A) Gain function of the customer

Generally, by consuming a certain amount of power, a customer experiences a certain gain which reflects the level of satisfaction. For example, when reading under a bad lighting condition, a customer will feel happy by turning on a light, and such a happiness can be characterized by a certain gain. We assume that each customer i has a minimal power demand d _i ^min to operate some essential appliances such as refrigerator and air conditioner. If the demand is smaller than d _i ^min, the customer will feel very uncomfortable, so the gain is zero. Once the power demand reaches d _i ^min, the customer experiences a gain g _i . After satisfying the minimal demand constraint, the gain will increase by a certain value if an additional appliance is turned on. Since customers are intelligent and rational, they will always first turn on the appliance that can bring the largest increase of their level of satisfaction. For example, a customer in a dark room will turn on the light first, whereas the customer who feels hot will turn on the fan first. With such an intuition, the gain function should be an increasing step function with the step size decreasing over the demand for all demand that is larger than the minimal demand constraint, e.g., the red dot curve in Fig. 2. Since the gain function characterizes the level of satisfaction of the customer, it can be different under different climate conditions and different moods of the customer. For example, the pink dash curve and blue dot-dash curve in Fig. 2 can be the gain functions under two different conditions. To better understand the behavior of the customers, we assume that the gain function measures the average level of satisfaction under different conditions such as climate and mood conditions.

Fig. 2. An illustration of the gain function. The red, blue, and pink dot-dash curves stand for the gain functions under different climate conditions and different moods of the customer, whereas the cyan curve is the gain function that measures the average level of satisfaction under different conditions.

From the above discussion, we can see that the gain should be zero for any demand smaller than the minimal demand constraint. For the demand larger than the minimal demand constraint, the gain function should be a monotonically increasing concave function with the level of satisfaction gradually saturating. After the demand reaching the maximal demand constraint which can be the total power demand for operating all appliances, the gain function should remain constant. There are many possible gain functions. In this paper, we use a modified quadratic gain function G _i (d) defined in (2) and illustrated as the cyan solid curve in Fig. 2. A similar gain function was used in [Reference Samadi, Mohsenian-Rad, Schober, Wong and Jatskevich20]. Note that our scheme can be easily extended to other gain functions.

(2) $$G_i\lpar d\rpar = \left\{\matrix{0\comma \; \hfill &\hbox{if} 0 \leq d \lt d_i^{\min}\semicolon \; \hfill \cr - {\alpha_i \over 2} \lpar d - d_i^{\min}\rpar ^2 \hfill \cr \quad + w_i\lpar d-d_i^{\min}\rpar + g_i\comma \; \hfill &\hbox{if } d_i^{\min} \leq d \leq {w_i \over \alpha_i} \hfill \cr {} & \quad+ d_i^{\min}\semicolon \; \hfill \cr {w_i^2 \over 2\alpha_i} + g_i\comma \; \hfill &\hbox{if } d \gt {w_i \over \alpha_i} + d_i^{\min}\comma \; \hfill} \right.$$

where d _i ^min is the minimal power demand, g _i is the gain of the minimal power demand, α _i is the parameter controlling the speed of increase of the quadratic function which can be time-varying, and w _i is the declivity of the parabola at d = d _i ^min which is fixed over time.

B) The proposed mechanism for power substation

To motivate customers to report their true optimal demands to power substation, we propose an incentive compatible mechanism as follows. At the beginning of time slot t, the power substation announces a reference price p ^r to all customers. How to determine the reference price p ^r will be discuss in Section III-F. After receiving the reference price, each customer computes the optimal demand $d_{i}^{\star}$ by maximizing the intermediate utility function as follows:

