diff --git a/docs/make.jl b/docs/make.jl
index 699924cda..fa109ea37 100644
--- a/docs/make.jl
+++ b/docs/make.jl
@@ -41,6 +41,9 @@ pages = [
"Circuit Operations" => "noisycircuits_ops.md",
"API" => "noisycircuits_API.md"
],
+"Generalized Stabilizer" => [
+ "Overview" => "genstab.md",
+ ],
"ECC compendium" => [
"Evaluating codes and decoders" => "ECC_evaluating.md"
"API" => "ECC_API.md"
diff --git a/docs/src/genstab.md b/docs/src/genstab.md
new file mode 100644
index 000000000..8a81412dc
--- /dev/null
+++ b/docs/src/genstab.md
@@ -0,0 +1,74 @@
+# [Generalized Stabilizer Representation](@id Generalized-Stabilizer-Overview)
+
+Gottesman's introduction of stabilizer formalism in 1997 greatly impacted quantum complexity and coding
+theory. The key insight of the Gottesman-Knill theorem lies in utilizing a Heisenberg representation[^1] for
+quantum states, allowing classical simulations to work with only `n` Pauli operators, rather than processing
+an exponentially large complex vector with approximately `2ⁿ` entries for an `n`-qubit state. However, this
+approach is limited to stabilizer circuits with Clifford gates and measurements. While effective, the theorem
+has a narrow scope, making it essential to generalize it for broader quantum circuit simulations. Theodore
+Yoder[^2] introduced the generalized stabilizer representation to address this challenge.
+
+# Advances in Stabilizer Formalism
+
+Since its inception, the stabilizer formalism has undergone several improvements. Notable enhancements include:
+
+```@raw html
+
+timeline
+ title Related Work in Generalization of the Gottesman-Knill Theorem
+ 1997 : Gottesman introduces stabilizer formalism and the Gottesman-Knill theorem.
+ 2002 : Bartlett et al. expand to continuous variable quantum computation.
+ 2004 : Aaronson and Gottesman improve measurement time complexity to 𝒪(n²).
+ 2006 : Anders and Briegel achieve 𝒪(n log n) speedup in time complexity with graph states.
+ 2012 : Bermejo-Vega and Van den Nest generalize to any finite Abelian group from n-qubits ℤ₂ⁿ.
+ 2012 : Yoder develops the Generalized Stabilizer with a novel state representation.
+
+```
+
+# Generalized Stabilizer Representation
+
+The generalized stabilizer representation provides a flexible framework for simulating quantum circuits by:
+
+- Enabling the representation of any quantum state, pure or mixed.
+- Allowing simulations of arbitrary quantum circuits, including unitary operations, measurements, and
+quantum channels.
+
+This representation expands on the stabilizer formalism by incorporating non-stabilizer states and circuits,
+enabling the simulation of non-Clifford gates and broader quantum channels for diverse quantum computations.
+
+Unlike previous methods that may use a superposition of stabilizer states to represent arbitrary states,
+this approach employs the tableau construction developed by Aaronson and Gottesman[^3]. This method implicitly
+represents a set of orthogonal stabilizer states, forming a stabilizer basis capable of representing arbitrary
+quantum states. Updating the tableau takes only twice as long as updating a single stabilizer, enabling efficient
+updates of the entire stabilizer basis with minimal computational overhead.
+
+# Simulation of Quantum Channels
+
+The generalized stabilizer representation enables the simulation of arbitrary quantum channels, beyond just
+unitary gates and measurements. It does this by decomposing the Kraus operators of a channel into Pauli operators
+from the state’s tableau, allowing for a broader range of quantum operations.
+
+# Advantages of the Generalized Stabilizer
+
+The proposed representation combines the rapid update capabilities of stabilizer states with the generality of
+density matrices. Key features include:
+
+- High update efficiency for unitary gates, measurements, and quantum channels, influenced by the sparsity of
+the density matrix, `Λ(χ)`, which indicates the count of non-zero elements in `χ`.
+
+- Simulations maintain linear complexity with respect to the number of measurements, and the representation
+remains straightforward, reflecting the principle that measurements simplify quantum states through collapse.
+
+# Implications for Classical and Quantum Computation
+
+Investigating stabilizer circuits enhances our understanding of classical and quantum computation. Simulating these
+circuits is a complete problem in the classical complexity class `⊕L`, a subset of `P`, indicating that stabilizer
+circuits may not be universal in classical computation contexts. Surprisingly, adding just one non-Clifford gate to
+circuits with Clifford gates and measurements generally enables universal quantum computation—a contrast that highlights
+intriguing questions about the computational boundaries between classical and quantum systems.
+
+[^1]: [gottesman1998heisenberg](@cite)
+
+[^2]: [yoder2012generalization](@cite)
+
+[^3]: [gottesman1997stabilizer](@cite)
diff --git a/docs/src/references.bib b/docs/src/references.bib
index 09820c204..78fcc7945 100644
--- a/docs/src/references.bib
+++ b/docs/src/references.bib
@@ -191,6 +191,45 @@ @article{nahum2017quantum
year = {2017}
}
+% Generalized Stabilizer
+
+@article{yoder2012generalization,
+ title={A generalization of the stabilizer formalism for simulating arbitrary quantum circuits},
+ author={Yoder, Theodore J},
+ journal={See http://www. scottaaronson. com/showcase2/report/ted-yoder. pdf},
+ year={2012},
+ publisher={Citeseer}
+}
+
+@article{bartlett2002efficient,
+ title={Efficient classical simulation of continuous variable quantum information processes},
+ author={Bartlett, Stephen D and Sanders, Barry C and Braunstein, Samuel L and Nemoto, Kae},
+ journal={Physical Review Letters},
+ volume={88},
+ number={9},
+ pages={097904},
+ year={2002},
+ publisher={APS}
+}
+
+@article{anders2006fast,
+ title={Fast simulation of stabilizer circuits using a graph-state representation},
+ author={Anders, Simon and Briegel, Hans J},
+ journal={Physical Review A?Atomic, Molecular, and Optical Physics},
+ volume={73},
+ number={2},
+ pages={022334},
+ year={2006},
+ publisher={APS}
+}
+
+@article{bermejo2012classical,
+ title={Classical simulations of Abelian-group normalizer circuits with intermediate measurements},
+ author={Bermejo-Vega, Juan and Nest, Maarten Van den},
+ journal={arXiv preprint arXiv:1210.3637},
+ year={2012}
+}
+
% codes
@article{mackay2004sparse,