Transformer (deep learning architecture)

Last updated
A standard Transformer architecture, showing on the left an encoder, and on the right a decoder. Note: it uses the pre-LN convention, which is different from the post-LN convention used in the original 2017 Transformer. Transformer, full architecture.png
A standard Transformer architecture, showing on the left an encoder, and on the right a decoder. Note: it uses the pre-LN convention, which is different from the post-LN convention used in the original 2017 Transformer.

A transformer is a deep learning architecture that was developed by researchers at Google and is based on the multi-head attention mechanism, which was proposed in the 2017 paper "Attention Is All You Need". [1] Text is converted to numerical representations called tokens, and each token is converted into a vector via lookup from a word embedding table. [1] At each layer, each token is then contextualized within the scope of the context window with other (unmasked) tokens via a parallel multi-head attention mechanism, allowing the signal for key tokens to be amplified and less important tokens to be diminished.

Contents

Transformers have the advantage of having no recurrent units, therefore requiring less training time than earlier recurrent neural architectures (RNNs) such as long short-term memory (LSTM). [2] Later variations have been widely adopted for training large language models (LLM) on large (language) datasets, such as the Wikipedia corpus and Common Crawl. [3]

Transformers were first developed as an improvement over previous architectures for machine translation, [4] [5] but have found many applications since. They are used in large-scale natural language processing, computer vision (vision transformers), reinforcement learning, [6] [7] audio, [8] multimodal learning, robotics, [9] and even playing chess. [10] It has also led to the development of pre-trained systems, such as generative pre-trained transformers (GPTs) [11] and BERT [12] (bidirectional encoder representations from transformers).

History

Predecessors

For many years, sequence modelling and generation was done by using plain recurrent neural networks (RNNs). A well-cited early example was the Elman network (1990). In theory, the information from one token can propagate arbitrarily far down the sequence, but in practice the vanishing-gradient problem leaves the model's state at the end of a long sentence without precise, extractable information about preceding tokens.

A key breakthrough was LSTM (1995), [note 1] a RNN which used various innovations to overcome the vanishing gradient problem, allowing efficient learning of long-sequence modelling. One key innovation was the use of an attention mechanism which used neurons that multiply the outputs of other neurons, so-called multiplicative units. [13] Neural networks using multiplicative units were later called sigma-pi networks [14] or higher-order networks . [15] LSTM became the standard architecture for long sequence modelling until the 2017 publication of Transformers. However, LSTM still used sequential processing, like most other RNNs. [note 2] Specifically, RNNs operate one token at a time from first to last; they cannot operate in parallel over all tokens in a sequence.

Modern Transformers overcome this problem, but unlike RNNs, they require computation time that is quadratic in the size of the context window. The linearly scaling fast weight controller (1992) learns to compute a weight matrix for further processing depending on the input. [16] One of its two networks has "fast weights" or "dynamic links" (1981). [17] [18] [19] A slow neural network learns by gradient descent to generate keys and values for computing the weight changes of the fast neural network which computes answers to queries. [16] This was later shown to be equivalent to the unnormalized linear Transformer. [20] [21]

Attention with seq2seq

The idea of encoder-decoder sequence transduction had been developed in the early 2010s (see previous papers [22] [23] ). The papers most commonly cited as the originators that produced seq2seq are two concurrently published papers from 2014. [22] [23]

A 380M-parameter model for machine translation uses two long short-term memories (LSTM). [23] Its architecture consists of two parts. The encoder is an LSTM that takes in a sequence of tokens and turns it into a vector. The decoder is another LSTM that converts the vector into a sequence of tokens. Similarly, another 130M-parameter model used gated recurrent units (GRU) instead of LSTM. [22] Later research showed that GRUs are neither better nor worse than LSTMs for seq2seq. [24] [25]

These early seq2seq models had no attention mechanism, and the state vector is accessible only after the last word of the source text was processed. Although in theory such a vector retains the information about the whole original sentence, in practice the information is poorly preserved. This is because the input is processed sequentially by one recurrent network into a fixed-size output vector, which is then processed by another recurrent network into an output. If the input is long, then the output vector would not be able to contain all relevant information, degrading the output. As evidence, reversing the input sentence improved seq2seq translation. [26]

The RNNsearch model introduced an attention mechanism to seq2seq for machine translation to solve the bottleneck problem (of the fixed-size output vector), allowing the model to process long-distance dependencies more easily. The name is because it "emulates searching through a source sentence during decoding a translation". [4]

The relative performances were compared between global (that of RNNsearch) and local (sliding window) attention model architectures for machine translation, finding that mixed attention had higher quality than global attention, while local attention reduced translation time. [27]

In 2016, Google Translate was revamped to Google Neural Machine Translation, which replaced the previous model based on statistical machine translation. The new model was a seq2seq model where the encoder and the decoder were both 8 layers of bidirectional LSTM. [28] It took nine months to develop, and it outperformed the statistical approach, which took ten years to develop. [29]

Parallelizing attention

Seq2seq models with attention (including self-attention) still suffered from the same issue with recurrent networks, which is that they are hard to parallelize, which prevented them to be accelerated on GPUs. In 2016, decomposable attention applied a self-attention mechanism to feedforward networks, which are easy to parallelize, and achieved SOTA result in textual entailment with an order of magnitude less parameters than LSTMs. [30] One of its authors, Jakob Uszkoreit, suspected that attention without recurrence is sufficient for language translation, thus the title "attention is all you need". [31] That hypothesis was against conventional wisdom of the time, and even his father, a well-known computational linguist, was skeptical. [31] In the same year, self-attention (called intra-attention orintra-sentence attention) was proposed for LSTMs. [32]

In 2017, the original (100M-sized) encoder-decoder transformer model was proposed in the "Attention is all you need" paper. At the time, the focus of the research was on improving seq2seq for machine translation, by removing its recurrence to process all tokens in parallel, but preserving its dot-product attention mechanism to keep its text processing performance. [1] This led to the introduction of a multi-head attention model that was easier to parallelize due to the use of independent heads and the lack of recurrence. Its parallelizability was an important factor to its widespread use in large neural networks. [33]

AI boom era

Already in spring 2017, even before the "Attention is all you need" preprint was published, one of the co-authors applied the "decoder-only" variation of the architecture to generate fictitious Wikipedia articles. [34] Transformer architecture is now used in many generative models that contribute to the ongoing AI boom.

In language modelling, ELMo (2018) was a bi-directional LSTM that produces contextualized word embeddings, improving upon the line of research from bag of words and word2vec. It was followed by BERT (2018), an encoder-only Transformer model. [35] In 2019 October, Google started using BERT to process search queries. [36] In 2020, Google Translate replaced the previous RNN-encoder–RNN-decoder model by a Transformer-encoder–RNN-decoder model. [37]

Starting in 2018, the OpenAI GPT series of decoder-only Transformers became state of the art in natural language generation. In 2022, a chatbot based on GPT-3, ChatGPT, became unexpectedly popular, [38] triggering a boom around large language models. [39] [40]

Since 2020, Transformers have been applied in modalities beyond text, including the vision transformer, [41] speech recognition, [42] robotics, [6] and multimodal. [43] The vision transformer, in turn, stimulated new developments in convolutional neural networks. [44] Image and video generators like DALL-E (2021), Stable Diffusion 3 (2024), [45] and Sora (2024), are based on the Transformer architecture.

Training

Methods for stabilizing training

The plain transformer architecture had difficulty converging. In the original paper [1] the authors recommended using learning rate warmup. That is, the learning rate should linearly scale up from 0 to maximal value for the first part of the training (usually recommended to be 2% of the total number of training steps), before decaying again.

A 2020 paper found that using layer normalization before (instead of after) multiheaded attention and feedforward layers stabilizes training, not requiring learning rate warmup. [46]

Pretrain-finetune

Transformers typically are first pretrained by self-supervised learning on a large generic dataset, followed by supervised fine-tuning on a small task-specific dataset. The pretrain dataset is typically an unlabeled large corpus, such as The Pile. Tasks for pretraining and fine-tuning commonly include:

The T5 transformer report [47] documents a large number of natural language pretraining tasks. Some examples are:

Note that while each of these tasks is trivial or obvious for human native speakers of the language (or languages), they have typically proved challenging for previous generations of machine learning architecture.

Tasks

In general, there are 3 classes of language modelling tasks: "masked", [49] "autoregressive", [50] and "prefixLM". [51] These classes are independent of a specific modeling architecture such as Transformer, but they are often discussed in the context of Transformer.

In a masked task, [49] one or more of the tokens is masked out, and the model would produce a probability distribution predicting what the masked-out tokens are based on the context. The loss function for the task is typically sum of log-perplexities for the masked-out tokens: and the model is trained to minimize this loss function. The BERT series of models are trained for masked token prediction and another task.

In an autoregressive task, [50] the entire sequence is masked at first, and the model produces a probability distribution for the first token. Then the first token is revealed and the model predicts the second token, and so on. The loss function for the task is still typically the same. The GPT series of models are trained by autoregressive tasks.

