Visual tracking for the recovery of multiple interacting plant root systems from X-ray \(\upmu \)CT images

We adopt the level set framework [32] to search for the boundaries of root cross-sections. We aim at finding the interfaceof a time-dependent function \(\varPhi _{x,y,t}\) that separates an object consisting of comparable intensity values from its heterogeneous background. The interface of \(\varPhi _{x,y,t}\) can be implicitly propagated by solving a partial differential equationwhich can be approximated and rewritten using a finite forward difference scheme in timegiving a general formulation of the time-discretised level set method, with F being a speed function that defines the motion of the front over time t. One possible way to find the boundary of an arbitrary object is to define a speed function that stops at high image gradients. A solution based on the formulation presented in [33] was tested, but failed to correctly identify root objects: blurred and low contrast boundaries are common in CT data. A solution is therefore proposed that evolves a level set function guided by a greyscale intensity distribution model [11]. Assuming we have the greyscale intensity values of a known root object, we use a kernel density estimator to build a statistical probability density function, which we will refer to as our root appearance model \(p_{m}\) where n is the number of data points, x(i) the samples of the greyscale distribution, h the bandwidth and K a Gaussian smoothing kernel \(K(x) = \frac{1}{\sqrt{2\pi }} \mathrm{e}^{-\frac{1}{2} x^{2}}\). Using the Jensen–Shannon (JS) divergence [34] as given in Eq. 5, we compute the distance between a probability density function \(p_{f}\) estimated around the interface of the level set function and our known root model \(p_{m}\) where H is the Shannon entropy function calculated as in Eq. 6 over the range of the probability density function of possible greyscale values n. \(w_{1}\) and \(w_{2}\) are two weighting parameters \(w_{1},w_{2} \ge 0, w_{1}+w_{2}=1\) used to balance the contribution of the two statistical probability density functions and useful for conditional probability studies where the weighting parameters represent prior probabilities. In our case, however, we set \(w_{1}=w_{2}=0.5\).The JS divergence is a non-negative and symmetric dissimilarity measure, bounded by \([0, \log _{b} 2]\). Using a logarithm of base 2 results in a distance that is measured within [0, 1], where 0 is considered a complete match between two probability density functions. The higher the value of the JS divergence, the lower is the probability that the data come from the same distribution. These properties, and the fact that the dissimilarity measure is not constrained by the number of samples and their shape of the distribution, make the JS divergence a good choice for our application. Given the above definitions, we can now build them into a level set frameworkwhere \(\hbox {JS}_{\beta \vee } = \max (\lceil \beta -\hbox {JS}\rceil ,0)\) and \(\hbox {JS}_{\beta \wedge } = \min (\lfloor \beta -\hbox {JS}\rfloor ,0)\) are the propagation forces, with \(\beta \in [0,1]\) defining the acceptance distance of the JS divergence between model and data distribution. \(\alpha \in [0,1]\) is a weighting parameter between the propagation force and the curvature dependency \( \kappa = \nabla \cdot \frac{\nabla \varPhi ^{t}_{x,y}}{|\nabla \varPhi ^{t}_{x,y}| }\) of the front. The numerical solution requires a difference scheme to be chosen that propagates information in the direction upwind to the moving interface. This is achieved through \(\nabla ^{+}= [\max (D^{-x},0)^{2}+\min (D^{+x},0)^{2}+\max (D^{-y},0)^{2}+\min (D^{+y},0)^{2}]^{1/2}\) in case of an expanding force and similarly through \(\nabla ^{-}= [\max (D^{+x},0)^{2}+\min (D^{-x},0)^{2}+\max (D^{+y},0)^{2}+\min (D^{-y},0)^{2}]^{1/2}\) for a contracting force, where \(D^{+x} = \frac{\varPhi _{x+\varDelta x, y, t}-\varPhi _{x,y,t}}{\varDelta x}\) is the forward difference operator and \(D^{-x} = \frac{\varPhi _{x, y, t}-\varPhi _{x-\varDelta x,y,t}}{\varDelta x}\) the backward difference operator in x, and respectively, \(D^{+y}\) and \(D^{-y}\) in y. The interface evolves until the front converges to a stationary solution, which is checked by counting the number of sign changes of the level set function. This has further the advantage that the evolution process can be terminated even if the front oscillates [32]. The level set framework is implemented using the narrow band strategy [35] for increased efficiency and the fast sweeping method [36] for re-initialisation. Figure 1 shows a cross-sectional image in which root objects are identified and separated from their complex and heterogeneous soil environment using the method described above.

