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content/robotics/SLAM by Durrant 2006 Part 1.md

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+[[Durrant-Whyte_Bailey_SLAM-tutorial-I.pdf|text]]
+# SLAM by Durrant 2006 Part 1
+## Notes on the Abstract
+There appear to be several reasons why this paper is an especial industry favorite as it clearly opens with the following hooks:
+- targets small, mobile, embedded and low power systems of the time
+- and discusses *implementation* in a ==tutorial== format
+
+## Discourse
+### Introduction
+Starting with a definition, the Simultaneous Localisation and Mapping (SLAM) problem/problem scenario (more on this later) requires and the checks the possibility of a *"mobile robot"* incrementally building a map of its vicinity while also determining its location in the course, when placed into an unknown and un-cached environment. It is of an intrinsic essence of said problem to have very influential solution in the field of robotics, should they be found. Needless to say, this is a fundamental problem of robotic motion.
+
+### The Problem
+![[Pasted image 20231120122338.png]]
+#### Defining variables
+In the image above, the color filled icons represent what the robot perceives using its sensors or LiDAR instruments, while the icons without a fill represent true vectors and landmarks. Directed triangles represent the path the robot is taking, while all forms of lines represent motion vectors fitting a curve. The indicated variable $k$ represent the time instance at which the labeled vector is being considered. The unexplained variable $i$ is an iterator of the the closest landmark given a $k^{th}$ vector.
+
+- $\vec{x_k}$ is the state vector of the robot at time $k$
+- $\vec{u_k}$ is the change vector applied at $k-1$ to change $\vec{x_{k-1}}$ to $\vec{x_k}$
+- $\vec{m_i}$ is a offset/erorr vector from the estimated to true location of a landmark given landmark of identity $i$, assuming the true location is *time invariant*
+- $z_{i,k}$ is an observation pertaining to the ==location== **of** the $i^{th}$ landmark at time $k$. When referring to a set or history of such measurements, it is conventional short hand to denote them as $z_k$
+##### Set definitions
+- $X_{0:k} = {\lbrace x_0,x_1,...,x_k \rbrace}= {\lbrace X_{1:k-1},x_k \rbrace} \rightarrow$ The history of robot locations
+- $U_{1:k} = {\lbrace u_1,u_2,...,u_k \rbrace}= {\lbrace U_{1:k-1},u_k \rbrace} \rightarrow$ The history of control vectors
+- $m$ is the set of all landmarks
+- $Z_{1:k} = {\lbrace z_1,z_2,...,z_k \rbrace}= {\lbrace Z_{1:k-1},z_k \rbrace} \rightarrow$ The historical set of all landmark observations
+
+### Probabilistic SLAM
+The probability distribution given time $k$:
+$$
+P(x_{k},m \vert Z_{1:k},U_{1:k},x_0)
+$$
+This distribution describes the *joint* end density of the coplanar measurements of landmark location and vehicle state (losing a dimension or two of vehicle state vector.) Since a vehicle control vector is improbable to be perfectly implemented in a real-world situation, and the change in measurements, temporally recursive computations are desirable. 
+It is important to understand that this distribution is possible when *given* the set $U_{0:k}$, the control vectors *including* $u_{k}$. This can be read as the probability of a random $\vec{p_k}$ taking on the desired value of $\vec{x_k}$ in *conjunction* with $i_n$ number of random vectors taking on the values in set $m$ given observations and adjustment control vectors and a initial positional state vector $x_0$. Importantly, this is a computation of the probability of *both* observing the correct landmarks *in* the map, *and* possessing the desired state $x_k$.
+In direct corollary, there exist four vital probabilistic models:
+
+Model | Distribution 
+-- | -- 
+Observation | $P(z_{k}\vert x_k,m)$
+Motion | $P(x_{k}\vert x_{k-1},u_k)$
+Time-update | $P(x_k,m\vert Z_{1:k-1},U_{1:k},x_{0)}=\int{P(x_k\vert x_{k-1},u_k)}*{P(x_{k-1},m\vert Z_{1:k-1},U_{1:k-1},x_0)}*dx_{k-1}$
+And finally Measurement Update:
+$$
+P(x_k,m\vert Z_{1:k},U_{1:k},x_0)
+=\frac{P(z_k\vert x_k,m)*P(x_k,m\vert Z_{1:k-1},U_{1:k},x_0)}{P(z_k\vert Z_{1:k-1},U_{1:k})}
+$$
+As seen the last two are both recursive over a new piece of information each. Leaving the math here, the author will refrain it for the rest of this paper, as the rest of the matter depends highly on model variant and implementation. 
+#### Core Concepts
+Sparing you the the drivel:
+- A large portion of error across multiple landmark observations $z_k$ is *common* to all landmarks when compared to $m$
+- This is a high *monotonous* correlation in landmark location estimates constructed using $Z$
+- Therefore, relative location is easier to discern than absolute location for all entities
+- $m_i-m_j$ may be known with high accuracy even with a uncertain $m_i$ ($i$ and $j$ not relating with previous definitions)
+- In probabilistic terms, $P(m_i,m_j)$ has a higher density than $P(m_i)$
+- Correlations between landmark estimates increase *monotonically*
+- $P(m)$ progressively becomes more peaked
+- Even if a landmark $m_i$ is not observed in the current frame of sense, relative changes in position in perspective of $x_k$ propagate back to landmark $m_i$
+- A robot usually has a circular field of vision, like our car in F1Tenth
+
+
+### Solutions
+Solutions to the probabilistic SLAM problem necessitate a hunt for an appropriate algorithmic and thorough mathematical model to facilitate the computation of the Motion, Observation, and Time-Update posterior probability density models.
+The first solution discussed in this paper is ***EKF-SLAM***, which will not be discussed here, in favor of a deeper dive in another note:
+![[EKF-SLAM#Introduction]]
+
+## Citation
+H. Durrant-Whyte and T. Bailey, "Simultaneous localization and mapping: part I," in IEEE Robotics & Automation Magazine, vol. 13, no. 2, pp. 99-110, June 2006, doi: 10.1109/MRA.2006.1638022.
+
+# Foundational Wikis
+[Baye's Factor](https://en.wikipedia.org/wiki/Bayes_factor)
+[Posterior probability](https://en.wikipedia.org/wiki/Posterior_probability)
+# Credits
+Author of this note: Krishna Ayyalasomayajula
+
+#paper-review #SLAM #krishna #literature-review