The Elderly’s Independent Living in Smart Homes: A Characterization of Activities and Sensing Infrastructure Survey to Facilitate Services Development
Abstract
:1. Introduction
2. Smart Home Projects and Applications
2.1. Recent Surveys on Smart Homes
2.2. Smart Home Projects
2.3. Smart Home Applications Suited to Elderly People
2.3.1. Specific Health Monitoring
2.3.2. Daily Activities Monitoring, Prediction and Reminding
2.3.3. Detection of Anomalous Situations
2.4. Human Factors
3. Conceptualization and Formalization of Activities in Smart Home
3.1. Taxonomy of Activities
Type | Activity | Description of How the Activity Relates to the Elderly Independent Living |
---|---|---|
Basic ADLs | Bathing | Performs sponge bathing, tub bathing or showering without assistance |
Brushing teeth | Brushes one’s teeth without assistance (including the use of toothbrush and toothpaste) | |
Dressing | Puts on and off clothes and shoes without assistance (except for tying shoes) | |
Using toilet | Goes to toilet, uses it, dresses and returns without assistance (may use cane or walker) | |
Eating and drinking | Feeds oneself and drinks without assistance (including the use of cutlery) | |
Sleeping | Sleeps on a bed in the bedroom without assistance | |
Instrumented ADLs | Preparing meals | Chooses material and food in the kitchen, prepares meals autonomously without assistance |
Preparing drinks | Chooses the type of drinks, prepares drinks with sugar or milk | |
Resting | Reads a book, listens to music, operates and watches TV without assistance during leisure time | |
Housekeeping | Keeps house clean (sweeps floor with broom, washes dishes and glasses in kitchen, etc.) and does housework (such as ironing) without assistance | |
Using a telephone | Picks up the telephone, dials the number, has a conversation or answers a call without assistance | |
Taking medicine | Takes the prescribed medicines appropriately and timely without assistance | |
Ambulatory Activities | Walking | Walks from one place to another, walks up or down the stairs without assistance |
Doing exercise | Does exercise such as running and cycling without assistance | |
Transitional activities | Performs transitional movements (such as sit-to-stand, sit-to-lie, stand-to-sit, lie-to-sit) in and out of bed or chair without assistance | |
Stationary activities | Sits in the sofa, stands for a period of time (may use cane or walker), lies in bed or sofa |
3.2. Activity Conceptualization
- Specialization of activities—Activities can be categorized at multiple granularity levels. In [65], the authors distinguish the ADLs in the smart home from the actions, in order to define the human behavior at different complexity levels and durations. An action is an atomic activity that is performed by a single subject and lasts for a relatively short time. Some examples of action are “open the door”, “turn on the light” and “go to bed”. An ADL is usually defined as a more complex behavior performed by either a single user or multiple users and which lasts for a longer time than an action. Furthermore, a so-called coarse-grained activity may be specialized into two or more fine-grained activities. For example, “preparing drinks” may have as its child activities: “preparing hot drink” and “preparing cold drink”, whereas “preparing hot drink” can be further broken down into its child activities: “preparing tea”, “preparing hot milk” and “preparing coffee”. Meditskos et al. [66] defined the specialization of activities differently. As an example, in their activity pattern, the activity “night sleep” is defined as the overall night sleep activity of a person and the activity “out of bed” is detected when the person gets out of bed. With the addition of context description and activity type interpretation, an “out of bed” activity can be further specialized as a “bed exit” activity, which refers to the “out of bed” activity when it occurs during the “night sleep”.
- Composition of activities—Most complex ADLs are composed of an ordered succession of simpler activities. For instance, “sleeping” may consist of: “opening the door”, “going to bed”, and “turning off the light” (as shown in Figure 2). The ordering of the simple activities may depend an individual’s preferences or habits, thus leading to several variants of an activity. Furthermore, activities may have time-related connections to each other, to form a composite activity. At this respect we may distinguish three situations: sequential activities, concurrent activities and interleaved activities. Figure 2 shows graphically these temporal relationships.
