Enabling Remote Elderly Care: Design and Implementation of a Smart Energy Data System with Activity Recognition
Abstract
:1. Introduction
- We designed and validated an IoT platform in a real scenario to unobtrusively perform load monitoring and activity recognition (ADLs), aiming to enable remote elderly care in Chile.
- The proposed system achieves near real-time operation by accurately identifying both low- and high-power-consumption devices, overcoming the limitations of NILM solutions in this regard.
- The proposed system is capable of recognizing activities being simultaneously performed, and showing the information to users in a friendly manner through a dashboard interface.
- The proposed system is flexible, allowing the connection of any appliance independently of the plug, making it adaptable to different devices.
2. Related Work
2.1. Medical-Oriented Applications in Research
2.2. Family-Oriented Applications in Research
2.3. Summary
3. Methodology
- Cost concerns: high installation costs deter utilities and consumers.
- Infrastructure challenges: upgrading existing infrastructure is a complex and expensive task.
- Lack of awareness: consumers might not fully understand the benefits of smart meters.
- Privacy and security: concerns about data privacy and security hinder adoption.
- Regulatory hurdles: complex regulatory processes delay widespread roll-out of smart meters.
- Utility resistance: utilities might resist operational changes.
- Financial constraints: economic challenges impact adoption decisions.
- Vendor availability: limited supply chain options currently exist in the country.
4. Design and Implementation of the Proposed SEDAR System
- The lower layer, called data acquisition, encompasses physical devices such as appliances and metering devices (smart plugs). At this layer, energy transactions take place.
- Moving up, the communication network layer incorporates various network technologies available in the market for local communication. It connects smart plugs with the home gateway and establishes a connection between the home gateway and middleware.
- Next, the data analytics layer gathers a range of technologies, including ML models and preprocessing algorithms for data processing, showing this information to users through a web interface. This layer serves as a mediator between physical devices and services. The integration of a diverse array of healthcare services is possible, covering in-home monitoring, user comfort, safety, and behavior analysis.
4.1. Data Acquisition Layer
- Area level: The metering devices are used to monitor household areas, measuring the consumption after the utility’s energy meter.
- Plug level: The metering devices are located next to the plugs to monitor directly appliances connected to the outlet or multi-outlet.
- Appliance level: The metering devices are embedded directly in the appliances or placed in a dedicated outlet (i.e., the outlet for a specific appliance).
4.2. Communication Network Layer
- Home area network (HAN): Inside a household, the home area network is used to provide monitoring of energy usage. This communication network carries data generated by the metering devices and home appliances to the middleware technology in which the post-processing (monitoring, control, comfort analysis, occupancy, among other applications) is performed. Examples of communication technologies include IEEE 802.3 family, power line communications (PLCs), serial communication RS-232/485, wireless networks (IEEE 802.11 family, IEEE 802.15 family, mobile field network) (GSM-based 2G, CDMA-based 3G, LTE-based 4G, NR-based 5G), and low-power networks (NarrowBand IoT, LoRa, Sigfox) [53,54].
- Wide area network (WAN): Outside the household domains, the WAN provides data exchange between smart homes and services providers, forming smart neighborhoods and cities. Furthermore, central managed solutions, such as the cloud-based load monitoring system and database servers, are accessible through this communication network.
4.3. Data Analytics Layer
- Collect data from different metering devices at the plug level through the HAN.
- Provide monitoring and analysis of the main loads inside a household.
- Activity distribution: determined by calculating the percentage of time each activity is performed during different time intervals, such as the last hour, last 24 h, and last week.
- Average inactivity periods: calculated by averaging the duration of the inactivity periods during different time intervals, such as the last hour, last 24 h and last week.
- Appliance usage frequency: computed by counting the number of times each appliance is detected during different time intervals, such as the last hour, last 24 h, and last week.
4.4. Security
- Physical attacks: hardware devices can become damaged or intentionally removed from the plug, thereby hindering the system’s functionality.
- Insecure device configuration: vulnerabilities in device settings can be exploited to gain unauthorized access or disrupt network operations [57].
- Device-to-device interception: even without internet access, an attacker could position between two devices within the LAN and intercept the traffic exchanged between them. This could involve capturing unencrypted communication or attempting to decrypt encrypted traffic if the encryption keys are compromised [57,58].