(3) $$\eqalign{d_i^{\star} &= \arg \max_{d} \lambda G_i\lpar d\rpar - p^r d \cr &= \left\{\matrix{{w_i-p^r/\lambda \over \alpha_i} + d_i^{\min}\comma \; \hfill &\hbox{if} {\lpar \lambda w_i - p^r\rpar ^2 \over 2\lambda \alpha_i} \hfill \cr {} \hfill &\quad + \lambda g_i \geq p^r d_i^{\min} \hfill \cr {} \hfill &\hbox{and} w_i \geq p^r/\lambda\comma \; \hfill \cr d_i^{\min}\comma \; \hfill &\hbox{if} w_i \lt p^r/\lambda \hbox{and} \lambda g_i \geq p^r d_i^{\min}\comma \; \hfill \cr 0\comma \; \hfill &\hbox{else}\comma \; \hfill} \right.}$$

Nevertheless, we should notice that customers may not report their true optimal demand $d_{i}^{\star}$ to the power substation due to their selfish nature. Let us assume that customer i reports $\hat{d}_{i}$ to the power substation. After receiving all the demands from the customers, the power substation announces to each customer i the cost function $C_{i}\lpar p_{i}\comma \; d_{i}\comma \; \hat{d}_{i}\rpar $ as follows

(4) $$C_i \lpar p_i\comma \; d_i\comma \; \hat{d}_i\rpar = \left\{\matrix{p_i\hat{d}_i\comma \; \hfill &\hbox{if } d_i \leq \hat{d}_i\semicolon \; \hfill \cr p_i\hat{d}_i + \lambda\Delta\lpar d_i - \hat{d}_i\rpar + \lambda \rho\comma \; \hfill &\hbox{if } d_i \gt \hat{d}_i. \hfill} \right.$$

where p _i is defined as

(5) $$p_i = p^r + {m \over \hat{d}_i}\comma \;$$

and m is a constant which can be treated as the maintenance fee, $\Delta \geq \max \lcub w_{1}\comma \; \ldots\comma \; w_{N}\rcub $ and $\rho \geq \max\lcub g_{1}\comma \; \ldots\comma \; g_{N}\rcub $ are two fixed parameters. From (4), we can see that customers are punished for both overreporting and underreporting. For overreporting, customers will be charged for what they reported, which can be treated as a pre-paid rule. For underreporting, customers will receive a penalty that is linear in the deviation $d_i - \hat{d}_{i}$ .

Finally, according to the price p _i , each customer consumes power d _i and pays $C_{i}\lpar p_{i}\comma \; d_{i}\comma \; \hat{d}_{i}\rpar $ , and the utility function of customer i can be computed as in (1).

The detailed interactions between the power substation and customers are summarized in Algorithm 1 In the next three subsections, we will prove that the proposed demand response mechanism is incentive compatible and the outcome of the proposed demand response mechanism maximizes the social welfare, which is the sum of the customers' utilities and the revenue of the substation, and is proportionally fair in terms of the utility function.

Algorithm 1: Incentive compatible mechanism design for demand response

C) Incentive compatible property

In this subsection, we prove that the proposed mechanism is incentive compatible, which means that all customers are motivated to report and consume the optimal demands, i.e., their utility is maximized when $d_{i}=\hat{d}_{i}=d_{i}^{\star}$ , and any deviation will lead to a utility loss.

Proof: To prove Lemma 1 , we need to show that $U_{i} \lpar d_{i}\comma \; \hat{d}_{i}\rpar - U_{i}\lpar \hat{d}_{i}\comma \; \hat{d}_{i}\rpar \leq 0\comma \; \forall d_{i}$ , with equality if and only if $d_i = \hat{d}_{i}$ . Since the payment function $C_{i}\lpar p_{i}\comma \; d_{i}\comma \; \hat{d}_{i}\rpar $ in (4) is a piecewise function of d _i , we will compute the difference between $U_{i}\lpar d_{i}\comma \; \hat{d}_{i}\rpar $ and $U_{i}\lpar \hat{d}_{i}\comma \; \hat{d}_{i}\rpar $ for each region.

