ES1248994U - BABY MONITORING SYSTEM (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

A baby monitoring system comprising: a plurality of sensors (60), an interface module (50), at least one near field communication card (90) wherein the sensors (60) and the near field communication card (90) are configured to be attached to a baby stroller (100), a stroller (200), a safety seat (300) or a crib (400), characterized in that the interface module (50) comprises a screen (84) and is configured to be positioned next to the near field communication card (90) by a user by means of adjustable coupling means, to read the near field communication card, check the identity of the near field communication card and show monitored parameters on the screen (84). (Machine-translation by Google Translate, not legally binding)

Description

DESCRIPTION

BABY MONITORING SYSTEM

Field of the invention

The present invention belongs to the childcare sector and in particular to the monitoring of babies and young children. More particularly, the invention belongs to the sector of smart baby strollers, pushchairs, baby seats, car safety seats and smart cribs.

Background of the invention

It is known in the childcare industry to use baby monitoring devices in some situations, for example when a baby is in the care of a new person. This is increasingly common given the demands on the work lives of parents who are responsible for the safety and well-being of their young children while not supervising them in person or while they are busy with other tasks.

The application of some monitoring methods in baby strollers is also known. For example, CN103584577 describes a baby carriage comprising a power supply, a control module, a humidity detection module, a switch, a motor, a music playback module, and a voice prompt module. Moisture detection module and voice module can alert parents to change a baby's diaper.

CN104742951 describes a stroller comprising LED light sources, a control unit, a humidity sensor and an alarm device, in which the LED light sources are arranged outside the body. The humidity sensor and the alarm device are electrically connected to the control unit. The multifunctional stroller has the function of lighting in case of emergency and the functions of detection and warning of diaper changes.

CN108363340 describes a single chip microprocessor-based smart baby stroller, wherein the stroller comprises a control module, a diffuse infrared photoelectric switch, an ultrasound distance measurement module, a braking device, a first module infrared detection module, a second infrared detection module, a temperature and humidity sensor, a monitoring button and an alarm module that connect with the control module. The smart baby stroller has functions of collision avoidance, automatic braking, automatic tracking, baby loss alarm and baby urination alarm.

In the smart strollers described in these three examples, the information transmitted by the alarms is very limited: it only alerts the adult when the level of a parameter exceeds a threshold. The device cannot analyze the general state of comfort of the baby taking several factors into account. Nor is a procedure disclosed to update sensors or alarms without replacing the entire stroller, or using part or all of the system in another stroller from the same manufacturer.

CN105812580 describes a smart baby stroller mainly based on the internet of things. The information exchange with the baby carriage is done using a mobile application and a WiFi connection. Various functions of the baby stroller can be controlled; The baby stroller can automatically rock and play children's songs through the detection of a baby cry. Strong light can be detected by a light ray detector and a sun protection net can be closed. A humidity detection module detects if a baby gets wet according to the humidity information and alerts the adult. A color display built into the baby carriage can display time and information such as the baby's temperature and weight as detected by sensors. There is also automatic control and real-time monitoring.

In this smart stroller, the monitoring system is detachable and can analyze and display more complex information. The fact that the information can be displayed on a mobile phone allows the information to be shared and viewed remotely, for example the information can be shared with a caregiver operating the stroller and a mother at home. However, such a mobile application could be used with other strollers from other manufacturers.

Then, it would be advantageous to provide a monitoring system for baby strollers where the system can manage complex data, can remotely communicate with other personal electronic devices and can be used in other strollers or products of the same manufacturer.

Description of the invention

The present invention provides a baby monitoring system comprising a plurality of sensors, an interface module, and at least one Near Field Communication (NFC) card. The sensors and the NFC card are configured to be attached to a stroller, a stroller, a highchair or a crib. The interface module comprises a display and is configured to be positioned close to the NFC card by a user by means of adjustable coupling means, to read the NFC card, verify the identity of the NFC card and display monitored parameters. An identical NFC card can be installed in a product line of a certain manufacturer, for example, strollers, chairs and cribs. This can allow the same monitoring system to be disassembled and used on any product in this product line. Reading the NFC card can verify that the monitoring system is being used with a product from a certain manufacturer and can prevent the system from being used with other products.

In some embodiments of the invention, the plurality of sensors comprises one or more of: a camera, a microphone, a temperature sensor, a humidity sensor, a CO ² sensor, a photoelectric sensor, a motion sensor, a sensor rain, a fire sensor or a geolocation module. The sensors can be electrically connected to the interface module, or they can be independently and communicate wirelessly. The interface module can process the raw data from the sensors to monitor more complex parameters such as the baby's emotional state or state of comfort.

