Abstract
The Internet of Things (IoT) applications and services are increasingly becoming a part of daily life; from smart homes to smart cities, industry, agriculture, it is penetrating practically in every domain. Data collected over the IoT applications, mostly through the sensors connected over the devices, and with the increasing demand, it is not possible to process all the data on the devices itself. The data collected by the device sensors are in vast amount and require high-speed computation and processing, which demand advanced resources. Various applications and services that are crucial require meeting multiple performance parameters like time-sensitivity and energy efficiency, computation offloading framework comes into play to meet these performance parameters and extreme computation requirements. Computation or data offloading tasks to nearby devices or the fog or cloud structure can aid in achieving the resource requirements of IoT applications. In this paper, the role of context or situation to perform the offloading is studied and drawn to a conclusion, that to meet the performance requirements of IoT enabled services, context-based offloading can play a crucial role. Some of the existing frameworks EMCO, MobiCOP-IoT, Autonomic Management Framework, CSOS, Fog Computing Framework, based on their novelty and optimum performance are taken for implementation analysis and compared with the MAUI, AnyRun Computing (ARC), AutoScaler, Edge computing and Context-Sensitive Model for Offloading System (CoSMOS) frameworks. Based on the study of drawn results and limitations of the existing frameworks, future directions under offloading scenarios are discussed.
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Introduction
Internet of Things (IoT) is termed as a connection of networks over the Internet. However, the purpose of this network is not merely the transfer of data or acting as a communication channel; instead, the objective of this network is for enabling the linked devices to communicate and collaborate among themselves to provide some particular service. The aim of IoT is to simplify tasks and enable it to perform smartly by gaining a high degree of intelligence in applications and services with the least human intervention using various sensors, actuators and processors [1]. Internet serves a significant role in IoT services to provide a communication channel and set up a smart interface between people and surrounding objects. Cloud and edge structures act as the critical component of IoT, to provide useful applications, specific services in multiple application domains [2]. IoT brings in automation in all sectors of life referred to as public domain and also makes all physical objects intelligent that can connect, communicate with each other and can make the smart decision by themselves. IoT provides several applications to the various streams of users, and for that, it implements different frameworks. IoT frameworks can be termed as a set of guiding policies, protocols, and principles which simplify the accomplishment of IoT applications [3].
Manyika et al. [4] had predicted the sharp rise of IoT impacting the overall economic sector by $2.7 trillion to $6.2 trillion per year by 2025. Health services and manufacturing would be the most impacted area in the system. After these sectors, the next most influenced areas from IoT would be farming, energy processing, and security. It is calculated that the sole financial impact of IoT technology in health-related services would be range from $1.1 trillion to $2.5 trillion per year by 2025 [4]. The application of IoT spans in all the domains of society and daily life; it serves in all the fields from environmental information, activity information of living organism to the processing tasks in the industries. In all domains, IoT has no existence without a Wireless Sensor Network (WSN). Acting as a backbone of IoT, sensors collect the data and communicate them. Sensors are connected with the devices having different technologies and vide application areas, which make the incorporation of IoT with WSN challenging [5].
Some of the common issues that arise for the deployment of IoT applications are data management, communication issues, real-time computing and security, privacy and scalability of data [6]. There is also trustworthiness issue related to security and privacy of data in cloud storage scenarios, there may arise a security concern due to continuous connectivity of IoT-based sensors with the edge entities [7, 8], the vulnerabilities can arise specially in sectors like healthcare where a small change in values can be life threatening. Data aggregation is also termed as one big problem for smart grid IoT systems [9] which is somewhere related to data gathering and management issue. Some applications are delay sensitive due to challenges when processing a large amount of data at edge or the cloud level of devices, leading to latency, which is not acceptable in some critical applications like health scenarios, transport management, etc. Some solutions demand high energy, and it’s evident that computation-intensive applications require more power and drain the batteries of devices quickly; thus, demanding expensive options or solutions [10].
Figure 1 lists several critical issues faced by IoT, in the paper focus of the study is that using the computation and data offloading in middleware architecture design can aid in dealing with the huge data generation and its processing challenge, also context awareness and device management issues. Architectures serve as a building blocks to fulfil all the essential requirements to solve the fundamental problems faced in IoT [11].
The architecture of internet of things
Limited knowledge and work in the present scenario resist the researchers to get through the scope of the Internet of Things. Middleware plays a vital role in IoT services, and this paper study the role of middleware and its scope to deal some of the critical challenges like time delay, energy consumption, scalability and big data management, etc. using offloading frameworks. Offloading frameworks are part of architectures to improve the overall functionality of IoT applications by developing a better understanding of the associated tool, technologies, and methodology. Its primary purpose is to solve real-life problems using and developing IoT concepts for day-to-day tasks [12].