In a prefixLM task, [51] the sequence is divided into two parts. The first part is presented as context, and the model predicts the first token of the second part. Then that would be revealed, and the model predicts the second token, and so on. The loss function for the task is still typically the same. The T5 series of models are trained by prefixLM tasks.

Note that "masked" as in "masked language modelling" is not "masked" as in "masked attention", and "prefixLM" (prefix language modeling) is not "prefixLM" (prefix language model).

Architecture

All transformers have the same primary components:

The following description follows exactly the Transformer as described in the original paper. There are variants, described in the following section.

By convention, we write all vectors as row vectors. This, for example, means that pushing a vector through a linear layer means multiplying it by a weight matrix on the right, as .

Tokenization

As the Transformer architecture natively processes numerical data, not text, there must be a translation between text and tokens. A token is an integer that represents a character, or a short segment of characters. On the input side, the input text is parsed into a token sequence. Similarly, on the output side, the output tokens are parsed back to text. The module doing the conversion between texts and token sequences is a tokenizer.

The set of all tokens is the vocabulary of the tokenizer, and its size is the vocabulary size. When faced with tokens outside the vocabulary, typically a special token is used, written as "[UNK]" for "unknown".

Some commonly used tokenizers are byte pair encoding, WordPiece, and SentencePiece.

Embedding

Each token is converted into an embedding vector via a lookup table. Equivalently stated, it multiplies a one-hot representation of the token by an embedding matrix . For example, if the input token is , then the one-hot representation is , and its embedding vector isThe token embedding vectors are added to their respective positional encoding vectors (see below), producing the sequence of input vectors.

The number of dimensions in an embedding vector is called hidden size or embedding size and written as . [35]

Un-embedding

An un-embedding layer is almost the reverse of an embedding layer. Whereas an embedding layer converts a token into a vector, an un-embedding layer converts a vector into a probability distribution over tokens.

The un-embedding layer is a linear-softmax layer:The matrix has shape . The embedding matrix and the un-embedding matrix are sometimes required to be transposes of each other, a practice called weight tying. [52]

Positional encoding

A diagram of a sinusoidal positional encoding with parameters
N
=
10000
,
d
=
100
{\displaystyle N=10000,d=100} Positional encoding.png
A diagram of a sinusoidal positional encoding with parameters

A positional encoding is a fixed-size vector representation of the relative positions of tokens within a sequence: it provides the transformer model with information about where the words are in the input sequence. Without positional encoding, the model would be unable to process input sequence as more than a bag of words, as for example, both "man bites dog" and "dog bites man" would be processed exactly the same way.

The positional encoding is defined as a function of type , where is a positive even integer. The full positional encoding defined in the original paper [1] is:where .

Here, is a free parameter that should be significantly larger than the biggest that would be input into the positional encoding function. The original paper uses .

The function is in a simpler form when written as a complex function of type where .

The main reason for using this positional encoding function is that using it, shifts are linear transformations:where is the distance one wishes to shift. This allows the transformer to take any encoded position, and find the encoding of the position n-steps-ahead or n-steps-behind, by a matrix multiplication.

By taking a linear sum, any convolution can also be implemented as linear transformations:for any constants . This allows the transformer to take any encoded position and find a linear sum of the encoded locations of its neighbors. This sum of encoded positions, when fed into the attention mechanism, would create attention weights on its neighbors, much like what happens in a convolutional neural network language model. In the author's words, "we hypothesized it would allow the model to easily learn to attend by relative position."

In typical implementations, all operations are done over the real numbers, not the complex numbers, but since complex multiplication can be implemented as real 2-by-2 matrix multiplication, this is a mere notational difference.

Encoder-decoder (overview)

One encoder-decoder block. Transformer, one encoder-decoder block.png
One encoder-decoder block.
A Transformer is composed of stacked encoder layers and decoder layers. Transformer, stacked layers and sublayers.png
A Transformer is composed of stacked encoder layers and decoder layers.

Like earlier seq2seq models, the original transformer model used an encoder-decoder architecture. The encoder consists of encoding layers that process all the input tokens together one layer after another, while the decoder consists of decoding layers that iteratively process the encoder's output and the decoder's output tokens so far.

The purpose of each encoder layer is to create contextualized representations of the tokens, where each representation corresponds to a token that "mixes" information from other input tokens via self-attention mechanism. Each decoder layer contains two attention sublayers: (1) cross-attention for incorporating the output of encoder (contextualized input token representations), and (2) self-attention for "mixing" information among the input tokens to the decoder (i.e. the tokens generated so far during inference time). [53] [54]

Both the encoder and decoder layers have a feed-forward neural network for additional processing of their outputs and contain residual connections and layer normalization steps. [54] These feed-forward layers contain most of the parameters in a Transformer model.

Feedforward network

The feedforward network module. It is a two-layered network that maps
d
emb
{\displaystyle d_{\text{emb}}}
-dimensional vectors into
d
emb
{\displaystyle d_{\text{emb}}}
-dimensional vectors. Transformer architecture - FFN module.png
The feedforward network module. It is a two-layered network that maps -dimensional vectors into -dimensional vectors.

The feedforward network (FFN) modules in a Transformer are 2-layered multilayer perceptrons:where is its activation function. The original Transformer used ReLU activation.

The number of neurons in the middle layer is called intermediate size (GPT), [55] filter size (BERT), [35] or feedforward size (BERT). [35] It is typically larger than the embedding size. For example, in both GPT-2 series and BERT series, the intermediate size of a model is 4 times its embedding size: .

Scaled dot-product attention

Attention head

Scaled dot-product attention, block diagram. Transformer, attention block diagram.png
Scaled dot-product attention, block diagram.
Exact dimension counts within an attention head module. Transformer architecture - Attention Head module.png
Exact dimension counts within an attention head module.

The attention mechanism used in the Transformer architecture are scaled dot-product attention units. For each unit, the transformer model learns three weight matrices: the query weights , the key weights , and the value weights .

The module takes three sequences, a query sequence, a key sequence, and a value sequence. The query sequence is a sequence of length , and each entry is a vector of dimension . Similarly for the key and value sequences.

For each vector in the query sequence, it is multiplied by a matrix to produce a query vector . The matrix of all query vectors is the query matrix:Similarly, we construct the key matrix and the value matrix .

It is usually the case that all are square matrices, meaning , etc.

Attention weights are calculated using the query and key vectors: the attention weight from token to token is the dot product between and . The attention weights are divided by the square root of the dimension of the key vectors, , which stabilizes gradients during training, and passed through a softmax which normalizes the weights. The fact that and are different matrices allows attention to be non-symmetric: if token attends to token (i.e. is large), this does not necessarily mean that token will attend to token (i.e. could be small). The output of the attention unit for token is the weighted sum of the value vectors of all tokens, weighted by , the attention from token to each token.

The attention calculation for all tokens can be expressed as one large matrix calculation using the softmax function, which is useful for training due to computational matrix operation optimizations that quickly compute matrix operations. The matrices , and are defined as the matrices where the th rows are vectors , , and respectively. Then we can represent the attention as

where the softmax is applied over each of the rows of the matrix.

The number of dimensions in a query vector is query size and similarly for the key size and value size. The output dimension of an attention head is its head dimension. The attention mechanism requires the following three equalities to hold:but is otherwise unconstrained.

If the attention head is used in a self-attention fashion, then . If the attention head is used in a cross-attention fashion, then usually . It is theoretically possible for all three to be different, but that is rarely the case in practice.

Multiheaded attention

Multiheaded attention, block diagram. Multiheaded attention, block diagram.png
Multiheaded attention, block diagram.
Exact dimension counts within a multiheaded attention module. Transformer architecture - Multiheaded Attention module.png
Exact dimension counts within a multiheaded attention module.

One set of matrices is called an attention head, and each layer in a transformer model has multiple attention heads. While each attention head attends to the tokens that are relevant to each token, multiple attention heads allow the model to do this for different definitions of "relevance". Specifically, the query and key projection matrices, and , which are involved in the attention score computation, defines the "relevance". Meanwhile, the value projection matrix , in combination with the part of the output projection matrix , determines how the attended tokens influence what information is passed to subsequent layers and ultimately the output logits. In addition, the scope of attention, or the range of token relationships captured by each attention head, can expand as tokens pass through successive layers. This allows the model to capture more complex and long-range dependencies in deeper layers. Many transformer attention heads encode relevance relations that are meaningful to humans. For example, some attention heads can attend mostly to the next word, while others mainly attend from verbs to their direct objects. [56] The computations for each attention head can be performed in parallel, which allows for fast processing. The outputs for the attention layer are concatenated to pass into the feed-forward neural network layers.

Concretely, let the multiple attention heads be indexed by , then we have where the matrix is the concatenation of word embeddings, and the matrices are "projection matrices" owned by individual attention head , and is a final projection matrix owned by the whole multi-headed attention head.

It is theoretically possible for each attention head to have a different head dimension , but that is rarely the case in practice.

As an example, in the smallest GPT-2 model, there are only self-attention mechanisms. It has the following dimensions:Since , its output projection matrix is a square matrix.