In some embodiments of the invention, the sensors are configured to communicate wirelessly with the interface module.

In some embodiments of the invention, the interface module is configured to communicate wirelessly via a cloud with a personal electronic device. For example, the interface module can share data from the sensors with a mobile phone.

In some embodiments of the invention, the interface module is configured to connect to a WiFi network to download data and / or communicate with a cloud. The interface module can communicate with a cloud platform. You can also download maps, programs, and program updates from the platform. You can also upload data to the platform, for example the location of the system, to share this data with another device. The connection to a WiFi network also allows the updating of programs installed in the interface module.

In some embodiments of the invention, the interface module also comprises a SIM card tray and a SIM card reader so that the interface module is configured to connect to a mobile network to download data and / or communicate with a cloud.

In some embodiments of the invention, the interface module also comprises a bluetooth module so that the interface module is configured to connect via bluetooth to a mobile network of a mobile device close to the monitoring system to download data and / or communicate with a cloud.

In some embodiments of the invention, the interface module is configured to display one or more of the following database-monitored parameters detected by the sensors: current location, live image, baby emotional state, sleep or wake state. baby, baby hunger or thirst state, baby temperature, room temperature, diaper moisture, type of excretion in diaper, ambient pollution level, light level, noise level. These parameters can be calculated or analyzed by a program. For example, an algorithm can analyze an image transmitted by the camera to identify the emotional state of the baby.

In some embodiments of the invention, the interface module is configured to display one or more of the following monitored parameters to a database downloaded from a WiFi network or a mobile network: connection status with a wireless network, local map view, current date, current time, weather forecast.

In some embodiments of the invention, the monitoring system additionally comprises an audio output system. This can be part of the interface module.

In some embodiments of the invention, the display of the monitoring system is an LED display.

In some embodiments of the invention, the LED display and / or the audio output system are configured to display an alert when a monitored parameter is outside of an allowable range, where the alert is a visual symbol on the screen (e.g. example, a text message or an icon), a flashing light, a constant light and / or an audible alarm.

In some embodiments of the invention, the monitoring system is configured to display one or more of the monitored parameters and / or alerts on a personal electronic device. For example, the system can Share data about parameters in real time with the cloud platform via WiFi network or mobile network. This data can be downloaded, for example, by a mobile phone of a father or mother of the baby.

In some embodiments of the invention, the interface module comprises a program and is configured to download program updates periodically via WiFi or a mobile network.

In some embodiments of the invention, the interface module comprises a touch screen, a joystick, or at least one control button. By these input means, a user can select parameters to view or share for example.

Also described here:

A baby carriage comprising the monitoring system according to any of its embodiments.

The baby carriage can comprise a photovoltaic plate that powers a battery of the interface module, wherein the battery is internal or external to the interface module. The photovoltaic plate can be positioned on a surface of the interface module or on an upper surface of a hood of the stroller. The photovoltaic plate can be removable.

Optionally the stroller comprises a dynamo coupled with at least one wheel of the stroller, wherein the dynamo supplies a battery of the interface module, wherein the battery is internal or external to the interface module.

Preferably, the stroller comprises an adjustable clamp that couples the interface module to a handlebar of the stroller.

Also optionally, the stroller comprises a temperature sensor, a humidity sensor, a fire sensor and a first CO ² sensor positioned in a seat on an interior surface of the stroller. The humidity sensor can be positioned to quickly detect the baby's urination. The first CO ² sensor can identify if the baby has a lot of gas and identify the type of stool (urine or feces) in the baby's diaper.

Finally, the stroller can comprise a camera, a geolocation module, a microphone, a second CO ² sensor, a rain sensor, a photoelectric sensor and a motion sensor positioned on a frame of the stroller. The second CO ² sensor can detect the level of environmental pollution. The camera can record a live image of the baby or the path the stroller takes, depending on its orientation. In the latter case, the camera can detect obstacles or ditches, for example during a walk in nature where the baby is facing the operator of the stroller. The microphone can detect the ambient noise level or the baby's cry for automatic analysis and interpretation. The geolocation module can detect the geographical position of the stroller. This information can be incorporated into a digital map by the interface module, so that the operator of the stroller does not have to look at the mobile or other personal device while carrying the stroller in an unfamiliar area.