Target objects are selected for tracking by the user manually setting seed points in the first (top) image in the stack. An initial root appearance model is built for each target from the greyscale intensity values within a 5 pixel radius. To provide a good initial root model, seed points should be placed to capture as many valid pixels as possible. Seed points can be placed anywhere within large root cross-sections. The seed points also mark the initial interface of the propagating level set function, which is evolved until the root object boundaries are identified. Since a level set function can implicitly represent multiple interfaces, a classical two-pass connected component algorithm [37] is used to assign a label to each root cross-section. Labels are propagated when constructing the narrow band around an interface and it is therefore possible to evolve the level set function using different appearance models for each root object. This means that we do not have a single model that represents all the root objects in a plant at the same time, but several models that are generated, each representing a single target (root segment).

Once the boundaries of root objects are identified, the aim is to track these target objects through a sequence of horizontal slices, or images, building up a three-dimensional segmentation of the root system. Due to the high resolution of X-ray \(\upmu \)CT data, we assume that corresponding root locations in consecutive images partially overlap, and that their greyscale intensity distributions vary smoothly. Some variation is to be expected due to the heterogeneous environment of varying density materials and the unevenly distributed water content in both the soil and the root system, which can affect the estimated X-ray attenuation values making up the voxel data. Therefore, as root objects are tracked through the image sequence, their assigned root model distribution must be updated to adapt to their changing appearance. This is done by re-computing the root appearance model from the greyscale intensity values enclosed by each of the converged interfaces of the level set function.

Updating the root model is an inevitable step, yet it conceals potential problems. Noise or small areas of background might be included within the interface and so contribute to its probability density function. These errors can accumulate and result in a model that is no longer an appropriate representation of a tracked root object. To reduce the potential of model drift, we use a complex Fourier shape descriptor [38] to compare the shape of a root object in pairs of consecutive images and only update the root appearance model when the sum of squared differences of their filtered and normalised power spectra is below an empirically determined threshold.

A root system is composed of several branching roots. Splitting of a root boundary as it branches throughout the image stack is implicitly dealt with by the level set’s ability to adapt to changing topologies: as the level set interface evolves from one state to another, it can split into multiple disjoint interfaces. When a target object separates, the level set evolves based on the same root model, but will become two distinct objects with their own, independently updating root appearance model after proceeding to the next image slice. Figure 2 shows a sequence of cross-sectional images in which root objects are tracked from manual initialisation on the (single) root stem.

The tracker described so far, as it follows a root object through the image stack, will only capture roots that branch and grow downward, along the search direction. Any upward oriented roots will be missed, since they appear in the image stack before they connect to an identified target object. To address this, an additional step is introduced, allowing the tracker to ‘look back’ at the previously analysed image, using any of the currently identified targets to search for new root objects that have not been detected before. If such objects are found, they are temporarily labelled as potential upward growing roots, while the extraction process is continued downwards until the end of the image stack is reached. If, at the end, one or more objects have been labelled as upward oriented roots, then the image stack is reversed and each of the labels picked up by the tracker and followed as if they were downward oriented. Jumping to assigned labels avoids re-examination of the entire stack and further tracking of previously identified roots. This process of alternating direction is repeated until all targets have been examined and no new labels remain [12].

