Attachment was first identified in children and measured through an experimental paradigm known as the Strange Situation Procedure (SSP) (Ainsworth et al., 1978; Main and Solomon, 1990). The SSP is realized in a room where the child is the protagonist of eight three-minute episodes in which they are either alone or can interact with a caregiver or a stranger, allowing for the child’s attachment to be elicited. Through this procedure, four categories of attachment – security, avoidance, ambivalence, and disorganization – have been identified as corresponding to precise behavioral and emotional patterns expressed by the child during the eight episodes (Hesse, 2008). In this scheme, security simply means the absence of both avoidance and ambivalence, while disorganization is seen as a particular condition. Importantly, this conceptualization identifies a “security-insecurity dimension” and a corresponding caregiving feature – often called “sensitive responsiveness” – as underlying both avoidance and ambivalence (Ainsworth et al., 1978, p. 152). In other words, avoidance and ambivalence are seen as two opposite manifestations of the same dimension. The success of the SSP has been consolidated by the Adult Attachment Interview (AAI) (George et al., 1985; Main and Hesse, 1990; Hesse, 2016), through which the state of mind with respect to attachment can be measured in adults. The AAI identifies four attachment styles that correspond to the patterns identified by the SSP, thereby supporting the persistence of attachment phenomena throughout life. These kinds of measures consider attachment as characterized by mutually exclusive categories.

Although the categorical view of attachment is still in use, further research has shown that attachment can be better characterized as a multidimensional phenomenon. In particular, the four identified categories can be described by three (relatively) independent dimensions that correspond to representations acquired on specific aspects of the relationship (Fraley and Spieker, 2003; Liotti, 2011; Fraley et al., 2015; Paetzold et al., 2015; Mikulincer and Shaver, 2016; Gagliardi, 2021). Following the SSP, we refer to these dimensions as avoidance, ambivalence,¹ and disorganization. They can fully express the range of behaviors and internal states detectable through the SSP at around 1 year of age. Attachment disorganization has been connected to the experience of a frightening caregiver (Main and Solomon, 1990; Lyons-Ruth and Jacobvitz, 2016). In the SSP, disorganized children typically express incoherent/contradictory behaviors that arise from the contrasting motivations of seeking care and, simultaneously, shelter from a threatening caregiver. Therefore, this dimension represents a particular and delicate case. On the other hand, avoidance and ambivalence have been connected to the adequacy of the care received (Ainsworth et al., 1978; De Wolff and van Ijzendoorn, 1997). When such care is inadequate, attachment is deactivated, in the avoidant case, or hyperactivated, in the ambivalent case, which is reflected in corresponding behaviors and internal states as explained next (Ainsworth et al., 1978; Parkes et al., 1993; Mikulincer et al., 2003; Mikulincer and Shaver, 2016):

For each dimension, the acquired representations are primarily implicit (non-verbal) and deducible from the manifested patterns. In this case, the above descriptions – which are supported by expert ratings of a very large SSP sample (Fraley and Spieker, 2003) and by objective measurements on video and audio recordings (Chow et al., 2018; Prince et al., 2021) – suggest that: (1) Avoidant representations concern the caregiver’s emotional connection; and (2) Ambivalent representations concern the caregiver’s physical attendance.

The overall system (Figure 3) can conveniently be thought of as consisting of a core (blocks 1–4) and an interface (blocks 0 and 5–6), through which it interacts with the environment. Below, we describe these parts in turn. As done above, we primarily refer to the attachment system, which is the focus of this work (similar considerations hold for the caregiving system).

A drive is defined as what generates a need (i.e., the system’s activation) by combining the multiple factors involved. Between them, the time passed without providing care and what child and caregiver signal to each other have been documented as essential elements of the attachment relationship (Bowlby, 1973; Ainsworth et al., 1978). Following the DP-informed theory discussed above, for the formulation of the drives (Equations 1–4), we consider that, other things being equal:

Consistently, two pairs of coupled equations are proposed for the activation of attacher avoidance, drive a_av, and caregiver insensitivity, drive c_av (block 3):

And two pairs of coupled equations are proposed for the activation of attacher ambivalence, drive a_am, and caregiver unresponsiveness, drive c_am (block 4):

In these equations: (1) K is a measure of the elapsed psychological time since the child last received care; (2) N is the need signalled by the other agent that they require care (N_R), or wish to express caregiving (N_G); (3) S_E is a measure of the “emotional separation” experienced by both agents; (4) D_P is the “perceived distance” between the agents. Each of these elements are explained in more detail in the following subsections. (5) A_v is the level of the attacher’s avoidance, and I_n is the level of the caregiver’s insensitivity, while (6) A_m is the level of the attacher’s ambivalence, and U_n is the level of the caregiver’s unresponsiveness. These last four are control parameters set at the start and maintained fixed throughout the simulation run. A_v and A_m represent the dimensional levels stored in the attacher’s brain. (7) C_f,av and C_f,am are coupling factors, which determine the weight of each agent’s need on the other. (8) c_0a,av, c_0c,av, c_0a,am, and c_0c,am are constants used for the initial setting of the system.