3.3. Activity Context Representation Formalization
References | Sensor ID Coding | Timestamp Coding | Sensor Value Representation | Other Information |
---|---|---|---|---|
Ye et al. [70] (based on [71]) | Name indicating the location or the object to which the sensor is attached | Date and time in a single feature | ON/OFF (activation or deactivation) | Activity information in the form of annotations (optional) |
Cook et al. [71] | Number | Date and time in a single feature | ON/OFF (activation or deactivation) | |
Tapia et al. [72] | Number or name (e.g., “PDA”) | Two timestamps corresponding to the activation and deactivation times. An additional feature shows the difference between them in seconds | Implicit in the activation (OFF to ON) and deactivation (ON to OFF) timestamps | Contextual information (optional): room and object type to which the sensor is attached |
Type | References | Advantages | Disadvantages |
---|---|---|---|
Key-value modelling | Aiello et al. [73] CC/PP [74] | Key-value pairs are easy to manage | Limited capacities in capturing sophisticated context types |
Markup scheme modelling | McDonald et al. [75] Gonçalves et al. [76] | Allow defining interaction patterns | Lack of design criteria, only available in a limited scale |
Graphical modelling | Rialle et al. [77] Henricksen et al. [78] | More comprehensive support for capturing imperfect and historical information | Flat information model, limited in supporting interoperability within context-aware systems |
Object-oriented modelling | Zhang et al. [80] | Good performance in object related activity context representation | Limitation of interoperability |
Logic-based modelling | Bruno et al. [81] Chen et al. [82] | Clear and elegant semantics in describing contextual information | Unable to represent uncertain context and inflexibility to represent user’s habits |
Ontology-based modelling | Okeyo et al. [65] Ye et al. [84] Perich et al. [83] Chen et al. [85] | Represent context in terms of heterogeneity, interoperability, and usability with user friendly interface | Require well-built knowledge engineering skills, limited ability in dealing with uncertain and changing context |
4. Sensors in the Smart Home
Sensor | Measurement | Data Format | Advantages | Disadvantages |
---|---|---|---|---|
Video cameras | Human actions/environmental state | Image, video | Precise information | Privacy issues, computational expense, acceptability issues |
Microphones | Voice detection, other sounds | Audio | Certain and rich information about sound | Implementation difficulty and high computation cost, potential acceptability issues |
Simple binary sensors | User-object interaction detection/movements and location identification | Categorical | Low-cost, low-maintenance, easy to install and replace, inexpensive, less privacy-sensitivity, minimal computation requirements | Provide simple and limited information for composite and multi-user activity monitoring |
RFID | Object and user identification | Categorical | Small size and low cost | Reader collision and tag collision, range limited |
Temperature sensors/light sensors/humidity sensors | Environmental parameters | Time series | Intuitive monitoring of environment and object | Limited information for activity monitoring |
Wearable inertial sensors | Acceleration/orientation | Time series | Compact size, low cost, non-intrusiveness, high accuracy, unique identification of users, user’s location easily tracked. | Cumbersome and uncomfortable feeling, cannot provide sufficient context information |
Wearable vital signs sensors | Vital signs | Analog signal | Sensitive to slight change in vital signs monitoring, more accurate in emergency situation detecting | Reliability constraints, Security issues and uncomfortable feeling for long-time skin attaching |
4.1. Environmental Sensors
4.2. Wearable Sensors
4.2.1. Inertial Sensors
References | Number of Accelerometers | Placements | Activities |
---|---|---|---|
Gjoreski et al. [103] (2011) | 7 | Chest, left thigh, right ankle | Standing, sitting, lying, going down, standing up, sitting on the ground, on all fours |
Jiang et al. [104] (2011) | 4 | Left forearm, right forearm, left shank and right shank | Standing straight, sitting on a chair, lying on a bed, walking, jogging, cycling, walking on an elliptical machine, running on an elliptical machine, rowing and weight lifting. |
Jennifer et al. [105] (2011) | 1 | Smartphone | Walking, jogging, upstairs, downstairs, standing, sitting |
Zhu and Sheng [95] (2011) | 1 | Right thigh | Sitting, standing, lying, walking, sit-to-stand, stand-to-sit, lie-to-sit, sit-to-lie |
Siirtola et al. [106] (2012) | 1 | Smartphone placed in trousers’ front pocket | Walking, cycling, sitting, standing, driving a car |
Hemalatha and Vaidehi [107] (2013) | 1 | Chest | Standing, walking, sitting, lying, fall |
Mannini et al. [108] (2013) | 1 | Wrist/ankle | 26 daily activities |
Zheng et al. [96] (2013) | 1 | Wrist/hip/waist pocket | Lying, sitting, standing, walking, running, dancing, jogging, upstairs, downstairs, skipping |
Muaaz et al. [109] (2014) | 1 | Waist, right-hand side of the hip | Walking |
Gao et al. [97] (2014) | 4 | Chest, left under-arm, waist and thigh | Lying, sitting, standing, flat walking and up & down stairs, lie-to-stand, stand-to-lie, sit-to-stand, stand-to-sit |
4.2.2. Vital Signs Sensors
5. Sensor Data Processing
5.1. Data Preprocessing
5.1.1. Data Cleaning
5.1.2. Handling Missing Values
5.1.3. Data Transformation
- Nature of scale, which refers to the basic mathematical properties of the used scales.