The architecture serves as the most basic and essential block structure for IoT, and it is vital in terms of design choices for functional and non-functional requirements in IoT environments to serve the increasing scale and complexity of IoT.
Figure 2 shows the basic five-layer general IoT architecture where the bottom layer is perception and sensing layer, this is the physical layer and forms the connection between the real and the digital world. The role of the transport layer is transporting data among different devices and objects. Enormous sensors lead to a massive amount of data generation necessitating IoT system to be a flexible and high-performance network structure to support different protocols among these devices adequately. Processing layer also called as the middleware layer, analyses and process the data coming from the transport layer. This layer uses large numbers of technologies for analysing and processing work. Massive databases are used for maintaining the data and edge, femto, fog, and cloud computing schemes are used for processing tasks containing big data [1]. Temporary data storage functionalities, data duplication and distribution is provided by a storage layer. The top-most layer of the architecture is the application layer and provides application services of the IoT system to users.
Smart solutions
Edge and fog computing and its integration with cloud computing are one of the promising solutions to address many challenges faced by IoT applications, service-related problems and the limitations of cloud computing [13], Middleware plays a significant role to deal with such challenges and support the delay-sensitive and context-aware services in IoT applications by creating the smart gateway for edge/fog server structures. Local computing and nearby devices can perform a large amount of processing instead of carrying out all storage of data and computing in clouds clusters and thus provide timely and intelligent services.
Computation offloading is a scheme to achieve various performance parameters mainly to reduce the consumption of energy and latency of service among the IoT devices. With the help of offloading, resource-efficient edge/fog computing for IoT applications can be achieved, to provide smart services to the users.
Offloading criteria
Understanding the data and its context plays a vital role in offloading. Some criterion is listed in Fig. 3 that acts as a measure to take an offloading decision. Middleware by working as a smart gateway acts as a crucial mediator to monitor the nodes and decide the offloading of applications and services.
During the extreme computation requirement or under constrained resources or when the processing requirement of applications is more than the potential of the native device, devices are not able to fulfil the requirement of processing, and computation. This leads to delay or latency, which is critical to specific delay-sensitive applications. Load balancing is another criterion when the server has reached its maximum limit of processing the tasks, and jobs can be dispersed among other servers using offloading. Offloading is beneficial in the above cases and also this may help in securing the privacy and security of data at edge, femto cloud, or at fog cloud [14,15,16,17].
Related work
A systematic review of literature is carried out starting from the basic understanding of context, its role in IoT, how context awareness can help in offloading tasks, decision and role of machine learning and deep learning that can aid in recognition of context and taking an offloading decision based on it. A detailed review and comparative study are carried out of various models and offloading frameworks.
Role of context in offloading
Many researchers define context as understanding the situation of some events, Abowed et al. [18] defined context as the information that can be used to characterise the status of an entity. Context-aware or sensitive applications, look at the details of the data for understanding the behaviour of applications and requirement of services, to identify who’s, where’s, when’s and what’s of entities, to utilise the information to decide why the situation is occurring or taking place [19].
Context-aware computing requires both sensing and increasingly learning, as the data coming from the physical devices and sensor sources are large in amount and of continuous nature, making learning and gathering inferences tough. Big data and machine learning, aids by providing similar techniques for processing massive data sets [20]. Several big data techniques, learning algorithms like neural and deep learning, etc. are used to analyse data for IoT applications and services.
To recognise and distinguish the affective context from data, Nalepa et al. [21] showed the integration of context-aware systems with the affective computing prototype. Based on this knowledge, models, which interpret effects, were identified. Activity patterns are important during understanding and learning from data, recognition of patterns inference the knowledge and help in the identification of the context and situation. Researchers are mostly focussing on the implementation of computationally pervasive frameworks to make high-level conceptual models [22].
Under the current scenario, the middleware system architecture suffers by falling short in services and resources [23]. Middleware can provide essential services like collection of data from sensors, its processing and context recognition [22]. As achieving energy efficiency is a major challenge in context-aware applications as there are a continuous extraction and inference learning of data from sensors, there is a need of middleware design that can support context-awareness among application development task.
Offloading for IoT applications
As of now, there are a large number of devices and applications as part of IoT. There is a shift in the requirement of services towards computation and power management. The purpose of computation offloading architectures is to deal with such challenges and process the vast amount of data generated by IoT devices.