- Data manipulation: an attacker positioned between two devices can modify the data being exchanged between them. While the modification might not have the same impact as altering internet traffic, it could still lead to unintended consequences within the local network [57].
- Credential harvesting: An attacker might trick users within the local network into revealing sensitive information, such as login credentials, through techniques like phishing or social engineering [57].
- Address resolution protocol (ARP) poisoning: ARP spoofing can still occur within a local network. Attackers can associate their own MAC addresses with IP addresses of legitimate devices, potentially leading to communication redirection or unauthorized access [57].
- Rogue devices: an attacker could set up a rogue device within the network, masquerading as a legitimate device to intercept or manipulate traffic [57].
- Malware infection: if an infected device is connected directly to the middleware, malware can spread to other devices without internet access [57].
- Physical security: ensure physical security on gateways to prevent unauthorized access.
- Strong encryption: use WPA3 encryption for the Wi-Fi network. This provides strong encryption protocols to the data transmitted [59].
- Secure password: set a strong and unique password on all devices and the Wi-Fi network.
- Service set identifier (SSID) hiding: disable broadcasting the network name so that it is not visible to devices scanning for Wi-Fi networks. This adds an extra layer of security by making it less obvious that the network exists [59].
- MAC address filtering: enable MAC address filtering on the gateway to allow only specific devices with approved MAC addresses to connect to the network [59].
- Gateway firmware updates: regularly update the router’s firmware to address security vulnerabilities and ensure the latest security features are in place [59].
- Remote management: disable remote management of the gateway’s settings. This prevents attackers from trying to access its configuration remotely.
- Two-factor authentication (2FA): enable two-factor authentication for accessing the gateway’s settings to add an extra layer of security [59].
- Network segmentation: separate the network into separate virtual area networks (VLANs) for different device types [59].
- Disable unused services: turn off any unnecessary services on the gateway, such as universal plug and play (UPnP) or Wi-Fi protected setup (WPS), as this can introduce potential vulnerabilities.
- TSL/SSL: use encryption (TSL/SSL) for MQTT communication to ensure data confidentiality [59].
- Updates: regularly update and patch software on all components of the middleware to address known vulnerabilities [59].
- Authentication: implement strong authentication and access controls for MQTT [59].
- Educate users: educate users about security best practices and potential threats to prevent social engineering attacks. In this case, it was explained to every staff member in our laboratory.
5. Feature Extraction and Classification for Appliance Recognition
Algorithm 1: Function to view features in a window. |
|
6. Results
6.1. Training Results
6.2. Real-Time Operation
7. Discussion and Limitations
8. Conclusions
Author Contributions
Funding
Institutional Review Board Statement
Informed Consent Statement
Data Availability Statement
Acknowledgments
Conflicts of Interest
Abbreviations
2FA | Two-factor authentication |
AAL | Ambient assisted living |
ADLs | Activities of daily living |
AI | Artificial intelligence |
API | Application programming interface |
ARP | Address resolution protocol |
CSV | Comma-separated value |
DAQ | Data acquisition |
DAN | Data analytics layer |
EVs | Electric vehicles |
FIFO | First-in first-out queue |
GES | Explicit health guarantee |
HEMS | Home energy management system |
HVAC | Heating, ventilation, and air conditioning |
HTTP | Hypertext transfer protocol |
IDS | Intrusion detection system |
ILM | Intrusive load monitoring |
IoT | Internet of things |
IR | Infrared |
LAN | Local area network |
ML | Machine learning |
MQTT | Message queue telemetry transport protocol |