Brief description of the figures

To complement the description and in order to help a better understanding of the characteristics of the invention, according to an example of a practical embodiment thereof, a set of figures is attached as an integral part of the description in which with character Illustrative and not limiting, the following has been represented:

Figure 1 is a schematic representation of a baby carriage.

Figure 2 is a schematic representation of a stroller.

Figure 3 is a schematic representation of a safety chair.

Figure 4 is a schematic representation of a cradle.

Figure 5 is a side view of a baby carriage according to a first embodiment of the invention.

Figure 6 is a front view of the baby carriage of Figure 5.

Figure 7 is a side view of a baby carriage according to a second embodiment of the invention, showing the position of the sensors.

Figure 8 is a front view of the baby carriage of Figure 7.

Figure 9 is a side view of a baby carriage according to a third embodiment of the invention, showing the position of the battery of the interface module.

Figure 10 is a front view of the baby carriage of Figure 9.

Figure 11 is a side view of a bracket for an interface module according to the third embodiment of the invention.

Figure 12 is a front view of the clamp of Figure 11.

Figure 13 is a partial front view of a baby carriage according to the third embodiment of the invention, showing in detail the position of the clamp of Figure 12 and the battery.

Figure 14 shows several views of an interface module according to the third embodiment of the invention and a view of a support base of the clamp.

Figure 15 is a schematic representation of the interface module operation.

Figure 16 is a schematic representation of the operation of the interface module in a first scenario where the baby is hot or cold.

Figure 17 is a schematic representation of the operation of the interface module in a second scenario where the baby needs a diaper change.

Figure 18 is a schematic representation of the interface module's operation in a third scenario where the light level is excessive.

Figure 19 is a schematic representation of the interface module operation in a fourth scenario where the noise level is excessive.

Figure 20 is a perspective view of an interface module mounted to a baby carriage according to the third embodiment of the invention.

Figure 21 is another perspective view of the interface module of Figure 20, showing a side face.

Figure 22 is another perspective view of the interface module of Figure 20, showing the rear face.

Description of some embodiments of the invention

Figures 1 to 4 respectively show a baby stroller, a stroller, a safety chair and a cradle, in any of which the monitoring system of this invention can be applied.

Figure 5 shows a side view of a baby carriage 100 according to a first embodiment of the invention. As seen in the figure, the stroller comprises a frame 10, a seat 20, wheels 30 and 32, and a canopy 40. Although they are not visible in this figure, the stroller 100 also comprises sensors 60 in parts of the seat and frame. and an interface system 50 that may also comprise sensors. In this embodiment, the interface system is connected to a battery 56 found in a bag 54 removably hung on a handle 12 of the frame 10. The interface system is configured to receive information from the sensors and display it on a screen. 84. In this embodiment, a rear wheel 30 comprises a dynamo 34 and the hood 40 comprises a photovoltaic plate 42. The dynamo 34 and the photovoltaic plate 42 are electrically connected to the battery 56 to power it in certain circumstances; for example when there is light and the battery is not connected to a main power source. Figure 6 shows a front view of the baby carriage 100 according to the first embodiment where the position of the battery 56 in the bag 54 is better seen.

Figures 7 and 8 show a side and front view respectively of a baby carriage 100 according to a second embodiment of the invention. In this embodiment, the hood 40 does not comprise a photovoltaic plate, the wheel 32 does not comprise a dynamo, and the frame 10 has a different shape with respect to the first embodiment. Figure 7 shows the very approximate position of the sensors. A temperature sensor 621, a humidity sensor 622, a fire sensor 67 and a first CO ² sensor 65 are inside the seat. The temperature sensor 621 can measure the body temperature of a baby while in the seat, so that the interface system 50 can find out if the temperature is outside an acceptable range and if not, it can alert the user that the baby you may be ill or at risk for hypothermia. The humidity sensor 622 can be positioned on an upper surface of the seat 20 to measure the humidity of a baby's diaper, so that the interface system 50 can find out if the humidity level exceeds a limit value indicating that the diaper has to be changed. The first CO ² sensor 65 can be positioned near the humidity sensor 622 to measure the local CO ² level so that the interface system 50 can identify the type of stool in the baby's diaper, where an increased level of CO ² relative to the ambient level or above indicates the presence of gases or feces, and an unaltered CO ^{2 level} indicates urine. The fire sensor 67 can detect electromagnetic waves within a certain range of wavelengths, for example, between 760 nm and 1100 nm. The fire sensor 67 can activate an alarm via a speaker on the interface module.