To extract multiple root systems, a level set tracker is initialised to each plant and their level set functions evolved simultaneously. In this work we adopt the concept of multiple level set functions as presented in [39]. Let \(\varPhi ^{t}_{A}\) and \(\varPhi ^{t}_{B}\) be two level set functions and their interfaces occupy two different regions at time t. The level set functions evolve separately, based on their individual root appearance models, resulting in a temporary state of \(\varPhi ^{*}_{A}\) and \(\varPhi ^{*}_{B}\). \(\varPhi ^{*}_{A}\) and \(\varPhi ^{*}_{B}\) are then combined to obtain the level set functions \(\varPhi ^{t+1}_{A}\) and \(\varPhi ^{t+1}_{B}\) at time \(t+1\). The combination of the temporary level set functions depends on whether or not the interface of A can penetrate the interface of B, or vice versa, and as such pushes back the adjacent interface. Assuming that A can penetrate B, but B cannot penetrate A, then the new level set function at time step \(t+1\) will be updated according toThe following examples show how the rule in Eq. 8 solves the interaction between the level set functions \(\varPhi _{A}^{*}\) and \(\varPhi _{B}^{*}\). To recall, a level set function has negative values inside and positive values outside of its interface. There are different possible situations when updating \(\varPhi _{B}^{t+1}\), taking \(\varPhi _{B}^{*}\) and \(\varPhi _{A}^{*}\) into account. First, a point may appear inside both \(\varPhi _{A}^{*}\) and \(\varPhi _{B}^{*}\), so both level set functions have negative values. As \(\varPhi _{B}^{t+1}\) is obtained by taking the maximum of \(\varPhi _{B}^{*}\) and \(- \varPhi _{A}^{*}\), and the negative value of \(\varPhi _{A}^{*}\) is turned into a positive value, the point is assigned to the outside of the interface \(\varPhi _{B}^{t+1}\), while \(\varPhi _{A}^{t+1}\) remains negative. The effect is that A pushes away the interface of B. Now let us assume a point that is neither part of the interface of A nor B. This means that both values are positive. By placing the minus sign in front of \(-\varPhi _{A}^{*}\), the positive value becomes negative, but because of the maximum operator, the updated value for \(\varPhi _{B}^{t+1}\) remains positive, and therefore is not affected by the level set function \(\varPhi _{A}^{*}\). Finally, let us assume that a point is inside the interface of B but outside of A. Because the value of a level set function represents the distance to its interface, the negative value of \(- \varPhi _{A}^{*}\) will be less or equal the negative value of \(\varPhi _{B}^{*}\), and again, the result for \(\varPhi _{B}^{t+1}\) at that point remains unaffected by the level set function \(\varPhi _{A}^{*}\).

These examples show how interacting level set fronts can be controlled: this rule can be modified to define similar rules such that during an encounter of two level set fronts, neither is allowed to penetrate the other. This will stop them from advancing further and give an exact partition of the two regions at the front of collision. The mechanism of multiple fronts can easily be extended to any number of level set functions using the same principles of combination. Each evolving front in the set must be compared to all other level set functions in the same set. This allows easy identification of any collisions between interfaces and determination of which of the level set functions interact. Figure 3 shows three different scenarios in which two level set functions (front A (red) and front B (blue)) are evolved until their fronts interact with each other, at which point different combination rules are applied. This is a key element in the extraction of multiple interacting root systems, but not sufficient to allow separation of those root systems. While the combination rules allow individual trackers to be separated, the true boundary between touching root cross-sections remains unknown. Although level set functions can penetrate each other’s interface, there is no definition given yet of when these rules are to be applied. For this, shape information is used to estimate the boundary of root objects and so to find the intersecting front between them.

While tracking target objects through the image stack, their shape is noted and used to control appearance model updates. We can, therefore, easily recall an object’s outline and store the most recent shape information seen before the interaction with other objects began. This information is kept until the interaction ceases. Let \(U = \lbrace {\mathbf {u}}_{i} | i=1\ldots N_{u}\rbrace \) be a set of data points along the outline of a stored shape and \(V = \lbrace {\mathbf {v}}_{i} | i=1\ldots N_{v}\rbrace \) be a set of data points along a level set’s interface. The rotation matrix \(\mathbf{R }\) and the translation matrix \(\mathbf{T }\) are sought which minimise the root mean squared distance between U and V and therefore find the best alignment of the two point sets. This can be achieved using the iterative closest point (ICP) algorithm [40]. By calculating the centre of mass \({\varvec{\mu }}_{\mathbf{u}}\) and \({\varvec{\mu }}_{\mathbf{v}}\) of the two point clouds, it is possible to determine the cross-covariance matrix \(\hbox {cov}_{uv}=\dfrac{1}{N_{u}}\sum _{i=1}^{N_{u}} [({\mathbf {u}}_{i}-{\varvec{\mu }}_{\mathbf{u}})({\mathbf {v}}_{i}-{\varvec{\mu }}_{\mathbf{v}})^\intercal ]\) for U and V. Using the cyclic components \({\mathbf {a}}=(A_{23},A_{31},A_{12})\) of a matrix \(\mathbf{A }= \hbox {cov}_{uv}- \hbox {cov}_{uv}^\intercal \) allows the definition of a \(4\times 4\) matrix \(\mathbf{Q }\) The eigenvector \({\mathbf {r}}=(q_{1} \quad q_{2} \quad q_{3} \quad q_{4})\) of the matrix \(\mathbf{Q }\) with the maximum eigenvalue is used to define the rotation matrix \(\mathbf{R }\) The vector \({\mathbf {t}}=({\varvec{\mu }}_{\mathbf{v}}-\mathbf{R }{\varvec{\mu }}_{\mathbf{u}})\) is used to define the translation matrix \(\mathbf{T }\) The ICP algorithm is initialised by setting the rotation and translation matrices equal to the identity matrix \(\mathbf{R }=\mathbf{T }=\mathbf{I }\) and begins by identifying for each point \({\mathbf {u}} \in U\) the best match with the shortest distance \(d({\mathbf {u}},V)=\min _{{\mathbf {v}} \in V}||{\mathbf {v}}-{\mathbf {u}}||\). This step can be efficiently performed using a k–d tree [41]. With the set of matching pairs as input, the best registration is calculated using the quaternion-based least square method, determining \(\mathbf{R }\) and \(\mathbf{T }\) which are then applied to U. The whole process is repeated iteratively, finding new matching points and their transformation, until the change in mean squared error falls below a given threshold.