- Homogeneity, which refers to whether, or not, the sensors are measuring the same physical phenomenon.
- Empirical statistical distribution observed in the sensor values when applied to a given population segment (e.g., the elderly).
- Semantics, which refers to how the scale should be interpreted, such as probabilistic, possibilistic, utility or degree of similarity.
5.2. Data Segmentation
5.2.1. Temporal-Based Segmentation
5.2.2. Activity-Based Segmentation
5.2.3. Sensor Event-Based Segmentation
5.3. Dimensionality Reduction
5.3.1. Feature Extraction
Domain | Extracted Features |
---|---|
Time domain | Mean, Median, Average, Variance, Standard Deviation, Minimum, Maximum, Range, Root Mean Square (RMS), Correlation, Cross-Correlation, Zero-Correlation, Integration, Differences, Velocity, Signal magnitude area (SMA), Signal vector magnitude (SVM), Difference, Zero-crossing. |
Frequency domain | Wavelet Transformation, Fourier Transform (DC component, Key Coefficients, Coefficients sum, Dominant frequency, Spectrum Energy, Spectrum Entropy, Spectrum centroid) |
Discrete domain | Euclidean-based Distances, Dynamic Time Warping, Levenshtein Edit Distance |
5.3.2. Feature Selection
Activities | Sensors | Preprocessing Methods | Segmentation Methods | Dimensionality Reduction Methods | |
---|---|---|---|---|---|
BADLs | Bathing, dressing, eating and drinking, using toilet, grooming | ||||
IADLs | Using telephone, watching TV, preparing food, cleaning, taking medicine, sleeping |
|
| ||
Ambulatory activities | Lying, sitting, standing, walking, running, cycling, walking upstairs, walking downstairs, lie-to-stand, stand-to-lie, sit-to-stand, stand-to sit |
|
| ||
Vital sign monitoring | Brain activity and heart rate |
| -Temporal-based window with 2 s [42] | ||
Eye movement | EOG [117,118] |
| |||
Muscle activity |
|
|
|
|
6. Identified Research Challenges
6.1. Accuracy and Robustness in Activity Recognition
6.2. High-Level and Long-Term Activity Monitoring
6.3. Multi-User and Multi-Sensor Activity Monitoring
6.4. Real World Data Collection
6.5. Heterogeneous Sensor Data Representation
6.6. Imbalanced and Overlapping Data Classes
6.7. Meaningful Feature Extraction
6.8. Consideration of Human Factors
7. Conclusions
Acknowledgments
Conflicts of Interest
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Ni, Q.; García Hernando, A.B.; De la Cruz, I.P. The Elderly’s Independent Living in Smart Homes: A Characterization of Activities and Sensing Infrastructure Survey to Facilitate Services Development. Sensors 2015, 15, 11312-11362. https://doi.org/10.3390/s150511312
Ni Q, García Hernando AB, De la Cruz IP. The Elderly’s Independent Living in Smart Homes: A Characterization of Activities and Sensing Infrastructure Survey to Facilitate Services Development. Sensors. 2015; 15(5):11312-11362. https://doi.org/10.3390/s150511312
Chicago/Turabian StyleNi, Qin, Ana Belén García Hernando, and Iván Pau De la Cruz. 2015. "The Elderly’s Independent Living in Smart Homes: A Characterization of Activities and Sensing Infrastructure Survey to Facilitate Services Development" Sensors 15, no. 5: 11312-11362. https://doi.org/10.3390/s150511312
APA StyleNi, Q., García Hernando, A. B., & De la Cruz, I. P. (2015). The Elderly’s Independent Living in Smart Homes: A Characterization of Activities and Sensing Infrastructure Survey to Facilitate Services Development. Sensors, 15(5), 11312-11362. https://doi.org/10.3390/s150511312