Non-iid data and Continual Learning processes in Federated Learning: a long road ahead
Yüklə 1,96 Mb. Pdf görüntüsü
|
|
Fig. 6. Classification of the different techniques able to deal with the temporal
heterogeneity in the behaviour of the data samples. to establish relations between the different strategies results. In this case, nonetheless, most of the works we just presented compare their methods with EWC [ 143 ], using it as a baseline. In [ 143 ], the MNIST dataset is employed to simulate the different input data distributions. They take a random permutation of pixels and apply that permutation to all of the images to create each input domain. With this strategy, they only need one dataset, denoted Permuted MNIST, to simulate any number of domains. In [ 144 ], authors compare the accuracy ob- tained with their learning method (P&C) in each domain, and also the mean accuracy, with EWC, showing that P&C achieves slightly better results avoiding catastrophic forgetting. That also happens in [ 139 ], where CLEAR method is compared with both EWC and P&C. CLEAR outperforms EWC in most situations, and attain very similar results to P&C. [ 140 , 145 ] also use the permuted MNIST dataset and improve the mean accuracy of EWC, and some other methods they compare with. Lastly, generative strategies like [ 141 ] prove to be efficient to prevent catastrophic forgetting. They use the datasets MNIST and SVHN to show that the performance is barely affected when they change the input dataset. 5.2. Real concept drifts In this kind of situation, the users are allowed to change the task they are performing during the training process. In Section 3.3.2 we highlighted the necessity of a model designed in a way such that different clients can have distinct outputs even though they own similar inputs. However, our interest now is pursuing a model able to flip from one output to another for the same client in different timestamps. To overcome this challenge, there are two kinds of strategies: On the one hand, we have Contextual Information Methods, and on the other hand, we have Architecture-based Methods, see Fig. 6 . The approach of Contextual Information methods is closely related to the one we talked about in Section 3.3.2 [ 108 ]. That work discussed the possibility of adding a piece of information 𝑧 to the original data inputs, such as a task identifier or a domain identifier. This information 𝑧 could be designed to address both the multi-domain and the multi- task issues in a variety of situations besides the one presented in the article. Some more research articles in this line are [ 146 – 148 ]. The authors of [ 146 ] claim the sought tasks affect the process of training, and propose using a task identifier to achieve personalization. The other approaches [ 147 , 148 ] also rely on some kind of contextual information to determine the task corresponding to each data sample, and on the whole, they act as if they had a specific network for each of the tasks. In this case, when a new task appears in the training stage, each layer of Table 6 Summary of the datasets employed in the works presented in Section 5.2 . Asterisks indicate that the datasets have been modified in particular ways. Some of the datasets mentioned were not referenced so far: Atari games [ 153 ]. Article Datasets used in experiments [ 146 ] MNIST*; CIFAR-10* [ 147 ] MNIST*; CIFAR-100 [ 148 ] MNIST* [ 149 ] ImagenNet; CUBS; Oxford102Flowers [ 150 ] ImagenNet; CUBS; Oxford102Flowers [ 151 ] ImagenNet; CUBS; Oxford102Flowers [ 152 ] Atari games the network is expanded and the new neurons are used for the current task, but not for previous ones. The other kind of strategies, Architecture-based methods, focus on deep incremental multi-task learning techniques that modify the neural network depending on the performing task, without any forgetting on previous tasks. The most studied way for accomplishing it is using some kind of mask on the neural network. Several works have explored this alternative: [ 149 ], for instance, study the case of having a neural network already trained for one task and make use of a weight-level binary mask to cancel some of the weights, so the resulting network can solve another previously-defined task. This process can be effectively repeated for several tasks without any forgetting of the original one, as the weights are not effectively changed. There is a slightly different ap- proach proposed by the same authors [ 150 ], which consists of starting with a neural network trained for one task, setting some of their weights to zero, i.e, eliminating some neural connections, and retraining the model a few epochs for the initial task. After that, when trying to learn a new task, the already set weights are fixed, and the eliminated connections are reestablished and trained. This method is not scalable to several tasks, as the number of neural connections is limited. Another strategy based on the same ideas uses a ternary neuron-level mask to perform training [ 151 ]. The reasoning behind the use of a ternary mask is that some neurons may be useful for both a new task and a previously learned one, so three possible states are considered for each neuron concerning each task: unused, used but not trainable, or trainable. This paper also faces the scalability problem, as they allow the network to grow if necessary, setting the new neurons as unused for previous tasks in order to not modify their accuracy. On the other hand, authors of [ 152 ] propose a completely different technique. They start with a deep neural network for the first task, and when they are interested in learning a new task, they start a new neural network and create connections from the ones that already existed to each layer of the new one, in order to leverage the knowledge from previous tasks. This strategy is really useful when dealing with related tasks, but tasks that interfere with each other might harm the outcome model. These kinds of methods present a lot of differences in the way they implement their experimental results. Some of them pay attention to the accuracy obtained, while others are more concerned about the error they got, and some others concentrate on the level of for- getting they commit. For instance, in [ 146 ] the authors employ the MNIST dataset with pixel permutation, like in [ 143 ], and also ex- changes some class labels in parts of the dataset to simulate the different behaviours. They compare their results with EWC, LwF [ 154 ], and improve their results. However, they emphasize that this form of simulating the different tasks and behaviours is quite unrealistic. Surprisingly, [ 149 – 151 ] employ the same datasets to perform their experiments: the ImageNet dataset [ 104 ], used for training the pre- trained ImageNet-VGG-16 neural network; the CUBS dataset [ 155 ], and the Oxford102Flowers dataset [ 156 ] (see Table 6 ). This is, as we have seen in this paper, very rare. |