bluetooth Low Energy transmitters, especially in devices that monitor the body's locomotor functions and / or respiratory function and / or pulse, whereby a Bluetooth Low Energy radio transmitter block configured to transmit broadcast frames is capable of transmitting broadcast frames with variable intervals between broadcast frames compliant with the Bluetooth Low Energy standard, where broadcast frames are transmitted only for defined values in a sequence of consecutive digital values that form a binary string representing the input signal of the transmitter block and each digital value corresponds to the discrete time value, and then using a Bluetooth Low Energy radio receiver block, broadcast frames are received and the interframe intervals are measured, and then discrete time values representing the information are determined in the receiver block, the discrete values being time is determined by summing the last computed discrete time value and the last measured interframe interval, the first discrete time value being set as zero.

Preferably, transmission of broadcast frames is performed by a transmitter block comprising a radio module and a microcontroller block with at least one microcontroller.

Preferably, receiving the broadcast frames and determining the discrete time values representing the information are performed by a receiver block comprising a radio module and a microcontroller block with at least one microcontroller.

Preferably, the measurements of the interframe intervals and the determination of discrete time values representing the information are performed in at least one microcontroller of the radio receiver microcontroller block.

Preferably, before transmitting a broadcast frame, the broadcast data section of that frame is filled with binary data and the so filled frame is transmitted to the receiver block.

The method according to the invention uses broadcast transmission for Bluetooth Low Energy (BLE) devices, which allows to send and receive information also without the need to read in the device.

The contents of the data section of a frame are downlinked. This method does not result directly from the specification of the Bluetooth standard, because in this standard the transmission and reading of information are only related to the data sent in transmission frames.

The solution according to the invention has a number of advantages over the solutions known from the prior art:

- saving the energy necessary for the transmission process which results from the broadcast mode of the transmitter operation; impulse data transmission allows for significant energy savings, because it is discreetly collected for individual transmission cycles,

- the possibility of implementation in IoT applications - Internet of Things, thanks to the use of the transmitter in the BLE standard,

- simplified detection of organism functions, obtained thanks to the configuration of the transmitter to send frames with a variable transmission interval, which reflects the frequency of occurrence of the monitored organism functions; so in the receiver it is enough to receive individual frames and measure the time between them to recreate the frequency of this organism function,

- the ability to monitor the functions of organisms simultaneously on many receivers, including mobile devices; configuration of the BLE transmitter for broadcast mode allows for simultaneous reception of frames transmitted by it by many receivers,

- the ability to monitor several body functions at the same time; configuring the transmitter to a mode in which the variable transmission interval represents the frequency of occurrence of one of the organism functions being monitored, allowing the parameters of another organism function to be recorded as transmission frame data; in this way, one frame carries information about, for example, two functions of the body, which additionally allows you to save energy spent on transmission,

- open topology of the sensor network; thanks to the use of broadcast (connectionless) transmission, it is not limited to the standard Bluetooth topology, i.e. piconet or scatternet; it is possible to monitor bodily functions in multiple transceiver configurations, for example, one-to-one, one-to-many, many-to-one, and many-to-many; In the method according to the invention, there are no specific restrictions on the number of simultaneously used transmitters and receivers.

The method according to the invention will be explained in more detail on the basis of the drawing, in which Fig. 1 shows the principle of standard broadcast transmission with a fixed interframe interval, Fig. 2 - generalized BLE frame structure, Fig. 3 - simplified block diagram of the system for monitoring body functions, Fig. 4 - practical example of a system using variable interframe interval transmission, fig. 5 - example of broadcast with variable interframe intervals, fig. 6 - generalized block diagram of a system for monitoring body functions using transmission with variable interframe intervals, fig. 7 - visualization of the monitoring method of the bioelectric signal of the heart, fig. 8 - visualization of the method of monitoring gait cycles, fig. 9 - visualization of the method of simultaneous monitoring of respiratory activity and heart rate, fig. 10 an exemplary configuration of the system using transmission with variable interframe intervals with a single transmitter Fig. 11 - example configuration of a system using variable interframe transmission with multiple transmitters and one receiver, Fig. 12 - example configuration of a system using variable interframe transmission with multiple transmitters and a different number of measuring blocks and one receiver, fig. 13 - an example configuration of a system using transmission with variable interframe intervals with many transmitters and many receivers.