Ren et al. [24] proposed a Software Defined Network (SDN) to counter the challenge of generation of Big data across the different geographical locations, an adaptive recovery mechanism using support vector machine is given as solution. In [25], Mobile Edge Computing (MEC) devices are used, and to identify the offloading rate, current battery level of the devices is used. A reinforcement learning-based computation-offloading framework is presented for IoT device. Q-learning model with the combination of deep learning and hot-booting to increase the learning speed is shown.
For many large computation-intensive applications, there is a requirement of other entities to execute the tasks in place of a client device and getting results after processing [26], such mechanism is referred as offloading, where jobs are outsourced. This kind of offloading can be done in between sensors (edge devices), fog or cloud devices, but it turns out to be challenging to perform the real-time or actual processing due to the considerable distance between the cloud and end-user devices. Middleware can address such issues by acting as a smart medium in the middle of end nodes and the cloud. Mobile edge computing, cloudlets are some of the middleware technologies proposed to handle such offloading scenarios. Aazam et al. [27] described the offloading procedure, where the nodes close in proximity of client node that is the receiving node must be involved in the task of offloading for meeting the delay-sensitive requirements of applications. Offloading of tasks needs an intelligent system that can make optimal decisions about whether to offload based on the energy trade-offs and which specific task to be offloaded to the cloud, or a local fog or femto-cloud.
Authors in [28] proposed a partial flooding algorithm, and given an offloading methodology for Internet of Vehicles (IoV) to improve the overall utilization of system. For the reduction of time and energy consumption for mobile devices, a multi-objective optimisation technique is proposed in [29], here Computation Offloading Model (COM) is proposed for IoT-based cloud-edge computing.
With the perspective of context-awareness, many learning solutions and systems have been developed in IoT. These solutions are mainly designed-based, logic-based, and ontology-based, and developed using supervised, unsupervised, and reinforcement algorithms. A hybrid or a mixed approach can be designed to improve them. Deep learning, neural networks can be merged as a novel technique [30].
In the next section, we will be discussing the several IoT offloading frameworks and their major objectives and working parameters.
Offloading frameworks
There are different methodologies vide which the research network has learned different ways to implementing offloading frameworks, the various categories under offloading are: partition of applications, where applications can partition category wise [31], migration of threads, where first threads of applications are created then offloaded [32], migration of the application to the server-side, and distributed offloading [33]. Various internal and external factors like the requirement of applications, condition of network and device computing capabilities, etc. influence the decision of offloading of computation-intensive applications. These internal and external factors affect the offloading decision whether, where and when the offloading should be done.
Edge and fog computing are becoming a promising solution to lessen a load of computation from the cloud. This aids in delay-sensitive and context-aware applications by providing timely services. Instead of using only a cluster of clouds for data storage and performing all the computation processing, edge and fog computing try to utilise the maximum benefit of local computing.
MAUI [34] based on smartphones to make them work longer with code offloading, works on the principle of managed code, which reduces the load on the coder. Program partitioning is used to increase the energy benefits. ThinkAir [35], another model that works on the principle of smartphone virtualisation in the cloud, dynamic allocation of resource and parallel execution, is used for code offloading. Lin et al. [36] implemented a Context-Aware Decision Algorithm (CADA), a decision engine-based approach to decide whether to offload a given method to the cloud servers. CADA algorithm was integrated with ThinkAir.
MobiByte, a context-based model, proposed, is a cloud-based progressive application model for mobile cloud computing. It uses multiple data offloading schemes to increase smartphones devices applications performance, energy efficiency, and execution support [37]. Eom et al. [38] presented a mobile offloading framework called Machine Learning-Based Mobile Offloading Scheduler (MALMOS), having a novel approach of using online machine learning algorithms. It makes the assumption of attributes as independent of each other and also has a drawback of biasing towards earlier observations.
Majeed et al. [39] presented code offloading using Support Vector Machine (SVM), which is an adaptive and dynamic mobile system to take the offloading decision locally or remotely. AnyRun Computing (ARC) [40] uses a dynamic offloading model to choose the most capable nearby local computing infrastructure to support offloading structure. In ARC for offloading, not only the nearby devices are considered, but peer devices can also be taken to perform offloading as code can be run anywhere on any device structure. A round-robin scheduling based offloading approach is used in the Autoscaler [41] to allocate the load among the available servers. It consists of three parts, back-end consisting of servers that act as surrogates, front-end to receive the incoming requests, and load simulator to generate the multiple offloading requests.