• • If $d_{i} \leq \hat{d}_{i}$ , according to (2), (4), and (1), we have

  (6) $$\eqalign{&U_i\lpar d_i\comma \; \hat{d}_i\rpar - U_i\lpar \hat{d}_i\comma \; \hat{d}_i\rpar \cr &\quad = \lambda G_i\lpar d_i\rpar - C_i\lpar p_i\comma \; d_i\comma \; \ hat{d}_i\rpar \cr &\qquad - \left[\lambda G_i\lpar \hat{d}_i\rpar - C_i\lpar p_i\comma \; \hat{d}_i\comma \; \hat{d}_i\rpar \right]\cr &\quad = \lambda \left[G_i\lpar d_i\rpar - G_i\lpar \hat{d}_i\rpar \right]\cr &\quad \leq 0\comma \; }$$
  where the last inequality comes from the monotonically increasing property of G _i (.) function, and the equality holds if and only if $d_{i} = \hat{d}_{i}$ .

• • Similarly, if $d_{i} \gt \hat{d}_{i}$ , from (2), (4), and (1), we have

  (7) $$\eqalign{& U_i\lpar d_i\comma \; \hat{d}_i\rpar - U_i\lpar \hat{d}_i\comma \; \hat{d}_i\rpar \cr &\quad = \lambda G_i\lpar d_i\rpar -C_i\lpar p_i\comma \; d_i\comma \; \hat{d}_i\rpar \cr &\qquad -\left[\lambda G_i\lpar \hat{d}_i\rpar - C_i\lpar p_i\comma \; \hat{d}_i\comma \; \hat{d}_i\rpar \right]\cr &\quad = \lambda G_i\lpar d_i\rpar - \lambda G_i \lpar \hat{d}_i\rpar - \lambda \Delta \lpar d_i - \hat{d}_i\rpar - \lambda \rho \cr &\quad \leq \lambda \left[G_i\lpar d_i\rpar - G_i \lpar \hat{d}_i\rpar - w_i\lpar d_i - \hat{d}_i\rpar - g_i \right]\cr &\quad = \lambda \left\{\matrix{-w_i\lpar d_i-\hat{d}_i\rpar -g_i \lt 0\comma \; \hfill \cr \quad \hbox{if } 0 \leq \hat{d}_i \lt d_i \lt d_i^{\min}\semicolon \; \hfill \cr -{\alpha_i \over 2}\lpar d_i - d_i^{\min}\rpar ^2 + w_i\lpar \hat{d}_i - d_i^{\min}\rpar \lt 0\comma \; \hfill \cr \quad \hbox{if } 0 \leq \hat{d}_i \lt d_i^{\min} \leq d_i \leq {w_i \over \alpha_i} + d_i^{\min}\semicolon \; \hfill \cr -w_i\left(d_i - \hat{d}_i - {w_i \over 2\alpha_i} \right)\lt 0\comma \; \hfill \cr \quad \hbox{if } 0 \leq \hat{d}_i \lt d_i^{\min} \leq {w_i \over \alpha_i} + d_i^{\min} \lt d_i\semicolon \; \hfill \cr -{\alpha_i \over 2} \lpar d_i - \hat{d}_i\rpar \lpar d_i + \hat{d}_i - 2d_i^{\min}\rpar - g_i \lt 0\comma \; \hfill \cr \quad \hbox{if } d_i^{\min} \leq \hat{d}_i \lt d_i \leq {w_i \over \alpha_i} + d_i^{\min}\semicolon \; \hfill \cr -w_i\lpar d_i - d_i^{\min}\rpar + {w_i^2 \over 2\alpha_i} + {\alpha_i \over 2}\lpar \hat{d}_i - d_i^{\min}\rpar ^2 \hfill \cr \quad - g_i \lt 0\comma \; \hfill \cr \quad \hbox{if } d_i^{\min}\leq \hat{d}_i \leq {w_i \over \alpha_i} + d_i^{\min} \lt d_i\semicolon \; \hfill \cr - w_i\lpar d_i - \hat{d}_i\rpar - g_ i \lt 0\comma \; \hfill \cr \quad \hbox{if } {w_i \over \alpha_i} + d_i^{\min} \lt \hat{d}_i \lt d_i. \hfill} \right. \cr &\quad \lt 0\comma \; }$$
  where the first inequality comes from the definitions of Δ and ρ that Δ≥ max {w ₁, …, w _N } and ρ≥ max {g ₁, …, g _N }.