The presented method of broadcast transmission will be related to the hardware configurations on which it has been tested. These configurations also apply to the examples presented below.

Fig. 3 shows the general structure of a system using the broadcast transmission method. Block 9 is in practice a fully functional measuring system with an integrated sensor block containing sensors 7, analog and / or digital, and signal processing and conditioning circuits 8 (amplifiers, analog or digital filters, microcontrollers, DSP processors, etc.)

Output 90 propagates electrical signals representing information about a particular function of the body. Fig. 6 shows the generalized structure of the system for monitoring the body functions. In this system, several blocks 9 can be connected to the inputs 101 of the microcontroller block 10 in the form of a hardware communication interface and / or at least one general-purpose port and / or at least one analog input. Block 9 in the simplest case may be an analog or digital integrated circuit. sensor of the monitored body functions.

The output 90 of block 9 is connected to input 101 of microcontroller block 10, which is also input of transmitter block 12. Output 100 of microcontroller block 10 is connected to input 111 of radio module 11 (RF). In practice, the output 100 of the microcontroller unit 10 and the input 111 of the radio module 11 is the control interface lines radio module, such as SPI, I ² C, 1wire, UART like. The output 110 of the radio module 11 is attached to the transmitting antenna 120.

The radio module (or modules) 11 of the transmitter block (or blocks) 12 transmits the signals to the corresponding receiver block 12a, which comprises a radio module 11a configured as a receiver, and the microcontroller block 10a.

A receiving antenna 120a is connected to the input 111a of the radio module 11a. The output 110a of the receiver 11 is connected to input 101a of microcontroller unit 10a, whereas in practice, the output 110a of the receiver 11 and the entrance 101a of the microcontroller unit 10a is a low cost radio module control interface, such as SPI, I ² C, 1wire, UART like.

In the case of the transmitter block 12 and the receiver block 12a implemented on the basis of integrated circuits, the microcontroller block 10 and the radio module 11 are connected by an internal bus as well as the radio module 11a and the microcontroller block 10a.

The microcontroller block 10a of the receiver block 12a allows the use of available general purpose ports or communication interfaces as outputs 100a to external devices, modules, measurement systems, messaging and alarm systems, other radio or wired network structures, etc. The microcontroller block 10a therefore functions as an operation control system. the radio interface, processes the received signals, and transmits via the output 100a the signals to external modules, for example a display (LCD, OLED, etc.), an acoustic (e.g. piezo) and / or optical indicator (e.g. a LED). In practical applications, the antenna 120a, the radio module 11a, and the microcontroller block 10a are components of the receiver block 12a. The output 100a of the microcontroller block 10a can also act as a control and communication interface with external systems and support various standards, similar to the inputs of the microcontroller block 10a. Another variant of the receiver block 12a can also be receivers built into mobile devices, for example a smartphone, smartwatch, smartband, tablet, laptop, desktop computer with a radio interface (with Bluetooth version 4 or higher), etc.

For a more precise description of the method according to the invention and to demonstrate its practical application, examples will be presented below.

Fig. 1 of the drawing shows a characteristic visualizing the standard transmission of a BLE transmitter in the broadcast mode. The individual frames are sent in transmission cycles 1 consisting of several pulses, usually lasting several milliseconds in total. In accordance with the Bluetooth Low Energy standard, transmission frames are transmitted with a defined, constant time interval 2. During the transmission process, the current consumed by the transmitter increases rapidly (pulses), therefore in Fig. 1 the frame transmission is presented as a cycle of current pulses on the radio module power supply. In Fig. 1, the interval between the individual transmission cycles is 0.3 s.