Masked attention

It may be necessary to cut out attention links between some word-pairs. For example, the decoder, when decoding for the token position , should not have access to the token at position . This may be accomplished before the softmax stage by adding a mask matrix that is at entries where the attention link must be cut, and at other places:A non-masked attention module can be thought of as a masked attention module where the mask has all entries zero.

For example, the following matrix is commonly used in decoder self-attention modules, called "causal masking":In words, it means that each token can pay attention to itself, and every token before it, but not any after it. As an example of an uncommon use of mask matrix, the XLNet considers all masks of the form , where is a random permutation matrix. [57]

Encoder

One encoder layer. Transformer, one encoder block.png
One encoder layer.

An encoder consists of an embedding layer, followed by multiple encoder layers.

Each encoder layer consists of two major components: a self-attention mechanism and a feed-forward layer. It takes an input as a sequence of input vectors, applies the self-attention mechanism, to produce an intermediate sequence of vectors, then applies the feed-forward layer for each vector individually. Schematically, we have:

where stands for "feed-forward network". We can more succinctly write it aswith the implicit convention that the is applied to each row of the matrix individually.

The encoder layers are stacked. The first encoder layer takes the sequence of input vectors from the embedding layer, producing a sequence of vectors. This sequence of vectors is processed by the second encoder, and so on. The output from the final encoder layer is then used by the decoder.

As the encoder processes the entire input all at once, every token can attend to every other token (all-to-all attention), so there is no need for causal masking.

Decoder

One decoder layer. Transformer, one decoder block.png
One decoder layer.

A decoder consists of an embedding layer, followed by multiple decoder layers, followed by an un-embedding layer.

Each decoder consists of three major components: a causally masked self-attention mechanism, a cross-attention mechanism, and a feed-forward neural network. The decoder functions in a similar fashion to the encoder, but an additional attention mechanism is inserted which instead draws relevant information from the encodings generated by the encoders. This mechanism can also be called the encoder-decoder attention. [1] [54]

Like the first encoder, the first decoder takes positional information and embeddings of the output sequence as its input, rather than encodings. The transformer must not use the current or future output to predict an output, so the output sequence must be partially masked to prevent this reverse information flow. [1] This allows for autoregressive text generation. For decoding, all-to-all attention is inappropriate, because a token cannot attend to tokens not yet generated. Thus, the self-attention module in the decoder is causally masked.

In contrast, the cross-attention mechanism attends to the output vectors of the encoder, which is computed before the decoder starts decoding. Consequently, there is no need for masking in the cross-attention mechanism.

Schematically, we have:where is the matrix with rows being the output vectors from the encoder.

The last decoder is followed by a final un-embedding layer. to produce the output probabilities over the vocabulary. Then, one of the tokens is sampled according to the probability, and the decoder can be run again to produce the next token, etc, autoregressively generating output text.

Full transformer architecture

Sublayers

(a) One encoder layer and one decoder layer. (b) Two encoder layers and two decoder layers. The sublayers are labelled as well. Transformer, stacked multilayers.png
(a) One encoder layer and one decoder layer. (b) Two encoder layers and two decoder layers. The sublayers are labelled as well.

Each encoder layer contains 2 sublayers: the self-attention and the feedforward network. Each decoder layer contains 3 sublayers: the causally masked self-attention, the cross-attention, and the feedforward network.

Transformer encoder with norm-first and norm-last. Transformer encoder, with norm-first and norm-last.png
Transformer encoder with norm-first and norm-last.
Transformer decoder with norm-first and norm-last. Transformer decoder, with norm-first and norm-last.png
Transformer decoder with norm-first and norm-last.
Block diagram for the full Transformer architecture. Transformer, full architecture.png
Block diagram for the full Transformer architecture.
Schematic object hierarchy for the full Transformer architecture, in object-oriented programming style. Transformer, schematic object hierarchy, for implementation in object-oriented programming.png
Schematic object hierarchy for the full Transformer architecture, in object-oriented programming style.

The final points of detail are the residual connections and layer normalization (LayerNorm, or LN), which while conceptually unnecessary, are necessary for numerical stability and convergence. Similarly to how the feedforward network modules are applied individually to each vector, the LayerNorm is also applied individually to each vector.

There are two common conventions in use: the post-LN and the pre-LN convention. In the post-LN convention, the output of each sublayer is where is the function implemented by the sublayer itself.

In the pre-LN convention, the output of each sublayer isThe original 2017 Transformer used the post-LN convention. It was difficult to train and required careful hyperparameter tuning and a "warm-up" in learning rate, where it starts small and gradually increases. The pre-LN convention, proposed several times in 2018, [58] was found to be easier to train, requiring no warm-up, leading to faster convergence. [46]

Pseudocode

The following is the pseudocode for a standard pre-LN encoder-decoder Transformer, adapted from [59]

input: Encoder input t_e        Decoder input t_d output: Array of probability distributions, with shape (decoder vocabulary size x length(decoder output sequence))  /* encoder */ z_e ← encoder.tokenizer(t_e)  foreach t in 1:length(z_e) do     z_e[t] ← encoder.embedding(z_e[t]) + encoder.positional_embedding(t)  foreach l in 1:length(encoder.layers) do     layer ← encoder.layers[l]      /* first sublayer */     z_e_copy ← copy(z_e)     for each t in 1:length(z_e) do         z_e[t] ← layer.layer_norm(z_e[t])     z_e ← layer.multiheaded_attention(z_e, z_e, z_e)     for each t in 1:length(z_e) do         z_e[t] ← z_e[t] + z_e_copy[t]      /* second sublayer */     z_e_copy ← copy(z_e)     for each t in 1:length(z_e) do         z_e[t] ← layer.layer_norm(z_e[t])     z_e ← layer.feedforward(z_e)     for each t in 1:length(z_e) do         z_e[t] ← z_e[t] + z_e_copy[t]  for each t in 1:length(z_e) do     z_e[t] ← encoder.final_layer_norm(z_e[t])  /* decoder */ z_d ← decoder.tokenizer(t_d)  foreach t in 1:length(z_d) do     z_d[t] ← decoder.embedding(z_d[t]) + decoder.positional_embedding(t)  foreach l in 1:length(decoder.layers) do         layer ← decoder.layers[l]          /* first sublayer */         z_d_copy ← copy(z_d)         for each t in 1:length(z_d) do             z_d[t] ← layer.layer_norm(z_d[t])         z_d ← layer.masked_multiheaded_attention(z_d, z_d, z_d)         for each t in 1:length(z_d) do             z_d[t] ← z_d[t] + z_d_copy[t]          /* second sublayer */         z_d_copy ← copy(z_d)         for each t in 1:length(z_d) do             z_d[t] ← layer.layer_norm(z_d[t])         z_d ← layer.multiheaded_attention(z_d, z_e, z_e)          for each i in 1:length(z_d) do             z_d[t] ← z_d[t] + z_d_copy[t]          /* third sublayer */         z_d_copy ← copy(z_d)         for each t in 1:length(z_d) do             z_d[t] ← layer.layer_norm(z_d[t])         z_d ← layer.feedforward(z_d)         for each t in 1:length(z_d) do             z_d[t] ← z_d[t] + z_d_copy[t]  z_d ← decoder.final_layer_norm(z_d)  output_distributions ← [] for each t in 1:length(z_d) do     output_distributions.append(decoder.unembed(z_d[t]))  return output_distributions

Terminology

The Transformer architecture, being modular, allows variations. Several common variations are described here. [60]

An "encoder-only" Transformer applies the encoder to map an input text into a sequence of vectors that represent the input text. This is usually used for text embedding and representation learning for downstream applications. BERT is encoder-only. They are less often used currently, as they were found to be not significantly better than training an encoder-decoder Transformer, then taking just the encoder. [51]

A "decoder-only" Transformer is not literally decoder-only, since without an encoder, the cross-attention mechanism has nothing to attend to. Thus, the decoder layers in a decoder-only Transformer is composed of just two sublayers: the causally masked self-attention, and the feedforward network. This is usually used for text generation and instruction following. The models in the GPT series and Chinchilla series are decoder-only.

An "encoder-decoder" Transformer is generally the same as the original Transformer, with 2 sublayers per encoder layer and 3 sublayers per decoder layer, etc. They might have minor architectural improvements, such as alternative activation functions, changing the location of normalization, etc. This is also usually used for text generation and instruction following. The models in the T5 series are encoder-decoder. [60]

A "prefixLM" (prefix language model) is a decoder-only architecture, but with prefix masking, which is different from causal masking. Specifically, it has mask of the form [60] :Figure 3where the first columns correspond to the "prefix", and the subsequent columns correspond to the autoregressively generated text based on the prefix. They resemble encoder-decoder models, but has less "sparsity". Such models are rarely used, though they are cited as theoretical possibilities and benchmarked comparisons. [51]

There are also mixed seq2seq models. For example, in 2020, Google Translate replaced the previous RNN-encoder–RNN-decoder model by a Transformer-encoder–RNN-decoder model, on the argument that an RNN-decoder runs much faster than Transformer-decoder when run autoregressively. [61]

Subsequent work

Alternative activation functions

The original transformer uses ReLU activation function. Other activation functions were developed. The Llama series used SwiGLU; [62] both GPT-1 and BERT [35] used GELU. [63]

Alternative activation functions are often used in combination with Gated Linear Units in the feedforward module. [64]

Alternative normalizations

The normalization used in the Transformer can be different from LayerNorm. One example is RMSNorm [65] which is used in the Llama series. Other examples include CapsuleNorm [66] ScaleNorm, [67] or FixNorm. [67]

Alternative positional encodings

Transformers may use other positional encoding methods than sinusoidal. [68]

The original Transformer paper reported using a learned positional encoding, [69] but finding it not superior to the sinusoidal one. [1] Later, [70] found that causal masking itself provides enough signal to a Transformer decoder that it can learn to implicitly perform absolute positional encoding without the positional encoding module.