In all, according to (6) and (7), we can show that $U_{i}\lpar d_{i}\comma \; \hat{d}_{i}\rpar \leq U_{i} \lpar \hat{d}_{i}\comma \; \hat{d}_{i}\rpar \comma \; \forall d_{i}$ , with equality if and only if $d_{i} = \hat{d}_{i}$ . Therefore, after reporting $\hat{d}_{i}$ , the best strategy of customer i at the consumption stage is to consume $\hat{d}_{i}$ . □

Proof: To prove Theorem 1 , we need to show that the utility of the customer is maximized when he/she reports and consumes the optimal demand, i.e., $U_{i}\lpar d_{i}\comma \; \hat{d}_{i}\rpar $ is maximized at $d_{i}=\hat{d}_{i}=d_{i}^{\star}$ . According to (3), (5), (4), (1), and Lemma 1 , we have

(8) $$\eqalign{U_i\lpar d_i\comma \; \hat{d}_i\rpar &\leq U_i\lpar \hat{d}_i\comma \; \hat{d}_i\rpar \cr & = \lambda G_i\lpar \hat{d}_i\rpar - C_i \lpar p_i\comma \; \hat{d}_i\comma \; \hat{d}_i\rpar \cr &= \lambda G_i \lpar \hat{d}_i\rpar - p_i \hat{d}_i \cr &= \lambda G_i \lpar \hat{d}_i\rpar - p^r \hat{d}_i - m \cr &\leq \lambda G_i\lpar d_i^{\star}\rpar - p^r d_i^{\star} - m\comma \; }$$

where the first inequality is the consequence of Lemma 1 ; The three equalities come from the definition of utility function shown in (1), the definition of payment function shown in (4), and the definition of price function shown in (5), respectively. The last inequality comes from the definition of $d_{i}^{\star}$ shown in (3).

Note that equality in (8) holds if and only if $d_{i}=\hat{d}_{i}=d_{i}^{\star}$ . Therefore, all customers will try to report and consume the optimal demand to achieve maximal utility, and any deviation will lead to a utility loss, i.e., the proposed mechanism is incentive compatible. □

D) Maximizing social welfare

In this subsection, we prove that the proposed mechanism leads to an equilibrium that maximizes the social welfare, which is the sum of the customers' utilities and the revenue of the substation.

Theorem 2

The proposed mechanism maximizes the social welfare, i.e. $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ is the solution to the following optimization problem:

(9) $$\eqalign{&\max_{d_i\comma \forall i} \sum_{i=1}^N G_i\lpar d_i\rpar \cr & s.t.\ \sum_{i=1}^N d_i \leq d^{total}}$$

with $d^{total} = \sum_{i=1}^{N} d_{i}^{\star}$ .

Proof: We will prove the theorem using contradiction. Suppose there exists a solution $\lpar \hat{d}_{1}\comma \; \hat{d}_{2}\comma \; \ldots\comma \; \hat{d}_{N}\rpar $ that satisfies the constraint $\sum_{i=1}^{N} \hat{d}_{i}\leq d^{total}$ and can lead to a larger social welfare than $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ , i.e.,

(10) $$\sum_{i = 1}^N G_i\lpar \hat{d}_i\rpar \gt \sum_{i = 1}^N G_i\lpar d_i^{\star}\rpar.$$

Then, since $\sum_{i=1}^{N} \hat{d}_{i}\leq d^{total}=\sum_{i=1}^{N} d_{i}^{\star}$ , we have