An edge-based computing framework was proposed in [42] to help smart city residents by providing situational awareness. The presented framework showed that delivering relevant and essential services to the city residents would be beneficial by processing the IoT data at the edges. This would aid the decision-makers to be situation-aware and deliver services to the people. It is helpful in terms of latency and provides inferential knowledge to city residents. Results showed that using the edge computing services, the requirement of data that needed to be shifted to the remote server decreased significantly. The only limitation of this model is task allocation on edge devices is done based on fixed window size.
Another model named Evidence-Aware Mobile Computational Offloading (EMCO) [43] toolkit and platform is a cloud-based model designed as a new solution to solve the challenges faced during computational offloading. For the categorisation of the contextual parameters and other important factors on the offloading decisions, it makes use of the crowd sensed evidence traces. In this framework, models are constructed in the cloud and are sent to mobile devices; therefore, raw processing of data is not done.
Nakahara et al. [44] proposed a Context-Sensitive Model for Offloading System (CoSMOS). It is a self-adaptive offloading system and works based on the context-aware mechanism for mobile cloud computing (MCC) systems. An Adaptive Job Allocation Scheduler (AJAS) [45] to reduce the job reallocation delay time is proposed, it uses user behaviour pattern to requests the allocation of jobs to other nodes when the user's applications are being executed. Dynamic Energy-Efficient Data Offloading (DEED) framework given by Yan et al. [46] for IoT applications is based on an unstable channel state in the communication model and was proposed for task reliability, energy consumption, and device reliability model. The authors of Energy Efficient Offloading Strategy (EES) [47] developed a new bi-objective model based on firefly technique, which looks for the most advantageous computational device.
MobiCOP-IoT [48] framework uses the concept of surrogates, and it deploys them on both far-end clouds and nearby nodes. These nodes are edge-based and offer several features like automated self-regulating offloading of arbitrary tasks based on the output of an integrated decision-making engine. Having rich features, but still, MobiCOP-IoT needs manual configuring to decide whether the structure should work in cloud or edge mode. A Mobile Edge Computing (MEC) [49], based on an adaptive framework that supports mobile applications with offloading is proposed. It enables the application to dynamically offload among the mobile devices, edges and the cloud. An estimation model and unique design pattern based on DPartner, is proposed to decide the offloading scheme.
A content-based offloading mechanism for Mobile Edge Computing is proposed [50] in which the offloading is based on data transmission rate, built on which the contents are partitioned into separate categories. The transmission rate is considered to identify the priority; users having a low transmission rate are regarded as lesser priority work and offloaded first. It is considered that data having low priority will be having lower utilisation of Small Base Station (SBS). In case the SBS traffic exceeds the threshold, then the resources will be offloaded to the WiFi—app first. A code offloading edge/fog mobile-based Autonomic Management Framework is a computation-offloading model for mobile fog environment [51]. The main components of the framework are fog nodes to support parallelism, code analyser unit identify the basic blocks that are computation hungry and require resources. Resource availability and network status are considered for computing latency and resource demand.
Junior et al. [52] proposed a Context-Sensitive Offloading System (CSOS), which is a machine learning-based framework using J48, JRIP, IBK and Naive Bayes reasoning techniques. The authors selected two techniques—J48 and JRIP for the implementation as these provided the best accuracy to make offloading decisions. The Fog Computing (FC)-based analytical model is proposed for IoT-based healthcare applications [53]. These services are critical in terms of latency, and therefore, require fast processing. The overall latency in communication must be reduced, like computation and network latency for IoT data transmission. An edge-based structure is proposed as a solution for the problem, where edges are used for processing and analysis of data to reduce high latency.
Table 1 lists the authors with the objectives of their models and frameworks, and it also lists the offloading architecture specifying the basis and techniques of offloading used by them. The main aim of a large number of frameworks is to reduce time and energy consumption. The offloading frameworks are classified into two broad categories [54], Virtual Machine (VM) cloning, and Client–Server communication frameworks. In VM clone, the whole application is made on the cloud server by transferring application completely with its operating system; is therefore termed as full image transfer. After finishing the task, the cloned VM state is merged with the client to resume the execution. Client–server frameworks, works using communication protocols to achieve offloading, where only logic imitation termed as replication of logic part is done by pre-installing application part on the server device. Offloading frameworks mainly differ in their techniques and basis of implementation.
Table 2 presents a detailed study of different frameworks, including the data sets or real-time environment for their working, parameters used by them and their offloading and simulation environment. It also details the tools, technologies and the implementation used by the frameworks.
In the present scenario for large-scale IoT applications and systems, the offloading architecture is understudied. Due to a lack of understanding of contexts and situations, offloading is not favoured for large offloading environments. Consequently, there is poor usage and allocation of resources on the cloud, and the study of offloading have mostly shown that instead of benefiting, offloading increases computational effort.