RoPE

RoPE (rotary positional embedding), [71] is best explained by considering a list of 2-dimensional vectors . Now pick some angle . Then RoPE encoding isEquivalently, if we write the 2-dimensional vectors as complex numbers , then RoPE encoding is just multiplication by an angle:For a list of -dimensional vectors, a RoPE encoder is defined by a sequence of angles . Then the RoPE encoding is applied to each pair of coordinates.

The benefit of RoPE is that the dot-product between two vectors depends on their relative location only: for any integer .

ALiBi

ALiBi (Attention with Linear Biases) [72] is not a replacement for the positional encoder on the original transformer. Instead, it is an additional positional encoder that is directly plugged into the attention mechanism. Specifically, the ALiBi attention mechanism isHere, is a real number ("scalar"), and is the linear bias matrix defined byin other words, . The idea being that the linear bias matrix is a softened mask. Just as represent full attention paid, and represents no attention paid, the linear bias matrix increases attention paid in one direction and decreases attention paid in the other direction.

ALiBi allows pretraining on short context windows, then finetuning on longer context windows. Since it is directly plugged into the attention mechanism, it can be combined with any positional encoder that is plugged into the "bottom" of the entire network (which is where the sinusoidal encoder on the original transformer, as well as RoPE and many others, are located).

Relative Position Encodings

Relative Position Encodings [73] is similar to ALiBi, but more generic:where is a Toeplitz matrix, that is, whenever . This is contrasted with the original sinusoidal positional encoding, which is an "absolute positional encoding". [74]

Efficient implementation

The transformer model has been implemented in standard deep learning frameworks such as TensorFlow and PyTorch. Transformers is a library produced by Hugging Face that supplies transformer-based architectures and pretrained models. [11]

FlashAttention

FlashAttention [75] is an algorithm that implements the transformer attention mechanism efficiently on a GPU. It performs matrix multiplications in blocks, such that each block fits within the cache of a GPU, and by careful management of the blocks it minimizes data copying between GPU caches (as data movement is slow).

An improved version, FlashAttention-2, [76] [77] [78] was developed to cater to the rising demand for language models capable of handling longer context lengths. It offers enhancements in work partitioning and parallelism, enabling it to achieve up to 230 TFLOPs/s on A100 GPUs (FP16/BF16), a 2x speed increase over the original FlashAttention.

Key advancements in FlashAttention-2 include the reduction of non-matmul FLOPs, improved parallelism over the sequence length dimension, better work partitioning between GPU warps, and added support for head dimensions up to 256 and multi-query attention (MQA) and grouped-query attention (GQA). [79]

Benchmarks revealed FlashAttention-2 to be up to 2x faster than FlashAttention and up to 9x faster than a standard attention implementation in PyTorch. Future developments include optimization for new hardware like H100 GPUs and new data types like FP8.

Multi-Query Attention

Multi-Query Attention changes the multiheaded attention mechanism. [80] Whereas normally,

with Multi-Query Attention, there is just one , thus:

This has a neutral effect on model quality and training speed, but increases inference speed.

More generally, grouped-query attention (GQA) partitions attention heads into groups, each of which shares the key-value pair. MQA is GQA with one group, while standard multiheaded atteniton is GQA with the maximal number of groups. [81]

Caching

When an autoregressive transformer is used for inference, such as generating text, the query vector is different at each step, but the already-computed key and value vectors are always the same. The KV caching method saves the computed key and value vectors at each attention block, so that they are not recomputed at each new token. PagedAttention applies memory paging to KV caching. [82] [83] [84]

If a transformer is used with a baked-in prompt, such as ["You are a customer support agent..."], then the key and value vectors can be computed for the prompt, and saved on disk. The saving in compute is significant when the model is used for many short interactions, such as in online chatbots.

Speculative decoding

Transformers are used in large language models for autoregressive sequence generation: generating a stream of text, one token at a time. However, in most settings, decoding from language models is memory-bound, meaning that we have spare compute power available. Speculative decoding [85] [86] uses this spare compute power by computing several tokens in parallel. Similarly to speculative execution in CPUs, future tokens are computed concurrently, by speculating on the value of previous tokens, and are later discarded if it turns out the speculation was incorrect.

Specifically, consider a transformer model like GPT-3 with a context window size of 512. To generate an entire context window autoregressively with greedy decoding, it must be run for 512 times, each time generating a token . However, if we had some educated guess for the values of these tokens, we could verify all of them in parallel, in one run of the model, by checking that each is indeed the token with the largest log-likelihood in the -th output.

In speculative decoding, a smaller model or some other simple heuristic is used to generate a few speculative tokens that are subsequently verified by the larger model. For example, suppose a small model generated four speculative tokens: . These tokens are run through the larger model, and only and are accepted. The same run of the large model already generated a new token to replace , and is completely discarded. The process then repeats (starting from the 4th token) until all tokens are generated.

For non-greedy decoding, similar ideas apply, except the speculative tokens are accepted or rejected stochastically, in a way that guarantees the final output distribution is the same as if speculative decoding was not used. [85] [87]

Sub-quadratic transformers

Training transformer-based architectures can be expensive, especially for long inputs. [88] Many methods have been developed to attempt to address the issue. Long Range Arena (2020) [89] is a standard benchmark for comparing the behavior of transformer architectures over long inputs.

Alternative attention graphs

The standard attention graph is either all-to-all or causal, both of which scales as where is the number of tokens in a sequence.

Reformer (2020) [88] [90] reduces the computational load from to by using locality-sensitive hashing and reversible layers. [91]

Sparse attention [92] uses attention graphs that grows slower than . For example, BigBird (2020) [93] uses random small-world networks which grows as .

Ordinary transformers require a memory size that is quadratic in the size of the context window. Attention-free transformers [94] reduce this to a linear dependence while still retaining the advantages of a transformer by linking the key to the value.

Random Feature Attention

Random Feature Attention (2021) [95] uses Fourier random features:where are independent samples from the normal distribution . This choice of parameters satisfy , or Consequently, the one-headed attention, with one query, can be written as where . Similarly for multiple queries, and for multiheaded attention.

This approximation can be computed in linear time, as we can compute the matrix first, then multiply it with the query. In essence, we have managed to obtain a more precise version of Performer (2022) [96] uses the same Random Feature Attention, but are first independently sampled from the normal distribution , then they are Gram-Schmidt processed.

Multimodality

Transformers can also be used/adapted for modalities (input or output) beyond just text, usually by finding a way to "tokenize" the modality.

Multimodal models can either be trained from scratch, or by finetuning. A 2022 study found that Transformers pretrained only on natural language can be finetuned on only 0.03% of parameters and become competitive with LSTMs on a variety of logical and visual tasks, demonstrating transfer learning. [97] The LLaVA was a vision-language model composed of a language model (Vicuna-13B) [98] and a vision model (ViT-L/14), connected by a linear layer. Only the linear layer is finetuned. [99]

Vision transformers [41] adapt the transformer to computer vision by breaking down input images as a series of patches, turning them into vectors, and treating them like tokens in a standard transformer.

Conformer [42] and later Whisper [100] follow the same pattern for speech recognition, first turning the speech signal into a spectrogram, which is then treated like an image, i.e. broken down into a series of patches, turned into vectors and treated like tokens in a standard transformer.

Perceivers [101] [102] are a variant of Transformers designed for multimodality.

For image generation, notable architectures are DALL-E 1 (2021), Parti (2022), [103] Phenaki (2023), [104] and Muse (2023). [105] Unlike later models, DALL-E is not a diffusion model. Instead, it uses a decoder-only Transformer that autoregressively generates a text, followed by the token representation of an image, which is then converted by a variational autoencoder to an image. [106] Parti is an encoder-decoder Transformer, where the encoder processes a text prompt, and the decoder generates a token representation of an image. [107] Muse is an encoder-only Transformer that is trained to predict masked image tokens from unmasked image tokens. During generation, all input tokens are masked, and the highest-confidence predictions are included for the next iteration, until all tokens are predicted. [105] Phenaki is a text-to-video model. It is a bidirectional masked transformer conditioned on pre-computed text tokens. The generated tokens are then decoded to a video. [104]

Applications

The transformer has had great success in natural language processing (NLP). Many large language models such as GPT-2, GPT-3, GPT-4, AlbertAGPT, Claude, BERT, XLNet, RoBERTa and ChatGPT demonstrate the ability of transformers to perform a wide variety of NLP-related subtasks and their related real-world or practical applications, including:

Beyond traditional NLP, the transformer architecture has had success in other applications, such as:

See also

Notes

  1. Gated recurrent units (2014) further reduced its complexity.
  2. Some architectures, such as RWKV or state space models, avoid the issue.