(11) $$\eqalign{\sum_{i = 1}^N \left(G_i\lpar \hat{d}_i\rpar - p^r \hat{d}_i \right)&= \sum_{i = 1}^N G_i\lpar \hat{d}_i\rpar - p^r \sum_{i = 1}^N \hat{d}_i\comma \; \cr &\gt \sum_{i = 1}^N G_i \lpar d_i^{\star}\rpar - p^r \sum_{i = 1}^N \hat{d}_i\comma \; \cr &\geq \sum_{i = 1}^N G_i\lpar d_i^{\star}\rpar - p^r \sum_{i = 1}^N d_i^{\star}\comma \; \cr &= \sum_{i = 1}^N \left(G_i\lpar d_i^{\star}\rpar - p^r d_i^{\star} \right).}$$

According to (11), there is at least one $\hat{d}_{i}$ such that $G_{i}\lpar \hat{d}_{i}\rpar - p^{r}\hat{d}_{i} \gt G_{i}\lpar d_{i}^{\star}\rpar - p^{r}d_{i}^{\star}$ . This contradicts with the definition of $d_{i}^{\star}$ in (3). Therefore, $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ is the solution to the optimization problem in (9) that maximizes the social welfare. □

E) Proportionally fair solution

In this subsection, we prove that the proposed mechanism leads to the solution that is proportionally fair in terms of utility. Proportional fairness is the generalization of the Nash bargaining solution for multiple users [Reference Kelly29, Reference Han, Ji and Liu30]. Under the Nash bargaining, a transfer of resources between two users is favorable and fair if the percentage increase in the utility of one player is larger than the percentage decrease in utility of the other user. Under proportional fairness, the fair allocation should be such that, if compared to any other feasible allocation of utilities, the aggregate proportional change is less than or equal to zero. A formal definition of proportional fairness is given as follows.

Definition 1

A utility distribution is said to be proportionally fair when any change in the distribution of utilities results in the sum of the proportional changes being non-positive, i.e.,

(12) $$\sum_i {U_i - \tilde{U}_i \over \tilde{U}_i} \leq 0\comma \; \quad \forall U_i \in {\bf S}\comma \;$$

where Ũ _i and U _i are the proportionally fair utility and any other feasible utility for the ith user, respectively, and S is a closed and convex subset of ℜ ^N to represent the set of feasible utility functions that the users can achieve.

Theorem 3

The proposed mechanism leads to the solution that is proportionally fair in terms of utility, i.e. $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ is the solution to the following optimization problem:

(13) $$\max_{d_i\comma \forall i} \prod_{i = 1}^N \left(G_i\lpar d_i\rpar - p^rd_i \right).$$

Proof: We will prove the theorem using contradiction. Suppose there exists a solution $\lpar \hat{d}_{1}\comma \; \hat{d}_{2}\comma \; \ldots\comma \; \hat{d}_{N}\rpar $ that can lead to a larger product of utility than $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ , i.e.,

(14) $$\prod_{i=1}^N \left(G_i\lpar \hat{d}_i\rpar - p^r\hat{d}_i\right)\gt \prod_{i = 1}^N \left(G_i\lpar d_i^{\star}\rpar - p^rd_i^{\star}\right).$$

In such a case, there is at least one $\hat{d}_{i}$ such that $G_{i}\lpar \hat{d}_{i}\rpar -p^{r}\hat{d}_{i}>G_{i}\lpar d_{i}^{\star}\rpar -p^{r}d_{i}^{\star}$ . This contradicts with the definition of $d_{i}^{\star}$ in (3). Therefore, $\lpar d_{1}^{\star}\comma \; d_{2}^{\star}\comma \; \ldots\comma \; d_{N}^{\star}\rpar $ is proportionally fair in terms of utility. □