From Tables 1 and 2, we can identify that Client–server model is a better choice over the VM model for the offloading purpose as it saves bandwidth consumption and more near to the real-world situations required for data offloading. Also, most of the frameworks are mobile-based, and therefore, mobile and gaming applications are mostly used for the implementation purpose with cloud-based offloading scenario.
From the literature reviews, it has been identified that very less work has been done on edge structures and edge-based cloud scenarios, and the working models and frameworks based on them were not focussed on the smart requirements or understanding-based offloading approach. Instead, mostly fixed scheduling schemes were used.
Materials and methods
A total of five frameworks having different simulation, working environments, datasets, and working parameters, have been shortlisted for the implementation study. All these models are chosen based on their effective, accurate, and novel approach towards offloading.
EMCO framework
A novel computational offloading approach was given by Flores et al. [43], in which the solution in the form of a toolkit and platform was designed for offloading, for implementation resources are available as open-source on GitHub. Crowdsensed evidence traces were used to categorise the influence of different contextual factors and other parameters on offloading decisions. A simulation environment for the framework is Google Cloud Messaging, LAPSI cloud-based runtime, C4.5 Decision tree classifier with fivefold cross-validation environment based on the Dalvik virtual machine. Implementation is done on lightweight compiler for executing the code. The results obtained from the EMCO framework are in the context of the time taken from a range of 1–30 s to execute on different devices and cloud environment, including pre-caching techniques. The maximum energy consumption in the local scenario was approximately 10,000 J.
In Fig. 4a, the average execution time is calculated for both the applications of chess and backtracking. The time represents both summations of processing time and communication latency. Similarly, Fig. 4b shows the average energy consumption. Only a single local mobile device is taken, which shows that the local device consumes more time and energy for the calculations.
This model had considered only the cloud approach for offloading having smartphone implementation only. Approximate average execution time and energy consumption is 8.33 s and 391 J on surrogate’s cloud excluding requirements of the local execution of the devices.
MobiCOP-IoT
Frameworks given by Benedetto et al. [48] contain surrogates set up as distant clouds and proximate nodes at the edges to enhance the capabilities of resource-constrained devices. Various scenarios were used to examine MobiCOP-IoT; both with the centralised cloud and edge distribution, and performance measurements taken were based on time and energy to complete multiple tasks of the gaming applications. Figure 5a and b show edge computing is having the benefit in terms of performance parameter mentioned as time consumption.
On the similar lines, Fig. 5c and d show benefits of edge computing in total consumption of power. The framework is tested on three applications N-Queens, RenderScript and VideoProcessing.
In Fig. 5, improvement can be noticed in edge scenarios, results show that deployments get better in edge-based systems.
Both scenarios were taken when tasks were fully offloaded to the centralised cloud and to the edge servers, as shown in Fig. 5. These benchmarks are available online as open source. The average results of each task are taken after running five times.
Autonomic management framework
Alam et al. [51] proposed an edge/fog-based framework simulated through MATLAB. The N-Queen application is taken to carry out test, Fig. 6a shows the increase in the execution time when the number of queens increased from 1 to 8. Similarly, Fig. 6b shows the raise in energy consumption with the increase in number of queens.
The results from the model tested on dataset with the maximum number of queens taken was 8, variation in time observed was between 25 to 225 s, and energy consumption varied from 10 to 77 J.
Figure 6a shows the approximate execution time mentioned as response time in fog nodes and Fig. 6b shows approximate energy consumption, here eight fog nodes deployed to represent the 8-Queen problem. However, the model was not suitable when the number of queens increased to more than eight.
CSOS framework
Junior et al. [52] proposed a context-sensitive machine learning-based offloading environment (CSOS). Based on the implementation of a classification algorithm, a middleware is designed to work on a robust profiling system. Mobiles are very dynamic in nature; there is a need for an adaptive environment for them. By implementing the classification and profiling, a highly accurate decision engine way designed for mobiles. 10-fold cross-validation was used for training and testing purpose, and it achieved the accuracy of around 95%. The source for the implementation automation program is openly available on the GitHub.
Figure 7a shows the average execution time with an increasing interval of 5 tasks under the contexts data set. The graph shows the execution time as favourable, unfavourable, and unknown contexts of BenchFace & BenchImage application. J48, JRIP & Cloudlet simulations are taken into consideration, and the best time of the model at a particular task is taken into consideration for the calculation.