Related Research Articles

Recurrent neural networks (RNNs) are a class of artificial neural network commonly used for sequential data processing. Unlike feedforward neural networks, which process data in a single pass, RNNs process data across multiple time steps, making them well-adapted for modelling and processing text, speech, and time series.

<span class="mw-page-title-main">Autoencoder</span> Neural network that learns efficient data encoding in an unsupervised manner

An autoencoder is a type of artificial neural network used to learn efficient codings of unlabeled data. An autoencoder learns two functions: an encoding function that transforms the input data, and a decoding function that recreates the input data from the encoded representation. The autoencoder learns an efficient representation (encoding) for a set of data, typically for dimensionality reduction, to generate lower-dimensional embeddings for subsequent use by other machine learning algorithms.

Multimodal learning is a type of deep learning that integrates and processes multiple types of data, referred to as modalities, such as text, audio, images, or video. This integration allows for a more holistic understanding of complex data, improving model performance in tasks like visual question answering, cross-modal retrieval, text-to-image generation, aesthetic ranking, and image captioning.

Neural machine translation (NMT) is an approach to machine translation that uses an artificial neural network to predict the likelihood of a sequence of words, typically modeling entire sentences in a single integrated model.

Mixture of experts (MoE) is a machine learning technique where multiple expert networks (learners) are used to divide a problem space into homogeneous regions. MoE represents a form of ensemble learning.

Paraphrase or paraphrasing in computational linguistics is the natural language processing task of detecting and generating paraphrases. Applications of paraphrasing are varied including information retrieval, question answering, text summarization, and plagiarism detection. Paraphrasing is also useful in the evaluation of machine translation, as well as semantic parsing and generation of new samples to expand existing corpora.

Bidirectional encoder representations from transformers (BERT) is a language model introduced in October 2018 by researchers at Google. It learns to represent text as a sequence of vectors using self-supervised learning. It uses the encoder-only transformer architecture. It is notable for its dramatic improvement over previous state-of-the-art models, and as an early example of a large language model. As of 2020, BERT is a ubiquitous baseline in natural language processing (NLP) experiments.

<span class="mw-page-title-main">Variational autoencoder</span> Deep learning generative model to encode data representation

In machine learning, a variational autoencoder (VAE) is an artificial neural network architecture introduced by Diederik P. Kingma and Max Welling. It is part of the families of probabilistic graphical models and variational Bayesian methods.

A Neural Network Gaussian Process (NNGP) is a Gaussian process (GP) obtained as the limit of a certain type of sequence of neural networks. Specifically, a wide variety of network architectures converges to a GP in the infinitely wide limit, in the sense of distribution. The concept constitutes an intensional definition, i.e., a NNGP is just a GP, but distinguished by how it is obtained.

<span class="mw-page-title-main">Attention (machine learning)</span> Machine learning technique

Attention is a machine learning method that determines the relative importance of each component in a sequence relative to the other components in that sequence. In natural language processing, importance is represented by "soft" weights assigned to each word in a sentence. More generally, attention encodes vectors called token embeddings across a fixed-width sequence that can range from tens to millions of tokens in size.

<span class="mw-page-title-main">Contrastive Language-Image Pre-training</span> Technique in neural networks for learning joint representations of text and images

Contrastive Language-Image Pre-training (CLIP) is a technique for training a pair of neural network models, one for image understanding and one for text understanding, using a contrastive objective. This method has enabled broad applications across multiple domains, including cross-modal retrieval, text-to-image generation, aesthetic ranking, and image captioning.

A graph neural network (GNN) belongs to a class of artificial neural networks for processing data that can be represented as graphs.

<span class="mw-page-title-main">Vision transformer</span> Machine learning model for vision processing

A vision transformer (ViT) is a transformer designed for computer vision. A ViT decomposes an input image into a series of patches, serializes each patch into a vector, and maps it to a smaller dimension with a single matrix multiplication. These vector embeddings are then processed by a transformer encoder as if they were token embeddings.

Prompt engineering is the process of structuring an instruction that can be interpreted and understood by a generative artificial intelligence (AI) model. A prompt is natural language text describing the task that an AI should perform. A prompt for a text-to-text language model can be a query such as "what is Fermat's little theorem?", a command such as "write a poem in the style of Edgar Allan Poe about leaves falling", or a longer statement including context, instructions, and conversation history.

In machine learning, diffusion models, also known as diffusion probabilistic models or score-based generative models, are a class of latent variable generative models. A diffusion model consists of three major components: the forward process, the reverse process, and the sampling procedure. The goal of diffusion models is to learn a diffusion process for a given dataset, such that the process can generate new elements that are distributed similarly as the original dataset. A diffusion model models data as generated by a diffusion process, whereby a new datum performs a random walk with drift through the space of all possible data. A trained diffusion model can be sampled in many ways, with different efficiency and quality.

<span class="mw-page-title-main">Attention Is All You Need</span> 2017 research paper by Google

"Attention Is All You Need" is a 2017 landmark research paper in machine learning authored by eight scientists working at Google. The paper introduced a new deep learning architecture known as the transformer, based on the attention mechanism proposed in 2014 by Bahdanau et al. It is considered a foundational paper in modern artificial intelligence, as the transformer approach has become the main architecture of large language models like those based on GPT. At the time, the focus of the research was on improving Seq2seq techniques for machine translation, but the authors go further in the paper, foreseeing the technique's potential for other tasks like question answering and what is now known as multimodal Generative AI.

T5 is a series of large language models developed by Google AI introduced in 2019. Like the original Transformer model, T5 models are encoder-decoder Transformers, where the encoder processes the input text, and the decoder generates the output text.

In machine learning, normalization is a statistical technique with various applications. There are two main forms of normalization, namely data normalization and activation normalization. Data normalization includes methods that rescale input data so that the features have the same range, mean, variance, or other statistical properties. For instance, a popular choice of feature scaling method is min-max normalization, where each feature is transformed to have the same range. This solves the problem of different features having vastly different scales, for example if one feature is measured in kilometers and another in nanometers.

The Latent Diffusion Model (LDM) is a diffusion model architecture developed by the CompVis group at LMU Munich.

In neural networks, a pooling layer is a kind of network layer that downsamples and aggregates information that is dispersed among many vectors into fewer vectors. It has several uses. It removes redundant information, reducing the amount of computation and memory required, makes the model more robust to small variations in the input, and increases the receptive field of neurons in later layers in the network.