The drives generate a need according to the function:

where the variable x is the relevant drive (a or c) and the parameter h accounts for the dimension level (A_v or A_m), which equals the corresponding feature level (I_n or U_n; Figure 4). This need function expresses the child’s need to receive care (N_R, activation level of their attachment system) and the mother’s need to give care (N_G, activation level of her caregiving system). It is assumed that each agent can perceive the other’s need level, and two pairs of Equations 1–2 and 3–4, are copuled in this way. N(x,h) has the form of a Hill function (Somvanshi and Venkatesh, 2013), commonly used to model saturation in biological systems, and is parameterized by h such that the steepness of the curve reduces with increasing h (Figure 4A). This reflects, for example, the fact that the more a child is avoidant (larger h), the less they feel a change in the need to be taken care of (for a given change of the situation). A phenomenon that is well represented by the avoidant child reaction to a separation in the SSP.

K is the time passed with no provision of care, which relates to emotional care in the case of avoidance (K_av) and to physical care in the case of ambivalence (K_am). At each interaction n, this is equal to the number of iterations since care was last provided, considering care as provided when N_G exceeds its threshold. When K becomes zero, the need function N drops.³ The coefficient 1/2 of K was set empirically and could be changed to account for environmental variations.

The modeled interaction between child and caregiver corresponds to the oscillation of the drives, a and c, and the needs, N_R and N_G, around a baseline as illustrated in Figure 5 for an example simulation run. The need oscillations will generate a behavioral dynamics of alternating approach and exploration, with rates that depend on the level of avoidance or ambivalence (cf. Simulations section).

At each iteration, the agents experience an “emotional separation,” S_E, and “perceived distance,” D_P, connected to contextual cues. More specifically: (1) In the avoidant case, the attacher experiences S_Ea and the caregiver S_Ec; (2) In the ambivalent case, the attacher experiences D_Pa and the caregiver D_Pc. The use of different variables is due to the different nature of the two dimensions and their link to different contextual cues, as discussed next.

Following the DP, the terms “emotional separation” and “perceived distance” reflect the assumption that avoidance is an emotional dimension and ambivalence is a physical dimension. S_E refers to the emotional connection and D_P to the physical availability perceived by the child in the relationship. These “psychological variables” are connected to “behavioral variables” measurable in the lab. In particular, for each dimension, a variable related to the caregiver’s behavior provides a cue to the child to derive a dimensional level corresponding to the current situation. The child will compare this level with the target one stored in their mind to drive their action. In this perspective, attachment works as a multidimensional control system.

To derive S_E and D_P, we used the following behavioral variables:

(6)i[ n ]=100 Nex[ n ]n⁴

From them, each agent obtains S_E and D_P through an update rule of the form:

with a noisy step size representing the natural uncertainty of the agent’s perception. The particular expressions used are:

which update the previous values (first term) depending on the current indifference or distancing (second term), thereby going from observable variables (i, d) to mental ones (S_E, D_P) – as suggested by the DP. In these equations, r ∈ [0,1] is a uniformly distributed random number, T_E, T_i, T_P, and T_d are the target values of S_E, i, D_P and d, respectively (as discussed below). The effectiveness of this formula can be clarified considering the following. The update needs to depend on the targets: for a new dimensional level to be adequate, it has to be consistent with the corresponding target. By referring the current behavioral gap from target (i[n]−T_i or d[n]−T_d) to the previous psychological gap from target (S_E[n−1]−T_E or D_P[n−1]−T_P), this expression ensures an adequate update. For example, considering the distance (Equation 9), if the new d is further from its target than the old D_P from its, then it makes sense that the new D_P increases. If d is closer, it makes sense that D_P decreases. The behavioral variable provides a consistent update of the psychological one.