On similar lines, the average power utilisation is shown in Fig. 7b for BenchFace, BenchImage & CollisionBalls application, and its results show that in the favourable condition, JRIP is more efficient in terms of consumption of energy than the cloudlet and J48 strategy, and it has a smaller number of rules and needs less classification time. In an unfavourable context, J48 and JRIP show promising results by choosing to process locally. Unknown contexts show that for offloading of the computations, JRIP yields better outcome and results in lesser time for execution with lower consumption of energy.
Under the results shown in Fig. 7, the local strategy is not considered as it does not make use of the CSOS framework of offloading, and all processing is done on the smartphone. Further, in this framework, only cloud structure was taken for implementation of offloading structure on a mobile cloud with J48 & JRIP classifier.
Fog computing framework
A fog-computing framework-based analytical model proposed by Shukla et al. [53], aims at boosting the cloud-based computations by bringing them near the edge devices. A framework was designed for a healthcare system to incorporate the analytical model and hybrid fuzzy-based reinforcement-learning algorithm. iFogSim simulator was used for implementation that includes fog devices, ECG sensors, and cloud servers. Five physical arrangements topologies were used, as shown in Fig. 8.
Simulation setup was implemented on iFogSim (Net-Beans), Spyder (Python), skfuzzy API to model the fuzzy system & Java APIs. ECG data set available on the UCI machine learning repository was used, with parameters already specified in the paper mentioned in Table 2.
Results in Fig. 8a and b show physical topology configurations, and this framework showed improved performance and efficiency by minimising latency. Very few parameters of the data set were selected, as in case of health scenarios the accuracy of the results is critical. There might be a rise in overall latency, with the increase in number of parameters or increasing the size of dataset. But this model needs to be tried out with more parameters and larger dataset to formulate for obtaining desired improvement regarding overall latency, consumption of memory and network.
This section presents that EMCO framework; consider only cloud approach towards offloading with the average execution time of 10 s over six cloud surrogates and average energy consumption of 389 J over five cloud surrogates. MobiCOP-IoT working based on mobile applications showed that edge processing is beneficial over cloud processing. Still, there is a big rise in execution time and power consumption with the increase in the size of an application. For different applications on different devices, the range of average execution time is from 4 to 20 s, and the overall energy consumption is approximately from 10 to 195 J. In the Autonomic framework, the execution time extends beyond 200 s, which is comparatively higher than other frameworks. Here the size of application decreases the performance and energy consumption that goes around 80 J.
Like MobiCOP-IoT, CSOS framework is also a smartphone-based framework. The average variation of execution time is 4 s in case of favourable context, 17 s in unknown context and 103 s in unfavourable context cases. Similarly, the variation in the energy consumption in three different contexts is 0.5, 1 and at max 1.5 J/s, respectively. Similar to EMCO framework, CSOS is a cloud-based model without considering edge processing. The increase in the number of tasks adversely affects its performance. Fog computing framework based on edge processing working structure, is same as in EMCO and Autonomic framework in terms of non-smartphone-based application and gives an average delay of 0.8 s with more than 85% network and 25% memory consumption. This model gives a good performance in terms of time in general application scenario but required testing when data size increases as other frameworks have large data set over this.
After analysis of the implementation of different frameworks, it can be stated that most of the devices do not have any built-in framework for offloading computation and switches for manual offloading. There is a need for smart middleware gateway design that can work as a solution with the smart-devices operating system to perform the efficient offloading. Designing the middleware which can learn from the sensory data, battery behaviour, context inferences through machine learning and processing of that data, are the major challenges faced, as most of the available solutions are rule-based or logic-based. There is a scope of further improvement using hybrid methods and learning algorithms in future.
Comparative analysis and discussion
Under this section, some frameworks are taken for comparative study with the frameworks analysed above, based on several performance parameters, models are compared. These frameworks have their working conditions and environment discussed in detail in Sect. “Related work” and Tables 1 and 2.
MAUI is remotely executed on the server with WiFi with Round-trip time (RTT) of 10, 25, 50, 100 and 220 ms as shown in Fig. 9a and b.
In this, three applications are taken for performance and energy consumption parameters running standalone on the smartphone, which are video game for 400 frames and 30 moves for chess game and face recognition application, are taken. MAUI is tested on smartphones with mobile applications and uses program partitioning methodology.
Figure 10a shows the mean time execution and Fig. 10b shows the energy drain for ARC framework, here nexus smartphone is used to run all benchmarks to attain a baseline performance in three modes. The three modes are fixed network topology, full connectivity-based dynamic network topology, and emulated dynamic network topology.