References

  1. 1 2 3 4 5 6 7 8 9 10 Vaswani, Ashish; Shazeer, Noam; Parmar, Niki; Uszkoreit, Jakob; Jones, Llion; Gomez, Aidan N; Kaiser, Łukasz; Polosukhin, Illia (2017). "Attention is All you Need" (PDF). Advances in Neural Information Processing Systems. 30. Curran Associates, Inc.
  2. Hochreiter, Sepp; Schmidhuber, Jürgen (1 November 1997). "Long Short-Term Memory". Neural Computation. 9 (8): 1735–1780. doi:10.1162/neco.1997.9.8.1735. ISSN   0899-7667. PMID   9377276. S2CID   1915014.
  3. 1 2 "Better Language Models and Their Implications". OpenAI. 2019-02-14. Archived from the original on 2020-12-19. Retrieved 2019-08-25.
  4. 1 2 Bahdanau; Cho, Kyunghyun; Bengio, Yoshua (September 1, 2014). "Neural Machine Translation by Jointly Learning to Align and Translate". arXiv: 1409.0473 [cs.CL].
  5. Luong, Minh-Thang; Pham, Hieu; Manning, Christopher D. (August 17, 2015). "Effective Approaches to Attention-based Neural Machine Translation". arXiv: 1508.04025 [cs.CL].
  6. 1 2 Chen, Lili; Lu, Kevin; Rajeswaran, Aravind; Lee, Kimin; Grover, Aditya; Laskin, Michael; Abbeel, Pieter; Srinivas, Aravind; Mordatch, Igor (2021-06-24), Decision Transformer: Reinforcement Learning via Sequence Modeling, arXiv: 2106.01345
  7. Parisotto, Emilio; Song, Francis; Rae, Jack; Pascanu, Razvan; Gulcehre, Caglar; Jayakumar, Siddhant; Jaderberg, Max; Kaufman, Raphaël Lopez; Clark, Aidan; Noury, Seb; Botvinick, Matthew; Heess, Nicolas; Hadsell, Raia (2020-11-21). "Stabilizing Transformers for Reinforcement Learning". Proceedings of the 37th International Conference on Machine Learning. PMLR: 7487–7498.
  8. Radford, Alec; Jong Wook Kim; Xu, Tao; Brockman, Greg; McLeavey, Christine; Sutskever, Ilya (2022). "Robust Speech Recognition via Large-Scale Weak Supervision". arXiv: 2212.04356 [eess.AS].
  9. Monastirsky, Maxim; Azulay, Osher; Sintov, Avishai (February 2023). "Learning to Throw With a Handful of Samples Using Decision Transformers". IEEE Robotics and Automation Letters. 8 (2): 576–583. doi:10.1109/LRA.2022.3229266. ISSN   2377-3766.
  10. 1 2 Ruoss, Anian; Delétang, Grégoire; Medapati, Sourabh; Grau-Moya, Jordi; Wenliang, Li; Catt, Elliot; Reid, John; Genewein, Tim (2024-02-07). "Grandmaster-Level Chess Without Search". arXiv: 2402.04494v1 [cs.LG].
  11. 1 2 Wolf, Thomas; Debut, Lysandre; Sanh, Victor; Chaumond, Julien; Delangue, Clement; Moi, Anthony; Cistac, Pierric; Rault, Tim; Louf, Remi; Funtowicz, Morgan; Davison, Joe; Shleifer, Sam; von Platen, Patrick; Ma, Clara; Jernite, Yacine; Plu, Julien; Xu, Canwen; Le Scao, Teven; Gugger, Sylvain; Drame, Mariama; Lhoest, Quentin; Rush, Alexander (2020). "Transformers: State-of-the-Art Natural Language Processing". Proceedings of the 2020 Conference on Empirical Methods in Natural Language Processing: System Demonstrations. pp. 38–45. doi:10.18653/v1/2020.emnlp-demos.6. S2CID   208117506.
  12. 1 2 3 "Open Sourcing BERT: State-of-the-Art Pre-training for Natural Language Processing". Google AI Blog. 2 November 2018. Archived from the original on 2021-01-13. Retrieved 2019-08-25.
  13. Feldman, J. A.; Ballard, D. H. (1982-07-01). "Connectionist models and their properties". Cognitive Science. 6 (3): 205–254. doi:10.1016/S0364-0213(82)80001-3. ISSN   0364-0213.
  14. Rumelhart, David E.; McClelland, James L.; Hinton, Geoffrey E. (1987-07-29). Parallel Distributed Processing, Volume 1: Explorations in the Microstructure of Cognition: Foundations, Chapter 2 (PDF). Cambridge, Mass: Bradford Books. ISBN   978-0-262-68053-0.
  15. Giles, C. Lee; Maxwell, Tom (1987-12-01). "Learning, invariance, and generalization in high-order neural networks". Applied Optics. 26 (23): 4972–4978. doi:10.1364/AO.26.004972. ISSN   0003-6935. PMID   20523475.
  16. 1 2 Schmidhuber, Jürgen (1992). "Learning to control fast-weight memories: an alternative to recurrent nets" (PDF). Neural Computation. 4 (1): 131–139. doi:10.1162/neco.1992.4.1.131. S2CID   16683347.
  17. Christoph von der Malsburg: The correlation theory of brain function. Internal Report 81-2, MPI Biophysical Chemistry, 1981. http://cogprints.org/1380/1/vdM_correlation.pdf See Reprint in Models of Neural Networks II, chapter 2, pages 95-119. Springer, Berlin, 1994.
  18. Jerome A. Feldman, "Dynamic connections in neural networks," Biological Cybernetics, vol. 46, no. 1, pp. 27-39, Dec. 1982.
  19. Hinton, Geoffrey E.; Plaut, David C. (1987). "Using Fast Weights to Deblur Old Memories". Proceedings of the Annual Meeting of the Cognitive Science Society. 9.
  20. Katharopoulos, Angelos; Vyas, Apoorv; Pappas, Nikolaos; Fleuret, François (2020). "Transformers are RNNs: Fast autoregressive Transformers with linear attention". ICML 2020. PMLR. pp. 5156–5165.
  21. Schlag, Imanol; Irie, Kazuki; Schmidhuber, Jürgen (2021). "Linear Transformers Are Secretly Fast Weight Programmers". ICML 2021. Springer. pp. 9355–9366.
  22. 1 2 3 Cho, Kyunghyun; van Merriënboer, Bart; Gulcehre, Caglar; Bahdanau, Dzmitry; Bougares, Fethi; Schwenk, Holger; Bengio, Yoshua (October 2014). "Learning Phrase Representations using RNN Encoder–Decoder for Statistical Machine Translation". In Moschitti, Alessandro; Pang, Bo; Daelemans, Walter (eds.). Proceedings of the 2014 Conference on Empirical Methods in Natural Language Processing (EMNLP). Doha, Qatar: Association for Computational Linguistics. pp. 1724–1734. arXiv: 1406.1078 . doi:10.3115/v1/D14-1179.
  23. 1 2 3 Sutskever, Ilya; Vinyals, Oriol; Le, Quoc Viet (14 Dec 2014). "Sequence to sequence learning with neural networks". arXiv: 1409.3215 [cs.CL]. [first version posted to arXiv on 10 Sep 2014]
  24. Chung, Junyoung; Gulcehre, Caglar; Cho, KyungHyun; Bengio, Yoshua (2014). "Empirical Evaluation of Gated Recurrent Neural Networks on Sequence Modeling". arXiv: 1412.3555 [cs.NE].
  25. Gruber, N.; Jockisch, A. (2020), "Are GRU cells more specific and LSTM cells more sensitive in motive classification of text?", Frontiers in Artificial Intelligence, 3: 40, doi: 10.3389/frai.2020.00040 , PMC   7861254 , PMID   33733157, S2CID   220252321
  26. Sutskever, Ilya; Vinyals, Oriol; Le, Quoc V (2014). "Sequence to Sequence Learning with Neural Networks". Advances in Neural Information Processing Systems. 27. Curran Associates, Inc. arXiv: 1409.3215 .
  27. Luong, Minh-Thang; Pham, Hieu; Manning, Christopher D. (2015). "Effective Approaches to Attention-based Neural Machine Translation". arXiv: 1508.04025 [cs.CL].
  28. Wu, Yonghui; et al. (2016-09-01). "Google's Neural Machine Translation System: Bridging the Gap between Human and Machine Translation". arXiv: 1609.08144 [cs.CL].
  29. Lewis-Kraus, Gideon (2016-12-14). "The Great A.I. Awakening". The New York Times. ISSN   0362-4331. Archived from the original on 24 May 2023. Retrieved 2023-06-22.
  30. Parikh, Ankur P.; Täckström, Oscar; Das, Dipanjan; Uszkoreit, Jakob (2016-09-25). "A Decomposable Attention Model for Natural Language Inference". arXiv: 1606.01933 [cs.CL].
  31. 1 2 Levy, Steven. "8 Google Employees Invented Modern AI. Here's the Inside Story". Wired. ISSN   1059-1028. Archived from the original on 20 Mar 2024. Retrieved 2024-08-06.
  32. Cheng, Jianpeng; Dong, Li; Lapata, Mirella (November 2016). "Long Short-Term Memory-Networks for Machine Reading". In Su, Jian; Duh, Kevin; Carreras, Xavier (eds.). Proceedings of the 2016 Conference on Empirical Methods in Natural Language Processing. Austin, Texas: Association for Computational Linguistics. pp. 551–561. doi:10.18653/v1/D16-1053.
  33. Peng, Bo; Alcaide, Eric; Anthony, Quentin; Albalak, Alon; Arcadinho, Samuel; Biderman, Stella; Cao, Huanqi; Cheng, Xin; Chung, Michael (2023-12-10), RWKV: Reinventing RNNs for the Transformer Era, arXiv: 2305.13048