NCTS | Non-contact triboelectric sensors |
NILM | Non-intrusive load monitoring |
PD | Parkinson’s disease |
PLCs | Power line communications |
RFID | Radio-frequency identification |
SEDAR | Smart energy data with activity recognition |
SSL | Secure socket layer |
TLS | Transport layer security |
TV | Television set |
UTFSM | Universidad Técnica Federiso Santa María |
VLAN | Virtual local area network |
WAN | Wide area network |
WPA3 | Wi-Fi Protected Access 3 |
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Reference | Type | Wearable Sensors | Camera | ILM | NILM | Target Application |
---|---|---|---|---|---|---|
[1] | Technical | X | X | X | ✓ | Dementia |
[25] | Technical | X | X | X | ✓ | Anomalous behavior |
[31] | Survey | ✓ | X | X | X | Vital signs monitoring |
[23] | Technical | X | X | ✓ | X | Accident prevention, fall detection |
[20] | Technical | ✓ | X | X | X | Rehabilitation |
[19] | Survey | ✓ | X | X | X | Behavioral patterns |
[32] | Survey | ✓ | ✓ | ✓ | X | Anomalous behavior |
[22] | Technical | X | X | X | ✓ | Parkinson’s Disease |
[33] | Survey | X | X | ✓ | X | Elderly care |
[18] | Survey | ✓ | X | X | X | Rehabilitation |
[34] | Survey | ✓ | X | ✓ | X | In-home monitoring |
[26] | Technical | X | X | ✓ | X | Behavioral patterns, comfort |
[35] | Technical | X | X | ✓ | X | Elderly care |
[27] | Technical | X | X | ✓ | X | Anomalous behavior |
[36] | Technical | ✓ | X | X | X | Elderly care |
[37] | Technical | ✓ | X | ✓ | X | Remote monitoring for people in rural areas |
[24] | Technical | X | X | ✓ | X | Elderly care |
[28] | Technical | X | X | ✓ | X | Surveillance, in-home monitoring |
[38] | Technical | ✓ | X | X | X | Exertion recognition, asthenia |
[39] | Technical | X | X | ✓ | ✓ | Not specified |
[21] | Technical | ✓ | ✓ | X | X | In-home monitoring |
[40] | Technical | ✓ | X | X | X | In-home monitoring |
[41] | Survey | X | X | X | ✓ | AAL |
[42] | Survey | ✓ | X | X | ✓ | In-home monitoring |
[43] | Survey | ✓ | ✓ | X | X | In-home monitoring |
[44] | Survey | X | X | ✓ | X | In-home monitoring |
[3] | Survey | X | X | ✓ | X | In-home monitoring |
[29] | Technical | X | X | ✓ | X | In-home monitoring |
[45] | Technical | X | X | ✓ | X | Recommendations |
[46] | Technical | X | ✓ | X | X | Activity Recognition |
[47] | Technical | X | X | ✓ | X | Activity Recognition |
This work | Technical | X | X | ✓ | X | In-home monitoring, elderly care, HEMS integration |
Appliance | Brand | Model | City | Country |
---|---|---|---|---|
Kettle | Hamilton Beach | 40987-CL | Valparaiso | Chile |
TV | LG | 24TL520S-PS | Valparaiso | Chile |
Hair dryer | Siegen | SG-3049 | Valparaiso | Chile |
Minibar | Nex | CR-52 | Santiago | Chile |
Electric heater | Ufesa | RD-1500D | Santiago | Chile |
Instances | Format | Missing Values |
---|---|---|
100,582 | JSON(timestamp, r(t) (Eq.)) [3] | 2 |
Appliance | Precision | Recall | F1 Score |
---|---|---|---|
Fridge | 1.00000 | 0.99517 | 0.99758 |
Hair dryer | 0.83333 | 1.00000 | 0.90909 |
Heater | 0.00000 | 0.00000 | 0.00000 |
Kettle | 0.70000 | 0.87500 | 0.77778 |
TV | 1.00000 | 1.00000 | 1.00000 |
Accuracy | 0.98101 | ||
Cohen’s kappa | 0.961651 |
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Franco, P.; Condon, F.; Martínez, J.M.; Ahmed, M.A. Enabling Remote Elderly Care: Design and Implementation of a Smart Energy Data System with Activity Recognition. Sensors 2023, 23, 7936. https://doi.org/10.3390/s23187936
Franco P, Condon F, Martínez JM, Ahmed MA. Enabling Remote Elderly Care: Design and Implementation of a Smart Energy Data System with Activity Recognition. Sensors. 2023; 23(18):7936. https://doi.org/10.3390/s23187936
Chicago/Turabian StyleFranco, Patricia, Felipe Condon, José M. Martínez, and Mohamed A. Ahmed. 2023. "Enabling Remote Elderly Care: Design and Implementation of a Smart Energy Data System with Activity Recognition" Sensors 23, no. 18: 7936. https://doi.org/10.3390/s23187936
APA StyleFranco, P., Condon, F., Martínez, J. M., & Ahmed, M. A. (2023). Enabling Remote Elderly Care: Design and Implementation of a Smart Energy Data System with Activity Recognition. Sensors, 23(18), 7936. https://doi.org/10.3390/s23187936