In AutoScaler, execution time is based on the minimax algorithm, and varies on different surrogates as that can be seen in the Fig. 11a.
In Fig. 11b, edge computing framework, edges are used for offloading data, storage, processing, and privacy protection. For the partitioning of data for offloading to the edge devices fixed window size approach is used to sample the sensor stream data.
In Fig. 12a and b, the average of the total time taken for execution and their mini-max values are specified for both N-Queens and BenchImage applications.
In Fig. 13a, the average of total energy consumption for N-Queens application is taken and in Fig. 13b, the average for total consumption of energy for BenchImage application considered. Here min–max values are specified for both the applications. The three environment chosen for the analysis are cloudlet WiFi, cloud WiFi and cloud 3G.
From the Figs. 12 and 13, it can be said that, application size and physical distance among the devices and remote servers have a significant influence over the system as the offloading time rises with the transfer time of the dataset.
From Fig. 9, it is observed that the Round-trip time significantly affects the execution time and energy consumption of the applications. A sudden rise represents that this model is highly dependent on the size of the application similar to observed in frameworks like MobiCOP-IoT and Autonomic frameworks.
ARC framework from Fig. 10 represents the mean execution time and energy drain using application datasets described in Table 2. The execution time varies from 11 to 20 s with an exceptionally high-power consumption of around 300 Joules in two modes and about 600 J in ARC dynamic mode. This approach may waste resources during offloading done by the inference engine, which ignores the impact of remote devices for offloading.
AutoScaler can be referred to as a predecessor model of EMCO considering cloud approach, and it takes approximately 16.02 s over 11 devices, which is relatively higher like ARC. If the local devices are not considered, then the average computation time is about 13.6 s, and this, including communication latency and processing time. The main consideration point here is that the cases used are not a realistic practice as a smartphone.
Another framework based on edge computing structure is discussed to process the IoT data [42]. This model resembles the Fog Computing model [53] from the material and method section. This model takes 0.102 s (sec) in offline mode for CityPulse data set, 0.4 s for the Chicago park data set to calculate the results using edge processing. The total processing time in the real-time scenario is approximately 4.35 s, which includes sensor processing time of 0.352 s, edge to cloud network delay of 0.256 s, overall processing time in edge and cloud are 3.5 s and user delay is 0.243 s. Here the only disadvantage is that, fixed window size approach is used during data offloading, which is a rigid approach for all kinds of data whereas Fog Computing model uses the reinforcement learning approach but dataset size used is small and can’t be relied for real world applications.
A Context-Sensitive Model for Offloading System (CoSMOS), which is a mobile-based cloud computing offloading decision support model, also termed as self-aware and self-expressive system was proposed [44]. Two mobile applications, N-Queen problem, and BenchImage for image-processing applications used, with the focus on the CPU processing time. Over these applications, N-Queens have a relatively small dataset and BenchImage have a large data set. In the case of N-Queens, the number of queens taken is between 4 and 13. However, when taken number of queens taken are 14 or more, then the processing time and energy consumption increases drastically. For BenchImage application, five different resolutions of three pictures are handled within a range from 0.3 to 0.8 MP.
From the implementation, analysis, and comparison of different frameworks, it is observed that most of the structures are tested on gaming applications and are mobile-based. Their efficiency is affected by the bulkiness of the applications. Edge Computing paradigm and Fog computing frameworks discussed show some useful practical life data set implementations and shows promising results in terms of various parameters like time, energy, network, and system utilisation. However, some of the direct methods used for offloading create a scope for some hybrid, regression, and learning-based approaches for offloading. Scaling-up the requirement of services needs to be handled under offloading architectures, to manage the particular load of the devices. Proper planning for the capacities is required to identify the adequate number of back-end servers.
Future research challenges
There are several challenges in IoT from heterogeneity among the devices, their data to device management, context awareness and processing of information [5]. It has identified that, irrespective of application areas, there are some common key issues that keep on existing, like inherent distribution, data management and making human centric applications [74]. Today cloud services are required to give stable Quality of Service (QoS), as these can be reused. A cost-effective approach is required to provide cloud service composition [75]. Offloading appears as solution for IoT applications and devices but it is not as straightforward as it seems to be, raising further, several challenges from this fusion of technologies. To overcome the problem of computing power limitation, storing capability, and limitations of built-in batteries, the offloading of computations are critically important [45].
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Understanding the context, situation, or status of data and learning from them for computational and data offloading is among the major problems and can have a high impact on making systems and applications as a part of intelligent IoT services [51].