  34. Marche, Stephen (2024-08-23). "Was Linguistic A.I. Created by Accident?". The New Yorker. ISSN   0028-792X . Retrieved 2024-08-27.
  35. 1 2 3 4 5 Devlin, Jacob; Chang, Ming-Wei; Lee, Kenton; Toutanova, Kristina (11 October 2018). "BERT: Pre-training of Deep Bidirectional Transformers for Language Understanding". arXiv: 1810.04805v2 [cs.CL].
  36. "Google: BERT now used on almost every English query". Search Engine Land. 2020-10-15. Retrieved 2020-11-24.
  37. "Recent Advances in Google Translate". research.google. Retrieved 2024-05-08.
  38. "The inside story of how ChatGPT was built from the people who made it". MIT Technology Review. Retrieved 2024-08-06.
  39. "Improving language understanding with unsupervised learning". openai.com. June 11, 2018. Archived from the original on 2023-03-18. Retrieved 2023-03-18.
  40. finetune-transformer-lm, OpenAI, June 11, 2018, retrieved 2023-05-01
  41. 1 2 Dosovitskiy, Alexey; Beyer, Lucas; Kolesnikov, Alexander; Weissenborn, Dirk; Zhai, Xiaohua; Unterthiner, Thomas; Dehghani, Mostafa; Minderer, Matthias; Heigold, Georg; Gelly, Sylvain; Uszkoreit, Jakob (2021-06-03). "An Image is Worth 16x16 Words: Transformers for Image Recognition at Scale". arXiv: 2010.11929 [cs.CV].
  42. 1 2 Gulati, Anmol; Qin, James; Chiu, Chung-Cheng; Parmar, Niki; Zhang, Yu; Yu, Jiahui; Han, Wei; Wang, Shibo; Zhang, Zhengdong; Wu, Yonghui; Pang, Ruoming (2020). "Conformer: Convolution-augmented Transformer for Speech Recognition". arXiv: 2005.08100 [eess.AS].
  43. Choromanski, Krzysztof; Likhosherstov, Valerii; Dohan, David; Song, Xingyou; Gane, Andreea; Sarlos, Tamas; Hawkins, Peter; Davis, Jared; Mohiuddin, Afroz (2022-11-19), Rethinking Attention with Performers, arXiv: 2009.14794
  44. Liu, Zhuang; Mao, Hanzi; Wu, Chao-Yuan; Feichtenhofer, Christoph; Darrell, Trevor; Xie, Saining (2022). A ConvNet for the 2020s. Conference on Computer Vision and Pattern Recognition. pp. 11976–11986.
  45. Esser, Patrick; Kulal, Sumith; Blattmann, Andreas; Entezari, Rahim; Müller, Jonas; Saini, Harry; Levi, Yam; Lorenz, Dominik; Sauer, Axel (2024-03-05), Scaling Rectified Flow Transformers for High-Resolution Image Synthesis, arXiv: 2403.03206
  46. 1 2 Xiong, Ruibin; Yang, Yunchang; He, Di; Zheng, Kai; Zheng, Shuxin; Xing, Chen; Zhang, Huishuai; Lan, Yanyan; Wang, Liwei; Liu, Tie-Yan (2020-06-29). "On Layer Normalization in the Transformer Architecture". arXiv: 2002.04745 [cs.LG].
  47. Raffel, Colin; Shazeer, Noam; Roberts, Adam; Lee, Katherine; Narang, Sharan; Matena, Michael; Zhou, Yanqi; Li, Wei; Liu, Peter J. (2020-01-01). "Exploring the limits of transfer learning with a unified text-to-text transformer". The Journal of Machine Learning Research. 21 (1): 140:5485–140:5551. arXiv: 1910.10683 . ISSN   1532-4435.
  48. Raffel, Colin; Shazeer, Noam; Roberts, Adam; Lee, Katherine; Narang, Sharan; Matena, Michael; Zhou, Yanqi; Li, Wei; Liu, Peter J. (2019). "Exploring the Limits of Transfer Learning with a Unified Text-to-Text Transformer". arXiv: 1910.10683 [cs.LG].
  49. 1 2 "Masked language modeling". huggingface.co. Retrieved 2023-10-05.
  50. 1 2 "Causal language modeling". huggingface.co. Retrieved 2023-10-05.
  51. 1 2 3 4 Tay, Yi; Dehghani, Mostafa; Tran, Vinh Q.; Garcia, Xavier; Wei, Jason; Wang, Xuezhi; Chung, Hyung Won; Shakeri, Siamak; Bahri, Dara (2023-02-28), UL2: Unifying Language Learning Paradigms, arXiv: 2205.05131
  52. Press, Ofir; Wolf, Lior (2017-02-21), Using the Output Embedding to Improve Language Models, arXiv: 1608.05859 , retrieved 2024-10-21
  53. "Sequence Modeling with Neural Networks (Part 2): Attention Models". Indico. 2016-04-18. Archived from the original on 2020-10-21. Retrieved 2019-10-15.
  54. 1 2 3 Alammar, Jay. "The Illustrated Transformer". jalammar.github.io. Archived from the original on 2020-10-18. Retrieved 2019-10-15.
  55. Team, Keras. "Keras documentation: GPT2Backbone model". keras.io. Retrieved 2024-08-08.
  56. Clark, Kevin; Khandelwal, Urvashi; Levy, Omer; Manning, Christopher D. (August 2019). "What Does BERT Look at? An Analysis of BERT's Attention". Proceedings of the 2019 ACL Workshop BlackboxNLP: Analyzing and Interpreting Neural Networks for NLP. Florence, Italy: Association for Computational Linguistics: 276–286. arXiv: 1906.04341 . doi: 10.18653/v1/W19-4828 . Archived from the original on 2020-10-21. Retrieved 2020-05-20.
  57. Yang, Zhilin; Dai, Zihang; Yang, Yiming; Carbonell, Jaime; Salakhutdinov, Russ R; Le, Quoc V (2019). "XLNet: Generalized Autoregressive Pretraining for Language Understanding". Advances in Neural Information Processing Systems. 32. Curran Associates, Inc. arXiv: 1906.08237 .
  58. Wang, Qiang; Li, Bei; Xiao, Tong; Zhu, Jingbo; Li, Changliang; Wong, Derek F.; Chao, Lidia S. (2019-06-04), Learning Deep Transformer Models for Machine Translation, arXiv: 1906.01787
  59. Phuong, Mary; Hutter, Marcus (2022-07-19), Formal Algorithms for Transformers, arXiv: 2207.09238
  60. 1 2 3 Raffel, Colin; Shazeer, Noam; Roberts, Adam; Lee, Katherine; Narang, Sharan; Matena, Michael; Zhou, Yanqi; Li, Wei; Liu, Peter J. (2020). "Exploring the Limits of Transfer Learning with a Unified Text-to-Text Transformer". Journal of Machine Learning Research. 21 (140): 1–67. arXiv: 1910.10683 . ISSN   1533-7928.
  61. "Recent Advances in Google Translate". Google Research. June 8, 2020. Archived from the original on 4 Jul 2024. Retrieved 2024-08-07.
  62. Shazeer, Noam (2020-02-01). "GLU Variants Improve Transformer". arXiv: 2002.05202 [cs.LG].
  63. Hendrycks, Dan; Gimpel, Kevin (2016-06-27). "Gaussian Error Linear Units (GELUs)". arXiv: 1606.08415v5 [cs.LG].
  64. Shazeer, Noam (February 14, 2020). "GLU Variants Improve Transformer". arXiv: 2002.05202 [cs.LG].
  65. Zhang, Biao; Sennrich, Rico (2019). "Root Mean Square Layer Normalization". Advances in Neural Information Processing Systems. 32. Curran Associates, Inc. arXiv: 1910.07467 .
  66. Tembine, Hamidou, Manzoor Ahmed Khan, and Issa Bamia. 2024. "Mean-Field-Type Transformers" Mathematics 12, no. 22: 3506. https://doi.org/10.3390/math12223506
  67. 1 2 Nguyen, Toan Q.; Salazar, Julian (2019-11-02). Niehues, Jan; Cattoni, Rolando; Stüker, Sebastian; Negri, Matteo; Turchi, Marco; Ha, Thanh-Le; Salesky, Elizabeth; Sanabria, Ramon; Barrault, Loic (eds.). "Transformers without Tears: Improving the Normalization of Self-Attention". Proceedings of the 16th International Conference on Spoken Language Translation. Hong Kong: Association for Computational Linguistics. arXiv: 1910.05895 . doi:10.5281/zenodo.3525484.
  68. Dufter, Philipp; Schmitt, Martin; Schütze, Hinrich (2022-06-06). "Position Information in Transformers: An Overview". Computational Linguistics. 48 (3): 733–763. arXiv: 2102.11090 . doi: 10.1162/coli_a_00445 . ISSN   0891-2017. S2CID   231986066.
  69. Gehring, Jonas; Auli, Michael; Grangier, David; Yarats, Denis; Dauphin, Yann N. (2017-07-17). "Convolutional Sequence to Sequence Learning". Proceedings of the 34th International Conference on Machine Learning. PMLR: 1243–1252.
  70. Haviv, Adi; Ram, Ori; Press, Ofir; Izsak, Peter; Levy, Omer (2022-12-05), Transformer Language Models without Positional Encodings Still Learn Positional Information, arXiv: 2203.16634
  71. Su, Jianlin; Lu, Yu; Pan, Shengfeng; Murtadha, Ahmed; Wen, Bo; Liu, Yunfeng (2021-04-01). "RoFormer: Enhanced Transformer with Rotary Position Embedding". arXiv: 2104.09864 [cs.CL].
  72. Press, Ofir; Smith, Noah A.; Lewis, Mike (2021-08-01). "Train Short, Test Long: Attention with Linear Biases Enables Input Length Extrapolation". arXiv: 2108.12409 [cs.CL].