The inventive method described in the following examples uses the GAP (Generic Access Profile) of the BLE transmitter. Within the GAP profile, the transmitter block functions as a Peripheral, transmitting broadcast frames 3. These frames have a format compatible with broadcast frames as defined in the Bluetooth Core 4.2 specification. The frame type is set to connectionless (non-connectable) and not capable of sending a request for additional data (scanrequest), specified in the specification as ADV_NONCONN_IND. In accordance with the Bluetooth Core 4.2 specification, the data section 4 of the broadcast frame 3 contains thirty-one bytes of data that can be modified, the examples using the Bluetooth Low Energy protocol stack implemented by the chip manufacturer, which allows the bytes of the modifiable section 6 of the broadcast data 4 to be changed. while the preceding section 5 should be configured according to the manufacturer's recommendations. This is due to the fact that by default, the possibility to configure the broadcast transmission is provided with the use of a broadcast frame 3, the data section of which

The broadcast 4 is adapted to an iBeacon data format, which is not specified in the Bluetooth Core 4.2 specification. The transmission interval 2a between the frames is determined on the basis of the measurements taken and is not constant but depends on the monitored body function. This makes it possible to map the measurements to the receiving device only on the basis of the reception time of the next broadcast frame. Changing the broadcast data transmission interval exceeds the Bluetooth Core 4.2 specification, which states that the connectionless transmission interval is fixed and ranges from 100 ms to 10.24 s. Transmitted frames, however, can still be received by any compatible devices. this specification, if the format of the broadcast frame is 3. In some cases, this frame may not contain additional data, since the information related to the mere fact of receiving the frame is sufficient to represent the monitored body function. The frame only needs to have the header and address as specified in the Bluetooth Core 4.2 specification, and the broadcast data 4 need not be specified.

The receiver block 12a, like the transmitter block 12, uses the GAP profile. Within this profile, receiver block 12a acts as a central device. The receiver block 12a is configured in an observer mode which allows the radio module 11a to receive broadcast frames 3. This mode is defined in the Bluetooth Core 4.2 specification. The receiver, by means of the microcontroller block 10a, enables the mapping of monitored / monitored functions, in particular body functions, by analyzing the time between receiving successive frames and, optionally, also by analyzing the data placed in the frame.

P r z k ł a d 1

This example describes a broadcast transmission method for the Blue tooth Low Energy transmitters used in the respiratory cycle monitoring system. In order to visualize the method, in the example, Fig. 5 shows the characteristics representing the body function monitoring signal 13, in this case the respiratory function, compared to the current consumption of the BLE module during the transmission cycles 1 in which broadcast frames 3 are sent. in the microcontroller block 10, it is converted into a sequence of consecutive digital values constituting a binary string. Each broadcast frame 3 is sent when the next exhalation begins. The detection of the first low state indicating the beginning of the respiratory cycle in the example is the defined value 13a over the sequence of the numerical values constituting the binary sequence. Since respiratory activity is characterized by a variable time between individual respiratory cycles, also broadcasting is performed as the analogous, variable transmission interval 2a. The variable transmission interval in this case represents the respiratory rate. The broadcast frames 3 transmitted by the radio module 11 of the transmitter block 12 are then received by the radio module 11a of the receiver block 12a, in which the interframe intervals 2a are measured, which means that the time between successive received frames is measured in the microcontroller block 10a. Thereafter, discrete time values 15 representing the information are determined, the discrete time values 15 being determined by summing the last computed discrete time value 15 and the last measured interframe interval 2a, with the first discrete time value being set to zero. In this example, the broadcast frame was not populated with data.

A system that uses the method according to the invention described in the first example is presented in Fig. 4. The system generating negative capacitance at the input terminals, acting as a conditioning and processing system 8, together with a microcondensation sensor 7 connected to its input 81, form the generator system 9. The generator system in the discussed In this example, it acts as a measuring block 9, which at its output 90 generates a signal for monitoring the body's functions 13, in the present case a square wave signal with a variable frequency depending on the respiratory phase. The square wave signal is generated by the occurrence of respiratory activity, therefore it is easy to distinguish between the individual cycles. The transmitter block 12 was implemented in an integrated form, which means that the output 100 of the microcontroller block 10 and the input 111 of the radio module 11 were connected by an internal bus. A transmitting antenna 120 is connected to the output of the radio module 11. The receiver unit 12a was also integrated as an integral part. A receiving antenna 120a is connected to the input 111a of the radio module 11a. The output 110a of the radio module 11a is connected to the input 101a of the microcontroller block 10a via an internal bus. The output 100a of the receiver block 12a is implemented as a UART interface.

