Hi, thanks for your recommendation. I would probably not use this model for real world data as there are many important details that are missing (for the sake of providing a simple overview). I will pin your comment for others that also want to use this implementation. Thank you!

thanks for the kind words :)

Much appreciated!

Bcoz, positional embedding represent the adress or position of image information of image patches

@@trendingtech4youth989 in "Attention is all you need", afaik, positioal embeddings are not learnable

​@trendingtech4youth989 so..they are given like the patches, why shall they be learned

Imagine you have a sentence "I made a pizza and put it in an oven, it was tasty". Here we know that it refers to pizza, but for a model, it could mean pizza is delicious or oven is delicious. Positional encodings are learnt based on each other, the position of it here is with respect to pizza and oven. Therefore it is a learnt parameter. Here the video mentions that it is doesn't have any significant advantage over numbering, but when you are trying to teach the model to identify features, it will identify feature and position of one patch wrt other patches, ergo making it a learnable parameter

It’s not really needed, in the original transformer paper have been tests with learnable pe and basic-not-learnable-sinusoidal pe and that did not make a big difference, gpt2 also uses learnable pe, nowadays it’s more RoPE doing the positional encoding

Hi, have you tried a Lower learning rate? Also is the train loss decreasing or also stuck?

​@@DeepFindr Actually I've already found one bug in notebook. In forward method of Attention module, input is directly passed to MultiheadAttention bypassing linear layers. Changing learning rate doesn't affect training at all. Also, when training I've noticed that model's output converges to all zeros. I've checked gradients in network and it turns out that gradient flow stops at PatchEmbedding layer. All layers after it have non-zero gradients. Still don't know why this happens

Thanks for finding this bug. But I actually think it's not super relevant for this issue - I experimented with the attention previously and tried both ways (with linear layers and without), that's how this bug was created in the first place. When I started the training back then the loss was definitely decreasing, but I didn't expect it to get stuck at some plateau. Typically when models predict always the same class there can be a couple of reasons. I already checked this: - Input data is normalized - Too few / too many parameters (I would recommend to count the model parameters to get a feeling for this) - Learning rate - SGD Optimizer (seems to work a bit better) - Batch size, I put it to 128 - Embedding size, make it a bit smaller After 100 epochs the Loss is also converging to 3.61, but the model is predicting different classes. Maybe the Dataset is not big enough. What about trying another dataset? Alternatively, try data augmentation. As stated in the video, transformers need to see a lot of examples.

Hi! Thanks! There is a paper that investigated pre- VS post-layernorm in transformers (see here arxiv.org/pdf/2002.04745). The "Pre" variant seems to perform better as opposed to the traditional suggestion in the transformer paper. This is also what most public implementations do :)

You should have a deep understanding of transformer architecture to understand this.

Hi! In the forward pass of the PreNorm layer is this line: self.fn(self.norm(x), **kwargs) So normalization is applied first and then the function (such as attention in this example) The line you are referencing is just the initialization, not the actual call Hope that helps :)

@@DeepFindr stupid of me to not see that first. Thank you for the reply

Take a look at gpt4-omni to find out, lol

Hi, please see pinned comment. Maybe this helps :)

yes exactly, I also have same doubt, for me its 192 instead of 324

original image size was 144 (h) x 144 (w), after patch embedding, it was transformed to 324 patches, and each patch has 128 dimension size. 324 was derived from (144/8) x (144/8) = 18 x 18 = 324 patches. 8 is the patch size of each patch.

Hi! I think this is because the Dataset is too small. Transformers are data hungry. It should work with a bigger dataset

Also have a look at the pinned comment, maybe that helps :)

Sora is using DiT (Diffusion Transformer)