  73. Shaw, Peter; Uszkoreit, Jakob; Vaswani, Ashish (2018). "Self-Attention with Relative Position Representations". arXiv: 1803.02155 [cs.CL].
  74. Ke, Guolin; He, Di; Liu, Tie-Yan (2021-03-15), Rethinking Positional Encoding in Language Pre-training, arXiv: 2006.15595
  75. Dao, Tri; Fu, Dan; Ermon, Stefano; Rudra, Atri; Ré, Christopher (2022-12-06). "FlashAttention: Fast and Memory-Efficient Exact Attention with IO-Awareness". Advances in Neural Information Processing Systems. 35: 16344–16359. arXiv: 2205.14135 .
  76. "Stanford CRFM". crfm.stanford.edu. Retrieved 2023-07-18.
  77. "FlashAttention-2: Faster Attention with Better Parallelism and Work Partitioning". Princeton NLP. 2023-06-17. Retrieved 2023-07-18.
  78. "Introducing Together AI Chief Scientist Tri Dao, as he releases FlashAttention-2 to speed up model training and inference". TOGETHER. Retrieved 2023-07-18.
  79. Ainslie, Joshua; Lee-Thorp, James; de Jong, Michiel; Zemlyanskiy, Yury; Lebrón, Federico; Sanghai, Sumit (2023-12-23). "GQA: Training Generalized Multi-Query Transformer Models from Multi-Head Checkpoints". arXiv: 2305.13245 [cs.CL].
  80. Chowdhery, Aakanksha; Narang, Sharan; Devlin, Jacob; Bosma, Maarten; Mishra, Gaurav; Roberts, Adam; Barham, Paul; Chung, Hyung Won; Sutton, Charles; Gehrmann, Sebastian; Schuh, Parker; Shi, Kensen; Tsvyashchenko, Sasha; Maynez, Joshua; Rao, Abhishek (2022-04-01). "PaLM: Scaling Language Modeling with Pathways". arXiv: 2204.02311 [cs.CL].
  81. Ainslie, Joshua; Lee-Thorp, James; de Jong, Michiel; Zemlyanskiy, Yury; Lebrón, Federico; Sanghai, Sumit (2023-12-23), GQA: Training Generalized Multi-Query Transformer Models from Multi-Head Checkpoints, arXiv: 2305.13245
  82. Kwon, Woosuk; Li, Zhuohan; Zhuang, Siyuan; Sheng, Ying; Zheng, Lianmin; Yu, Cody Hao; Gonzalez, Joseph; Zhang, Hao; Stoica, Ion (2023-10-23). "Efficient Memory Management for Large Language Model Serving with PagedAttention". Proceedings of the 29th Symposium on Operating Systems Principles. SOSP '23. New York, NY, USA: Association for Computing Machinery. pp. 611–626. arXiv: 2309.06180 . doi:10.1145/3600006.3613165. ISBN   979-8-4007-0229-7.
  83. vllm-project/vllm, vLLM, 2024-06-20, retrieved 2024-06-20
  84. Contribution), Woosuk Kwon*, Zhuohan Li*, Siyuan Zhuang, Ying Sheng, Lianmin Zheng, Cody Yu, Joey Gonzalez, Hao Zhang, and Ion Stoica (* Equal (2023-06-20). "vLLM: Easy, Fast, and Cheap LLM Serving with PagedAttention". vLLM Blog. Retrieved 2024-06-20.{{cite web}}: CS1 maint: multiple names: authors list (link)
  85. 1 2 Leviathan, Yaniv; Kalman, Matan; Matias, Yossi (2023-05-18), Fast Inference from Transformers via Speculative Decoding, arXiv: 2211.17192
  86. Fu, Yao (2023-12-13). "Towards 100x Speedup: Full Stack Transformer Inference Optimization".
  87. Chen, Charlie; Borgeaud, Sebastian; Irving, Geoffrey; Lespiau, Jean-Baptiste; Sifre, Laurent; Jumper, John (2023-02-02), Accelerating Large Language Model Decoding with Speculative Sampling, arXiv: 2302.01318
  88. 1 2 Kitaev, Nikita; Kaiser, Łukasz; Levskaya, Anselm (2020). "Reformer: The Efficient Transformer". arXiv: 2001.04451 [cs.LG].
  89. Tay, Yi; Dehghani, Mostafa; Abnar, Samira; Shen, Yikang; Bahri, Dara; Pham, Philip; Rao, Jinfeng; Yang, Liu; Ruder, Sebastian; Metzler, Donald (2020-11-08). "Long Range Arena: A Benchmark for Efficient Transformers". arXiv: 2011.04006 [cs.LG].
  90. "Reformer: The Efficient Transformer". Google AI Blog. 16 January 2020. Archived from the original on 2020-10-22. Retrieved 2020-10-22.
  91. Gomez, Aidan N; Ren, Mengye; Urtasun, Raquel; Grosse, Roger B (2017). "The Reversible Residual Network: Backpropagation Without Storing Activations". Advances in Neural Information Processing Systems. 30. Curran Associates, Inc. arXiv: 1707.04585 .
  92. Child, Rewon; Gray, Scott; Radford, Alec; Sutskever, Ilya (2019-04-23), Generating Long Sequences with Sparse Transformers, arXiv: 1904.10509
  93. "Constructing Transformers For Longer Sequences with Sparse Attention Methods". Google AI Blog. 25 March 2021. Archived from the original on 2021-09-18. Retrieved 2021-05-28.
  94. Zhai, Shuangfei; Talbott, Walter; Srivastava, Nitish; Huang, Chen; Goh, Hanlin; Zhang, Ruixiang; Susskind, Josh (2021-09-21). "An Attention Free Transformer". arXiv: 2105.14103 [cs.LG].
  95. Peng, Hao; Pappas, Nikolaos; Yogatama, Dani; Schwartz, Roy; Smith, Noah A.; Kong, Lingpeng (2021-03-19). "Random Feature Attention". arXiv: 2103.02143 [cs.CL].
  96. Choromanski, Krzysztof; Likhosherstov, Valerii; Dohan, David; Song, Xingyou; Gane, Andreea; Sarlos, Tamas; Hawkins, Peter; Davis, Jared; Belanger, David; Colwell, Lucy; Weller, Adrian (2020-09-30). "Masked Language Modeling for Proteins via Linearly Scalable Long-Context Transformers". arXiv: 2006.03555 [cs.LG].
  97. Lu, Kevin; Grover, Aditya; Abbeel, Pieter; Mordatch, Igor (2022-06-28). "Frozen Pretrained Transformers as Universal Computation Engines". Proceedings of the AAAI Conference on Artificial Intelligence. 36 (7): 7628–7636. doi: 10.1609/aaai.v36i7.20729 . ISSN   2374-3468.
  98. "Vicuna: An Open-Source Chatbot Impressing GPT-4 with 90%* ChatGPT Quality | LMSYS Org". lmsys.org. Retrieved 2024-08-11.
  99. Liu, Haotian; Li, Chunyuan; Wu, Qingyang; Lee, Yong Jae (2023-12-15). "Visual Instruction Tuning". Advances in Neural Information Processing Systems. 36: 34892–34916.
  100. Radford, Alec; Kim, Jong Wook; Xu, Tao; Brockman, Greg; McLeavey, Christine; Sutskever, Ilya (2022). "Robust Speech Recognition via Large-Scale Weak Supervision". arXiv: 2212.04356 [eess.AS].
  101. Jaegle, Andrew; Gimeno, Felix; Brock, Andrew; Zisserman, Andrew; Vinyals, Oriol; Carreira, Joao (2021-06-22). "Perceiver: General Perception with Iterative Attention". arXiv: 2103.03206 [cs.CV].
  102. Jaegle, Andrew; Borgeaud, Sebastian; Alayrac, Jean-Baptiste; Doersch, Carl; Ionescu, Catalin; Ding, David; Koppula, Skanda; Zoran, Daniel; Brock, Andrew; Shelhamer, Evan; Hénaff, Olivier (2021-08-02). "Perceiver IO: A General Architecture for Structured Inputs & Outputs". arXiv: 2107.14795 [cs.LG].
  103. "Parti: Pathways Autoregressive Text-to-Image Model". sites.research.google. Retrieved 2024-08-09.
  104. 1 2 Villegas, Ruben; Babaeizadeh, Mohammad; Kindermans, Pieter-Jan; Moraldo, Hernan; Zhang, Han; Saffar, Mohammad Taghi; Castro, Santiago; Kunze, Julius; Erhan, Dumitru (2022-09-29). "Phenaki: Variable Length Video Generation from Open Domain Textual Descriptions".{{cite journal}}: Cite journal requires |journal= (help)
  105. 1 2 Chang, Huiwen; Zhang, Han; Barber, Jarred; Maschinot, A. J.; Lezama, Jose; Jiang, Lu; Yang, Ming-Hsuan; Murphy, Kevin; Freeman, William T. (2023-01-02). "Muse: Text-To-Image Generation via Masked Generative Transformers". arXiv: 2301.00704 [cs.CV].
  106. Ramesh, Aditya; Pavlov, Mikhail; Goh, Gabriel; Gray, Scott; Voss, Chelsea; Radford, Alec; Chen, Mark; Sutskever, Ilya (2021-02-26), Zero-Shot Text-to-Image Generation, arXiv: 2102.12092
  107. Yu, Jiahui; Xu, Yuanzhong; Koh, Jing Yu; Luong, Thang; Baid, Gunjan; Wang, Zirui; Vasudevan, Vijay; Ku, Alexander; Yang, Yinfei (2022-06-21), Scaling Autoregressive Models for Content-Rich Text-to-Image Generation, arXiv: 2206.10789
  108. Kariampuzha, William; Alyea, Gioconda; Qu, Sue; Sanjak, Jaleal; Mathé, Ewy; Sid, Eric; Chatelaine, Haley; Yadaw, Arjun; Xu, Yanji; Zhu, Qian (2023). "Precision information extraction for rare disease epidemiology at scale". Journal of Translational Medicine. 21 (1): 157. doi: 10.1186/s12967-023-04011-y . PMC   9972634 . PMID   36855134.

Further reading