When the interfaces of two level set functions collide, and each is made impenetrable, race conditions are generated, as illustrated in Fig. 4. This, however, can be solved using shape constraints. The ICP algorithm, as described above, is used to find the best alignment of the stored shape to the evolving interface. This leaves each point within the interface in one of two possible states: it is either outside or inside of its aligned region. Let \(S=\{S_{1}\ldots S_{n}\}\) be the enclosed areas of each aligned shape to its corresponding level set function, \(L=\{\varPhi _{1} \ldots \varPhi _{n}\}\) be the set of level set functions at time t and \(L^{*}=\{\varPhi _{1}^{*}\ldots \varPhi _{n}^{*}\}\) the set of their temporary states, then the final value of the level set function \(\varPhi ^{t+1}_{i}\) at time step \(t+1\) and position p is updated accordinglyA particular benefit of this solution is that, while it constrains the movement of the front, the selected root object is not required to maintain the registered shape. This allows the detection of lateral roots, since a level set function can still evolve beyond the aligned region. At the same time it prevents the path of a level set function being blocked by faster evolving level sets and allows their interface to be penetrated so that control over its target is maintained. The effect of adding shape constraints to the level set functions is illustrated in Fig. 4. Figure 5 shows a sequence of images in which tracked root cross-sections interact with each other.

Motivation for the recovery of plant root systems from X-ray \(\upmu \)CT data comes from a pressing need to analyse the spatial characteristics of root systems, particularly in relation to their neighbouring plant(s). Root growth is driven by apical meristems, which are groups of cells found close to root tips, formed either during the embryonic development of primary roots or in the primordium of lateral roots [44]. The root system’s further exploration of the soil environment therefore derives from existing root tips, which confines our attention.

To support the recovery of quantitative data on root system traits and interactions, each root system’s skeleton is extracted from the volumetric segmentation data produced by the methods presented above. An inverted 3D Manhattan distance map, beginning from the root walls and extending over the root cross-sections, is computed for each root system. The local minima of each root cross-section are then determined and used to identify a set of control points which are input to a non-parametric regression model using a linear piecewise curve-fitting function. Optimal smoothing parameters are found through cross-validation, finding a smooth and continuous representation of the root skeleton. Root tips are found at the ends of the skeleton, where root cross-sections are entirely enclosed by root walls (i.e. where all distances of a root cross-section are equal to zero). This ensures that root tips are labelled at the outer layer of the roots and not within the roots, away from their surface boundary. The result is a nested tree structure expressed in Root System Markup Language (RSML) format [45].

A vantage point (VP) tree [46] is generated for each of the skeletonised root systems and used in conjunction with the detected root tips to find the minimum distance from each of the tips to their neighbouring root system(s). Plant root systems that compete for localised accumulated resources are expected to show an increased number of close distances as the majority of roots are likely to grow towards the same location. The opposite is expected for root systems that avoid each other’s presence and would mostly grow towards unoccupied areas in the soil. A more substantive conclusion on plant root competition for resources could be derived from temporally acquired data, as it supports analysis of when and how distances change over time. Analysis of time series data and biologically focused studies of multiple root systems and their characteristic traits will be the subject of future work; for the present we demonstrate only the ability of our methods to provide information on root interactions. To this end, Fig. 9 visualises the computed minimum distances between root systems, represented as translucent spheres centred at root tips.