A camera 61, a geolocation module 63, a microphone 64, a second CO ² sensor 65, a rain sensor 66, a photoelectric sensor 68, and a motion sensor 69 are positioned on an outer surface of the handlebar 12 or on the interface module 50 (not visible in figures 7 and 8). The camera 61 is positioned on a rear surface of the interface module 50 and is oriented to record an image of the baby in the seat 20 of the stroller 100. An emotion recognition program in the interface module 50 can use the recorded images of the baby. to detect some emotional states of the baby. This program can also use sounds transmitted through the microphone 64 such as crying in combination with the images to detect the emotional state of the baby. Geolocation module 63 may be positioned within interface module 50 to display the position of the stroller on screen 84. Microphone 64 may be positioned on handlebar 12 to transmit a level of ambient noise or baby cries. The second sensor CO ² 65 can be positioned on the handlebar 12 and measure an ambient CO ² level. Rain sensor 66 can be positioned on handlebar 12 or anywhere in the stroller exposed to the elements of nature. Photoelectric sensor 68 may be positioned on handlebar 12 and measure the light level. Motion sensor 69 may be positioned on the rear surface of interface module 50 and oriented to detect a movement of the baby to activate other sensors if the presence of the baby is detected. The sensors can be electrically connected to the interface module 50. The sensors can also be configured to communicate wirelessly with the interface module 50.

Figures 9 and 10 show a side and front view respectively of a baby carriage 100 according to a third embodiment of the invention. In this embodiment, the hood 40 has a more hooded shape, giving more protection from the sun. The hood comprises a photovoltaic plate 42 and the wheel 30 comprises a dynamo 34. The frame also comprises an additional cross bar 14. In these figures the position of the interface module 50 is seen, which comprises a screen 84 on a front face. A clamp 52 adjustably and removably connects the interface module 50 with the handlebar 12. The handlebar 12 comprises an NFC card 90 (not shown in the figures) that identifies the stroller as a product of a certain manufacturer. The interface module 50 comprises an NFC reader 92 (not shown in the figures) so that the module 50 shows the parameters detected by the sensors only when the presence of the NFC card 90 is confirmed. In this way, the module 50 can be disassembled, for example to recharge its battery 56 from a main power source, without being able to use the module 50 in a stroller from another manufacturer. The sensors installed in the stroller can also be disassembled and replaced individually without replacing the module 50.

Figures 11 and 12 show a side and front view respectively of an example of the clamp 52 of the third embodiment. The bracket 52 comprises a support base 521, a ball joint 522, a hook 523 and a screw 524. The support base can be detachably connected to a lower face of the interface module 50 by means of hooks. Ball joint 522 allows the user to adjust an angle of module 50 in the horizontal plane. Hook 523 and screw 524 serve to mount and remove module 50 on stroller handle 12, in a desired horizontal position. Figure 13 shows the position of clamp 52 on handlebar 12.

Figure 14 shows various views of the support base 521 and the interface module 50. A plan view of the support base 521 is seen in the figure comprising four projections that form an engagement with a slot on a lower surface of the module. interface 50, coupling the two removably. A front view of interface module 50 shows a display 84 and a control lever 528 on the front surface. A view of the bottom surface of the module 50 shows a slot 525 configured to receive the projections of the support base 521. A rear view of the module 50 shows a chamber 526 on the rear surface. The module 50 may also comprise one or more USB ports, a charging port, a SIM card tray, and a connection to the sensors via cables not shown in Figure 14.

Figure 15 schematically shows the operation of the interface module 50 according to an embodiment of the invention compatible with any of the previously described strollers or with a stroller, a safety chair or a cradle. In figure 15, part 61 is a camera, 621 is a temperature sensor, 622 is a humidity sensor, 63 is a GPS, 64 is a microphone, 65 is a CO ² emissions sensor, 66 is a temperature sensor. rain, 67 is a fire sensor, 68 is a photoelectric sensor, and 69 is a motion sensor. The number 70 represents a device, 76 is a cloud, 78 is an application, 60 refers to the input means, 80 refers to the output means, where 82 is a speaker and 84 is the LED display. Information stored in cloud 76 may include information related to emotions, weather forecast, CO ² in the city, and time slot.