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Most of the designed solutions are based on rules, logic and ontology using supervised and unsupervised learning, along with reinforcement algorithms. There is a scope of improvement using hybrid methods, such as neural methods and deep learning algorithms to achieve better performance [29].
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There is a need for an intelligent system that can make optimal decisions about which specific tasks to be offloaded, to the cloud or Femto-cloud. Designing the middleware which can learn from the sensory data, battery behaviour, and context inferences through machine learning and processing of the data are quite challenging. Middleware devices encounter limitation during providing service due to resource constraints in terms of power, memory, and bandwidth [23, 24].
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Many IoT applications require separate entities to compute and process the tasks on behalf of user devices, like smart home, healthcare, intelligent transport management, Ambient Assisted Living (AAL), Virtual Reality (VR), etc. to produce the results. It becomes challenging to provide real-time computations and delivering fast responses due to significant distance among the cloud servers and end-users [26, 27].
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During transmission and computing for offloading the IoT applications to the cloud, there is the consumption of a large amount of energy because the far-end network experiences a higher latency and network delay. Edge and Fog nodes provide solution and offer the cloud services at near end edges of the network, and this makes IoT applications to run locally with minimum energy utilization and reduce the delay. However, such a structure has a limitation in terms of resource capacity. Resource-intensive IoT applications suffer constrained resources issue under edge/fog nodes implementation [46, 50].
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Current studies in the field of offloading are more focussed on centralisation and coordination of data. Edge computing and fog computing are new areas of research and need establishing frameworks to put these concepts into practice [51].
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Identification of the situation is a crucial issue to take the offloading decision as all of them are not beneficial, and a primary challenge is to identify those situations. A large number of factors influence the efficiency of offloading for making practical and optimal offloading decisions [42].
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The key research issues for offloading computation in fog or edge structures are choosing the approach to offload computation, the module or procedure of applications to offload, and where to offload for minimizing the latency of service computing [47].
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There is need of a smart, intelligent and selective offloading scheme to formulate the decision of whether to offload computation, when to offload and where to offload the tasks, like across local devices at edge level, to the fog cloud, or the cloud structure in proximity.
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Most of the solutions designed are single reasoner, or mobile-based, and therefore, mobile and gaming applications are used for the implementation study and very less work has been done on IoT applications and their implementation on edge-based cloud scenarios, and the working models or frameworks based on offloading with such scenarios have not focussed on the smart requirements or understanding-based offloading approach. Instead, mostly fixed scheduling schemes were used.
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With the results obtained in figures and graphs it can be seen that for most of the applications, their efficiency is affected by the bulkiness of the applications, with the efficient deployment of fog/edge scenarios and smart offloading scheme we can deal with such issues.
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Direct methods used for offloading create a scope for implementation of some hybrid and learning-based approaches for offloading. Such methodologies can take advantage of the reasoning techniques to provide offloading decisions, as higher latency and delay makes the data meaningless and inadequate for end-users.
Conclusion
In this paper, a detailed implementation analysis and comparison of various data offloading frameworks has been carried out, with the aim of understanding and analysing the role of context or situation to perform the data offloading. Some of the existing frameworks based on their novel approach and optimum results are taken for implementation. Under the analysis of implemented frameworks and their comparison with some of the existing frameworks, it has been identified that to meet the performance requirements of IoT enabled services, offloading play a crucial role. From the work carried out it also has been identified the size of the applications play crucial role for achieving adequate performance as increase in time and energy consumption can be seen in the graphs under the implementation, some intelligent approach is required to deal with large data size of applications and then perform the offloading to perform computations.
From the experiments done and results obtained, it has been deduced that offloading is not a straight way approach, rather before offloading some learning of context of data is required which will aid in taking correct decision like where and when to offload. Under the implementation scenarios, it has been seen that some learning methodologies were used in few implementations, but mostly was performed under mobile-based scenarios, there has been scope of improvement by implementing smart middleware design using hybrid learning mechanism to implement the computation offloading.
It also has been identified that there is a future possibility of work in edge structures and edge-based cloud structures for offloading frameworks, as very little work has been done in such scenarios and also mostly fixed scheduling schemes were used which can be improved.
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Acknowledgements
This work has been carried out in wireless sensor network research facility in Computer Science and Engineering department of Chitkara University, India. This research facility has been funded from the in-house grant of Chitkara University.
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Bajaj, K., Sharma, B. & Singh, R. Implementation analysis of IoT-based offloading frameworks on cloud/edge computing for sensor generated big data. Complex Intell. Syst. 8, 3641–3658 (2022). https://doi.org/10.1007/s40747-021-00434-6
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DOI: https://doi.org/10.1007/s40747-021-00434-6