A Federated Learning protocol built on Proof of Stake to establish Economic Security in the network. The architecture is built on top of micro-rollups to provide verifiable off-chain computation for state management and providing slashing conditions.

Federated Learning is a privacy preserving scheme to train deep learning models. Data exists in isolated pools and clients that are part of the network train a model with base parameters on their own individual data. They share the updated model parameters with an aggregator that takes the federated average of this set of models. The result is going to be a new updated base model for the next epoch of training.

In a network of clients, you have to ensure that they are training models honestly so that the accuracy of the model improves. You can have malicious clients in a network that can sabotage the network and reduce model accuracy. We can solve this problem by leveraging a Proof of Stake architecture.

A user can onboard on our platform and require a particular type of model by specifying their requirements like number of epochs or a desired accuracy of the model. The protocol we built has a set of clients that have data and they train models for our users. We have an aggregator that performs federated learning on this network. The clients are made to stake a set STAKE_AMOUNT into our StakingRegistry contract. This stake can be slashed by the SlashingManager which disincentivises any malicious behaviour.

In order to ensure spam resistance on the network, the user is made to pay an initial set BASE_FEE. After the model reaches a desired level of accuracy as per the user, he/she is charged accoridng to the number of Epochs and price per epoch for their model. The fees paid by the user is distributed amongst the protcol and the clients which is managed by RewardManager contract.

FLockChain uses Stackr to develop a micro-rollup on top of the network of clients. This rollup will act as a Model Parameters Sharing (MPS) Chain which will hold the state of the model parameters for each epoch. This is essential as their needs to be a verifiable track of the updated parameters shared by each client.

The rollup architecture also allows for off-chian verifiable computation where the slashing conditions are implemneted. The State Transition function of the rollup does the slashing checks offchains and maintains a state of the model parameters of a client as well as whether or not it should be slashed for that epoch. The aggregator fetches the state after each epoch and if a client is malicious, it calls the SlashingManager and slashes the stake of that client.

The Slashing conditions that are implemneted in the rollup check for correlation between the base and the trained models and the existence of outliers in the set of clients. The Krum function is used to set a score for each of the clients for that epoch. It is the sum of squared distances of the tensor value of that client with all other clients. The assumption of this function is that the majority of clients are honest and hence will have model parameters which are very similar to each other. The tensor value associated with a sharp contarst in Krum score is likely a bad actor.

Apart from outliers that reduce accuracy, their also exists free riders that may not train the model but wish to reap the benefits of the network. We have implemented checks that mesure the correlation between the model parameters of the previous and current epochs. If they are quite similar, the client has likely made no significant improvements and hence will have a to face a penalty.