PL 233 729 B1

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As a second example of a broadcast transmission method for Bluetooth Low Energy transmitters, the method used in the heart cycle monitoring system is presented. In order to visualize the method, the example in Fig. 7 shows the co-recorded curves of the bioelectrical activity of the heart (U) and the current (I) supplying the radio module 11. In the example discussed, the microcontroller block 10 of the transmitter block 12 is configured such that the detection of the maximum signal on its input 101 13 representing the QRS wave of the bioelectric heart rate, starts the procedure of broadcasting a broadcast frame 3 with variable intervals 2a between frames.

The signal of the body function 13 in the microcontroller block 10 is converted into a sequence of successive digital values constituting a binary string. The maximum QRS wave in the present example is the defined value 13a over the sequence of consecutive digital values constituting the binary sequence. The time between the individual heartbeats thus determines the transmission interval 2a between successive transmissions of the broadcast frames 3. The increased, pulsed current consumption of the radio transmitter indicates the transmission process. In the example discussed, the mere receipt of a broadcast mode frame informs about the occurrence of the heart cycle, while the time between the reception of successive frames indicates the heart rate - in this way, for example, the pulse can be monitored. At a Bluetooth Low Energy radio receiver block 12a, broadcast frames 3 are received and the interframe intervals 2a are measured, and then discrete time values 15 representing the information are determined, discrete time values 15 being determined by summing the last computed discrete time value 15 and the last measured interframe interval 2a.

The receiver block 12a is limited to merely receiving the transmission frames and measuring the interval between successive frames, without the need to read any data contained in the broadcast data section 4 of these frames. In the present example, the pulse frequency is reconstructed from the interframe intervals 2a measured in the microcontroller block 10a. On this basis, the information is reconstructed, which are the discrete values of the reception time of the broadcast frames 3.

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The third example also relates to the use of the method according to the invention for monitoring the bioelectrical activity of the heart, however, the method utilizes both the control of the transmission process by means of a bodily function monitoring signal, and the transmitted broadcast frames contain additional data related to the monitored function. In the modifiable section 6 of the broadcast data 4, up to 24 bytes are recorded in each of the frames. These data reflect the monitored electrocardiogram curve 13. Sampling was carried out in the transmitter block 12 at the analog input 101 of the microcontroller block 10 every 0.05 s, obtaining a sequence of successive digital values forming a binary sequence. The selected sampling time and the amount of broadcast data 4 of the broadcast frame 3 used allows for a lossless mapping of the bioelectrical activity of the heart. The value of each sample is represented by one byte and written successively to the modified broadcast data section 6 of the frame 4. Taking into account the fact that successive heartbeat cycles occur at irregular intervals of about 1 second, about 20 additional samples are transmitted in each sent frame. The frames are transmitted by the radio module 11 of the transmitter block 12 similarly to the previous example, i.e. after detection at the input 101 of the microcontroller block 10 of the maximum signal representing the QRS wave of the bioelectric heart function. The maximum QRS wave in the present example is the defined value 13a over the sequence of consecutive digital values constituting the binary sequence. In the present example, the pulse frequency is reconstructed from the interframe intervals 2a measured in the microcontroller block 10a. On this basis, information is reconstructed, which are the discrete values of the time of receipt of broadcasting frames 3. The bioelectric heart function curve is reconstructed after reading the data contained in successive bytes of received broadcast frames, taking into account the signal sampling time as a constant value 13. For this purpose, successively the values of the sampling time constant in the receiver block and reconstruct the discrete time values which correspond to the digital values of the numbers read from the individual bytes of the modifiable section 6 of the broadcast data 4 of the broadcast frame 3. In both the second and third examples, the measuring block 9 contained a differential amplifier INA128 in the circuit three-electrode, and analog filters. Output 90 of measuring block 9 is connected to analog input 101 of microcontroller block 10.