For each agent, the system compares the current dimensional level to the target (stored) one and takes an action that tends to decrease the difference between the two. A decision is made according to the threshold that characterizes the agent’s need N. Specifically, when N_R exceeds its threshold (T_R), the attacher needs care, and when N_G exceeds its threshold (T_G), the caregiver needs to provide care (Figure 4B). The thresholds are given by the following expression:

where, T_bl is a baseline value, τ is a constant, and r ∈ [0,1] is a uniformly distributed random number (to account for possible fluctuations, given that T is a subjective/psychological variable). T is reduced (minus sign in the formula) when N decreases. This is intended to model the prudential tendency to readily reactivate attachment or caregiving when they are deactivated, as expected given their role for contingent survival. The constants were set empirically (cf. Simulations section). As discussed above, according to the DP, the avoidant and ambivalent dyads differ for the goals they set for themselves. Therefore, the following is considered:

The target emotional separation (T_E) and perceived distance (T_P), respectively, represent the psychological values of emotional separation (S_E) and perceived distance (D_P) that maximize the subject’s comfort. For the child and the caregiver, such targets vary according to the level of avoidance or ambivalence.

In general, the targets in the mind of the agents (T_E, T_P) will correspond to targets observable in the context of interaction (T_i, T_d). In the case of our elementary squared environment, we used the simple linear relationships T_i = 1.1T_E (for the avoidant attacher and insensitive caregiver) and T_d = 0.24T_P (for the ambivalent and unresponsive caregiver).⁵

The action selection mechanism is implemented for the movement in the lab based on the agents’ needs and targets. The child will decide whether to approach – a manifestation of the need to receive care, i.e., attachment – or explore. The caregiver will decide whether to approach – a manifestation of the need to provide care to the child, i.e., caregiving – or explore. For each agent, approaching is a movement toward the other agent, while exploring is a movement toward an object of interest or random (when no object is found). Each move is a change in position that cannot exceed the agent’s speed.⁶

Given the need N and its threshold T, the implemented decision rule is (Figure 7):

Need is need to receive care in the case of the child and need to provide care in the case of the caregiver; S_E is compared in the avoidant case, D_P is compared in the ambivalent case; T_E and T_P are, respectively, the target emotional separation and perceived distance for the agent; k_E and k_P are constant values (cf. Simulations section).

The system acts as a multi-dimensional controller. It compares current dimensional levels to target ones and takes actions that tend to decrease the difference between the two.

For any given simulation session, interactions can be either avoidant or ambivalent. A basic activation mechanism based only on the dimensional level could be implemented by a winner-take-all rule that evaluates each level’s softmax function (Bishop, 2006) and selects its maximum:

d_i,i = 1,2 selected when s(d_i) = Max(s(d₁),s(d₂)), where:

d₁ = A_v (avoidance), d₂=A_m (ambivalence),

s⁢(di)=eβ⁢(di+ri)∑j=1,2eβ⁢(dj+rj) (softmax function),

r₁,r₂, normally distributed random numbers.

Here, the random numbers r_i account for contextual noise, and the parameter β can be used to act on the influence of the dimensional levels’ gap. A larger β tends to invert the effect of such a gap.

We first report relevant behavioral details concerning the simulations for representative levels of avoidance and ambivalence: (a) extremely low (A_v = 0.1, A_m = 0.1), (b) mid (A_v = 0.5, A_m = 0.4), and (c) extremely high (A_v = 0.9, A_m = 0.9; Figures 8, 9). We focus on the trajectories followed by the agents in the lab,⁸ the child’s trajectory relative to the caregiver ((x_a−x_c,y_a−y_c)), and the distance between the agents.

The percentage values over 1,000 iterations are reported for the following variables: (A) The need N – child’s need to receive care (N_R) and caregiver’s need to give care (N_G; above threshold). (B) Explorative and approaching behaviors. Also, the mean values over 1,000 iterations are reported for the distance between the two agents in the lab and the number of iterations with no provision of care.

The results obtained for avoidance/insensitivity and ambivalence/unresponsiveness are discussed considering the curves in their progression from left to right, i.e., for increasing dimensional values (black is used for the child, red for the mother).

The compliance of the above results with what expected according to the literature (Figure 1) is confirmed by the comparison of simulated need, approach, and exploration trends (solid) with the expected ones (dashed; in black for the child, in red for the caregiver; Figure 13). Both in the avoidant (Figures 13A–C) and ambivalent (Figures 13D–F) cases, the simulated trends match those expected.

In the DAM, psychological variables – in the mind of the agents – and behavioral variables – observable in the lab – are distinguished. From the basic setting of two autonomous dot-like agents moving in a limited space, two measurable features that can be interpreted by the child as cues for the construction of dimensional levels (i.e., psychological representations) are selected:

Therefore, from two behavioral variables, two corresponding psychological variables are derived (Equations 8, 9) – through a formula that is expected to depend on the agents and interaction context. The attacher uses these psychological variables (S_E, D_P) as dimensional levels to be compared with the corresponding stored dimensional set-goals (T_E, T_P) and select an action. Therefore, attachment works as a multidimensional control system (representations are compared to drive action).