Module 50 receives signals from sensors 60 and a cloud platform 76 via wireless communication means such as WiFi, Bluetooth, or a mobile network. An application 78 installed in the module manages the received signals. The signals received from the sensors may include for example: current location, live image, baby emotional state, baby sleep or wake state, baby hunger or thirst state, baby temperature, room temperature, diaper moisture, type of excretion in diaper, level of ambient pollution, light level, noise level. The signals received from the platform may include for example: connection status with a wireless network, local map view, current date, current time, weather forecast. The module 50 can also upload data to the platform that can comprise monitored parameter values from the signals received from the sensors. A personal electronic device 70 can securely connect to the platform via an application 78 and download this data or view it live. The personal electronic device 70 can be for example a mobile phone, a tablet or a computer. For example, a parent can monitor the location of the stroller on their mobile phone while their baby is out for a walk with a babysitter. The interface module 50 can also analyze the data received from the sensors or the platform to present it in a simplified way visually and / or audibly. The interface module may transmit information about monitored parameters to the user via display 84 and / or a speaker 82. Display 84 may be an LED display.

Figure 16 shows the operation of the monitoring system in a first scenario where the baby has cold or hot. In figure 16, the number 161 represents the step where the presence of the baby is detected, in 162 it is detected that it is crying, in 163 it is verified that it has negative emotion, in 164 it is detected cold / heat, in 165 a warning occurs in the device and in 166 a warning occurs in the application.

First, the motion sensor 69 detects the presence of the baby in the stroller. When the interface module 50 determines that the baby is in the stroller, it activates the microphone 64. The microphone transmits signals to the module 50 that determines that the baby is crying. When it is determined that the baby is crying, the module 50 activates the camera 61 which transmits images of the baby to the module 50. The module 50 analyzes the images and determines that the baby has a negative emotion. When a negative emotion is detected, the module 50 activates the temperature sensor 621 and the humidity sensor 622. The temperature sensor in this case detects a temperature outside of an acceptable range. For example, the baby is found to be cold because the temperature is below a minimum. Upon detecting that the baby is cold, the module 50 activates the display of a specific alert on the screen 84 of the module 50. The module also sends this information to the cloud platform through a wireless network, allowing the display of this information in a personal electronic device.

Figure 17 shows the operation of the monitoring system in a second scenario where the baby needs a diaper change. In figure 17, the number 171 represents the step where the presence of the baby is detected, in 172 it is detected that it is crying, in 173 it is verified that it has negative emotion, in 174 it is detected that the temperature / humidity exceeds a threshold, in 175 It differs if it is only urine or if it has gases and / or feces in the diaper, in 176 a warning is produced in the device and in 177 a warning occurs in the application.

In this scenario, the same sequence occurs as described above until the activation of the temperature sensor 621 and the humidity sensor 622. The humidity sensor 622 detects that the humidity level in the seat region exceeds a maximum acceptable value and transmits this information to module 50. The module activates the first CO ² sensor 65 which determines whether the CO ^{2 level} in this region is substantially higher than a reference level. The reference level can be the ambient CO ² level or the local level above. For example, a substantially increased level of CO ² is detected which is interpreted by module 50 as the presence of feces in the baby's diaper and that the diaper has to be changed. Upon detecting that the diaper has to be changed, the module 50 activates the display of a specific alert on the screen 84 of the module 50. The module also sends this information to the cloud platform through a wireless network, allowing it to be displayed. information on a personal electronic device.

Figure 18 shows the operation of the monitoring system in a third scenario where there is too much light for the baby. In figure 18, the number 181 represents the step where the presence of the baby is detected, in 182 it is detected that it is crying, in 183 it is verified that it has negative emotion, in 184 it is detected that a light threshold for a baby has been exceeded , in 185 a warning occurs on the device and 186 a warning occurs in the application.

In this scenario, the same sequence occurs as described above until the activation of the camera 61. The module 50 detects that the image transmitted by the camera shows a negative and active emotion, among others, the photoelectric sensor 68. The photoelectric sensor measures a ambient light level, the value of which is transmitted to module 50. Module 50 determines that the light level exceeds an acceptable maximum. Upon detecting that there is too much light, the module 50 activates the display of a specific alert on the screen 84 of the module 50. The module also sends this information to the cloud platform through a wireless network, allowing the display of this information in a personal electronic device.

Figure 19 shows the operation of the monitoring system in a fourth scenario where there is too much noise for the baby. In figure 19, the number 191 represents the step where the presence of the baby is detected, in 192 it is detected that it is crying, in 193 it is verified that it has negative emotion, in 194 it is detected that a sound threshold has been exceeded for which a baby is not used to it, in 195 a warning is produced on the device and in 196 a warning is produced in the application.