PL 233 729 B1

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Another example relates to the use of the method according to the invention to monitor gait cycles. To visualize the method of the present example, Fig. 8 shows the concurrently recorded curves that represent the data from the Y axis of the accelerometer (Ampl. Y) and the current consumption (I) by the transmitter block 12, indicating transmission of the frames. Broadcast frames 3 are transmitted only for defined values 13a in a series of consecutive digital values forming a binary string representing the input signal 13 of the transmitter block 12. The defined value 13a refers to the moment of contact of the heel (on which the sensor 7 is mounted) with the ground, which is shown in the curve Ampl.Y it is represented by a large change in amplitude, both positive and negative, and therefore the change is relatively easy to detect. In the discussed example, in Fig. 8, a characteristic feature of the information transmission method according to the invention can be seen, namely the first frame was sent only after detecting the first contact of the heel with the ground, i.e. after detecting the defined value 13a (in Fig. 8 marked with a broken line) in a series of successive values. for more than 4 seconds. For more than the initial three seconds, the monitored person stood freely, so the gait cycles were not implemented and the radio module 11 did not transmit broadcast frames 3. In Fig. 8, the area in which, based on the microcontroller block, 10 measurements of the organism monitoring signal 13, frame transmission is not performed, marked as 14. Then, by means of a Bluetooth Low Energy radio receiver block 12a, broadcast frames 3 are received and the interframe intervals 2a are measured, and then discrete time values 15 are determined in the receiver block 12a representing information. The contact frequency of the foot (heel) with the ground is reproduced on the basis of the interframe intervals 2a measured by the microcontroller block 10a. On this basis, information is reconstructed, which is the discrete values of the reception time of broadcasting frames 3. In the discussed case, the measuring block 9 was realized in the form of a digital multi-axis accelerometer, the output 90 and input 101 of the microcontroller block 10 constituted the I2C interface. Two separate transmitters 12 are used, each with a single measurement block 9 as shown in Fig. 12. The system also includes a single receiver block 12a embedded in the mobile device - smartphone. The transmitter block 12 together with the measurement block 9 is placed on the limbs of the monitored person, which allows the recording of signals analogous to that presented in Fig. 8, but separately for each limb.

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This example demonstrates the inventive method for monitoring respiration and pulse simultaneously. An example will be discussed on the basis of the curves shown in Fig. 9. In addition, for a precise description of the method in the example, a system which uses the method according to the invention and the measurement procedure will first be described. The measuring block 9 was implemented in the form of a digital multi-axis accelerometer, the output 90 and input 101 of the microcontroller block 10 constituted the I ² C interface. The accelerometer was placed on the abdominal wall of the monitored person (about 2 cm below the xiphoid process of the sternum), which shows oscillations of different frequency. Breathing causes slow-varying vibrations of the abdominal wall (frequencies usually below 1 Hz), while the heart rate causes quick-varying vibrations of smaller amplitude. The accelerometer measures both oscillations simultaneously, which are visible on the Ampl.A curve. This curve presents unscaled, dimensionless data recorded from the accelerometer as a function of time.

In the microcontroller block 10, the Ampl.A curve is converted into a sequence of consecutive digital values constituting a binary string. Accelerometer data filtration in microcontroller block 10 allows for the separation of the respiratory and pulse signals. The transmission of broadcasting frames is controlled on the basis of a pulse signal (higher frequency vibrations of the abdominal wall caused by the work of the heart). Broadcast frames 3 are transmitted only for the defined values 13a in the sequence of consecutive digital values constituting the binary string representing the input signal 13. The microcontroller block 10 is configured so that after detecting the peaks of each heart rate cycle (defined value 13a in the sequence of digital values making the binary string) , initiated the frame transmission, which is marked with the circle symbols on the Ampl.P curve. Prior to sending each frame, the microcontroller block 10 performs a sampling of the slow breathing curve approximately every 0.1 s and then fills the modifiable section 6 of the broadcast data 4 of the frame with single byte values of the slow curve samples before sending the frame. Therefore, at each heart rate cycle, depending on the frequency of its work, several to several dozen samples will be sent in one