In our model, the agents are driven by intrinsic motivations – the child by attachment and exploration, the mother by caregiving and exploration. Moreover, each agent’s need is influenced by the other’s (coupled Equations 1–2 and 3–4), thereby creating an intertwined dynamics between the motivational systems. In this respect, a relevant role is played by the time spent without giving care – implemented by an iteration counter (K) – which is the main determinant of cycles of attachment and caregiving activations alternated by exploration. In fact, the interplay between attachment and exploration is central to the infant’s attachment patterns (Bowlby, 1969/1982; Ainsworth et al., 1978; Hesse, 2008).

Simulations show that the DAM reproduces the quality expected by real avoidant and ambivalent relationships. Increasing the dimensional levels, children go from being “anti-avoidant” or ‘anti-ambivalent’ to secure to highly avoidant or ambivalent (Figures 8, 9). The DAM covers a broader range of cases compared to the standard theory (Ainsworth et al., 1978; Main and Solomon, 1990; Hesse, 2008), suggesting that extremely low dimensional levels (A_v = 0.1, A_m = 0.1) may correspond to rare instantiations of dysfunctional conditions – such as particular cases of compulsive dependence or self-reliance (Bowlby, 1973; Fonagy et al., 2002; Beck et al., 2015) – usually not considered for attachment classification. On the other hand, mid-levels (A_v = 0.5, A_m = 0.4) correspond to secure attachment, which is taken as the healthy standard, reflected in an optimal balance between attachment and exploration, where the child explores while being taken care of from time to time. Finally, the highest dimensional levels (A_v = 0.9, A_m = 0.9) strikingly represent the quality of the extreme avoidant and ambivalent relationships. The essence of these patterns is visually emphasized by the child’s and mother’s trajectories in the lab (Figure 10), which reflect the avoidant dyad’s independence and the ambivalent attacher’s over-involvement in the relationship related to their mother’s lack of care (Hesse, 2008; Mikulincer and Shaver, 2016; cf. attached video clips, see text footnote 9). The adherence of the DAM to attachment phenomena is further illustrated by the agents’ need as a function of the stored dimensional level (Figures 11A, 12A) and by the corresponding approach and exploration rates (Figures 11B, 12B). When the level raises, the attacher’s need for care decreases in the case of avoidance and increases in the case of ambivalence. At the same time, the avoidant explorations and the ambivalent approaches surge. Attacher’s and caregiver’s curves show matching trends, which entirely correspond to those expected (Figure 13).

The compliance of the DAM – in terms of need, approach, and exploration trends – with the expected attachment patterns demonstrates that such patterns can be generated by different dimensions. For each dimension, a specific configuration of agents’ goals needs to be considered. In particular, the high rate of child’s exploration in the avoidant case is the consequence of similar goals of high emotional separations. On the other hand, the high rate of child’s approaches in the ambivalent case is the consequence of opposite goals in terms of perceived distance. In other words, these outcomes can involve different areas of the relationship rather than be produced by opposite levels of the same dimension, as assumed by the early attachment theory.

Finally, it should be noted that, in the presented model, the drive-equations’ terms c_0a,av, c_0c,av, c_0a,am, c_0c,am were kept constant for simplicity. However, the form of such equations suggests that those terms are to be expected to depend on the dimensional levels A_v and A_m. Indeed, when K is zero (i.e., care is provided), the equations become:

and, all other things being equal (i.e., N, S_E, D_P), the drives will drop differently for different levels of avoidance and ambivalence. The drop will be greater for a more avoidant child (smaller c_0a,av) and smaller for a more ambivalent child (greater c_0a,am). Therefore, choosing appropriately variable coefficients is expected to further improve modeling performance. In fact, in the avoidant case, the following simple linear relationships:

– that implement the predicted kind of variability – enhance the system’s capacity to reproduce avoidance, as proven by the corresponding augmented range of needs, approaches, and explorations (Figure 14) compared to the above-illustrated case of constant c_0a,av and c_0c,av (Figure 11).

In conclusion, the presented DAM provides first computational support to the DP, suggesting it to be a convenient theoretical standpoint for attachment computational modeling. Adopting this perspective should help solve the limitations inherent to the early theory. This model also confirms the adequacy of the ABMs for the investigation of attachment (Petters and Waters, 2015).