In this scenario, the same sequence occurs as described above until the activation of the camera 61. The module 50 detects that the image transmitted by the camera shows a negative emotion and activates the microphone 64 again. The microphone detects a level of ambient noise , the value of which is transmitted to module 50. Module 50 determines that the noise level exceeds an acceptable maximum. Upon detecting that there is too much noise, the module 50 activates the display of a specific alert on the screen 84 of the module 50. The module also sends this information to the cloud platform through a wireless network, allowing the display of this information in a personal electronic device.

Figure 20 shows a perspective view of the interface module 50 mounted to a baby carriage. The figure shows the control lever 528, display 84, and clamp 52 in more detail. A cable 86 is also seen connecting the module to an external battery 56.

Figure 21 shows another perspective view of the interface module 50 mounted to a baby carriage. This figure shows more clearly a side surface of the module comprising two USB ports 527.

Figure 22 shows another perspective view of the interface module 50 mounted to a baby carriage. This figure shows a rear surface of module 50 with part of the housing removed. In the exposed part is a camera 526 oriented towards the seat of the stroller. An upper surface of the module 50 is also seen in which there are several slots, one of which is a tray 530 for a SIM card.

In this text, the word "understand" and its variants (such as "understanding", etc.) should not be interpreted in an exclusive way, that is, they do not exclude the possibility that what is described includes other elements, steps, etc. On the other hand, the invention is not limited to the specific embodiments that have been described but also encompasses, for example, the variants that can be carried out by the average person skilled in the art (for example, in terms of the choice of materials, dimensions , components, configuration, etc.), within the meaning of the claims.

Claims (14)

1. - A baby monitoring system that includes: a plurality of sensors (60), an interface module (50), at least one near field communication card (90), wherein the sensors (60) and the near field communication card (90) are configured to be attached to a baby stroller (100), a stroller (200), a car seat (300) or a crib (400), characterized in that the interface module (50) comprises a display (84) and is configured to be positioned close to the near field communication card (90) by a user by means of adjustable coupling means, to read the near field communication card, checking the identity of the near field communication card and displaying monitored parameters on the display (84). 2. - The monitoring system of claim 1 wherein the plurality of sensors (60) comprises one or more of: a camera (61), a microphone (64), a temperature sensor (621), a humidity sensor (622), a CO ² sensor (65), a photoelectric sensor (68), a motion sensor (69), a rain sensor (66), a fire sensor (67) or a geolocation module (63 ). 3. - The monitoring system according to any of the preceding claims wherein one or more of the sensors (60) is configured to communicate wirelessly with the interface module (50). 4. - The monitoring system according to any of the preceding claims wherein the interface module (50) is configured to communicate wirelessly via a cloud (76) with a personal electronic device (70). 5. - The monitoring system according to any of the preceding claims wherein the interface module (50) is configured to connect to a WiFi network to download data and / or communicate with a cloud (76). 6. - The monitoring system according to any of the preceding claims wherein the interface module (50) also comprises a SIM card tray (530) and a SIM card reader so that the interface module (50) is configured to connect to a mobile network to download data and / or communicate with a cloud (76). 7. - The monitoring system according to any of the preceding claims wherein the interface module (50) is configured to display one or more of the following monitored parameters based on data detected by the sensors (60): current location, image live, baby emotional state, baby sleep or wake state, baby hunger or thirst state, baby temperature, room temperature, diaper moisture, type of excretion in diaper, gas level, ambient pollution level, light level, noise level. 8. - The monitoring system according to any of claims 5 to 7 wherein the interface module (50) is configured to display one or more of the following monitored parameters based on data downloaded from a WiFi network or a mobile network: connection status with a wireless network, local map view, current date, current time, weather forecast. 9. - The monitoring system according to any of the preceding claims wherein the monitoring system additionally comprises an audio output system (82). 10. - The monitoring system according to any of the preceding claims wherein the screen (84) is an LED screen. 11. - The monitoring system according to claim 9 wherein the screen (84) and / or the audio output system (82) are configured to show an alert when a monitored parameter is outside of an allowed range, where the alert is a visual symbol on the screen, a flashing light, a steady light and / or an audible alarm. 12. - The monitoring system according to any of claims 7, 8 or 11 configured to display one or more of the monitored parameters and / or alerts in a personal electronic device (70). 13. -The monitoring system according to any of claims 4, 5 or 6 wherein the interface module comprises a program and is configured to download program updates periodically via WiFi or a mobile network. 14. -The monitoring system according to any of the preceding claims, wherein the interface module comprises a touch screen, a control lever or at least one control button.