On the basis of which a curve of slowly changing respiratory process is recreated. Breathing is represented by the Ampl.O curve. This curve presents filtered, uncalculated, dimensionless data recorded from the accelerometer as a function of time. By means of a Bluetooth Low Energy radio receiver block 12a, broadcast frames 3 are received and the interframe intervals 2a are measured, and then discrete time values 15 representing the information are determined in the receiver block 12a. Thus, in the discussed example, the pulse is monitored thanks to the detection of broadcast frames (the information that is the discrete values of the reception time of the broadcast frames 3 is reconstructed), while the respiratory functions are monitored thanks to the integration of data contained in subsequent such frames in the receiver block 12a. In this way, using the meager resources of the broadcast mode, it is possible to monitor, for example, two body functions during the transmission of one type of data.

The method according to the invention can in practice be used to transmit information in systems of various configurations. Transmitted broadcast frames from one transmitter block 12 may be received by multiple receiver blocks 12a, including those embedded in mobile devices simultaneously. A variant with one transmitter block and multiple receiver blocks is shown in Fig. 10. A variant with two transmitter blocks and a different number of measuring blocks 9 is shown in Fig. 11 in turn. Several systems for monitoring different body functions or the same type of function, but different persons transmit, via their transmitter blocks 12, broadcast frames which are received by one receiver block 12a in the form of, for example, a mobile device. Fig. 12 shows a variant of an arrangement with two transmitter blocks 12 of identical configuration which transmit broadcast frames to one receiver block 12a integrated in the smartphone. In turn, Fig. 13 shows a configuration in which a plurality of transmitter blocks 12 transmit broadcast frames received by a plurality of receiver blocks 12a.

All of the examples above use Bluetooth Low Energy modules and a protocol stack compliant with the Bluetooth Core 4.2 specification. The broadcast mode described in the Bluetooth Core 4.2 specification is based on the broadcast mode described in the Bluetooth Core 4.0 specification. This means that all Bluetooth devices, starting with those with an implemented Bluetooth protocol stack, at least version 4.0, can be used in the presented system (these are all Bluetooth Low Energy devices).

Patent claims

Claims (5)

1. A method of broadcast transmission for Bluetooth Low Energy transmitters, especially in devices monitoring the body's locomotor functions and / or respiratory function and / or pulse, characterized in that by means of a radio transmitter block (12) Bluetooth Low Energy configured to transmit broadcast frames (3 ) these broadcast frames (3) are broadcast with variable intervals (2a) between broadcast frames (3) compliant with the Bluetooth Low Energy standard, with broadcast frames (3) being transmitted only for defined values (13a) in a series of consecutive digital values forming a binary string representing the input signal (13) of the transmitter block (12) and a discrete time value for each digital value, after which the Bluetooth Low Energy radio receiver block (12a) receives broadcast frames (3) and measures the interframe intervals (2a) , and then discrete time values (15) representing. are determined in the receiver block (12a) information, wherein the discrete time value (15) is determined by summing the last computed discrete time value (15) and the last measured interframe interval (2a), the first discrete time value being set to zero. 2. The method according to p. The method of claim 1, characterized in that transmission of broadcast frames (3) is performed by means of a transmitter block (12) comprising a radio module (11) and a microcontroller block (10) with at least one microcontroller. 3. The method according to p. The method of claim 1, wherein the reception of broadcast frames (3) and the determination of discrete time values (15) representing the information are performed by a receiver block (12a) comprising a radio module (11a) and a microcontroller block (10a) with at least one microcontroller. PL 233 729 Β1 4. The method according to p. The method of claim 1, wherein the measurements of the interframe intervals (2a) and the determination of discrete time values (15) representing the information are performed in at least one microcontroller of the microcontroller block (110a). 5. The method according to p. The method of claim 1, characterized in that, prior to transmitting a broadcast frame (3), the broadcast data section (4) of that frame is filled with binary data and transmitting the filled frame to the receiver block (12a). Drawings