F) Dynamic pricing of the power substation

From the above discussion, we can see that the proposed mechanism is incentive compatible and can lead to the solution that is proportionally fair and social welfare maximizing, due to which all rational customers are motivated to report and consume the optimal demand. In such a case, according to (3), the average power consumption of the customers at time slot t can be computed as follows:

(15) $$\eqalign{D^{average} \lpar t\rpar & = {1 \over N} \sum_{i = 1}^N d_i^{\star} \lpar t\rpar \cr & = {1 \over N} \sum_{i = 1}^N \left({w_i - p^r\lpar t\rpar /\lambda \over \alpha_i \lpar t\rpar } + d_i^{\min} \right).}$$

Here, we exclude the inactive customers whose optimal demand is zero and simply assume N is the total number of active customers. Moreover, we assume that the parameters w _i and d _i ^min are time-invariant parameters, whereas the parameter α _i (t) is a time-variant parameter.

As discussed in Section III-A, α _i (t) is the parameter controlling the speed of increase of the quadratic gain function. According to (15), if ${1 \over \alpha_{i}\lpar t\rpar }$ is modeled as a Gaussian distribution with mean μ_α(t) and constant variance σ_α ², then, with the law of large numbers, the average power consumption of all customers can be approximated as

(16) $$\eqalign{D^{average}\lpar t\rpar &\approx \mu_{\alpha}\lpar t\rpar \left({1 \over N} \sum_{i = 1}^Nw_i - p^r\lpar t\rpar /\lambda \right)\cr &\quad + {1 \over N} \sum_{i = 1}^N d_i^{\min}\comma \; \cr &= \mu_{\alpha}\lpar t\rpar \left(W - p^r\lpar t\rpar /\lambda \right)+ Q\comma \; }$$

where $W = {1 \over N}\sum_{i=1}^{N} w_{i}$ and $Q = {1 \over N}\sum_{i=1}^{N}d_{i}^{\min}$ .

From (16), we can see that, given W, Q, and μ_α(t), there is a direct relationship between p ^r (t) and D ^average (t). Therefore, by dynamically adjusting the reference price p ^r (t), we can control the average demand D ^average (t) to meet the target average demand D ^target (t) as follows

(17) $$p^r \lpar t\rpar = \lambda \left[W - {D^{target}\lpar t\rpar - Q \over \mu_{\alpha}\lpar t\rpar } \right].$$

Since W and Q are two constants, we assume that they are known or can be well estimated by the power substation using the demand history. The μ_alpha(t) is the mean of the parameter ${1 \over \alpha_i \lpar t\rpar }$ controlling the increasing speed of the gain function, which means that μ_α(t) should be reasonably smooth over the time index t. Therefore, we propose to use Auto-Regressive (AR) process to model μ_α(t), i.e., μ_α(t) can be represented as a linear combination of μ_α(t − 1),…,μ_α(t − l) plus an additive white Gaussian noise,

(18) $$\mu_{\alpha}\lpar t\rpar = \gamma_1 \mu_{\alpha}\lpar t - 1\rpar + \cdots + \gamma_l \mu_{\alpha} \lpar t - l\rpar + n_{\mu_{\alpha}}\lpar t\rpar \comma \;$$

where γ₁, γ₂, …, γ _l are the AR coefficients, and $n_{\mu_{\alpha}}\lpar t\rpar $ is the additive white Gaussian noise with mean zero and variance $\sigma_{\mu_{\alpha}}^2$ .

According to the discussions above, the dynamic pricing algorithm of the power substation can be summarized as follows. At time slot t, the power substation announces a reference price p ^r (t). Based on the reference price, all customers report their optimal demand to the power substation. After receiving all demands from customers, the power substation computes μ_α(t) using

(19) $$\mu_{\alpha}\lpar t\rpar = {D^{average}\lpar t\rpar - Q \over W - p^r \lpar t\rpar /\lambda}.$$

Then, according to the AR modeling of μ_α(t), the power substation estimates μ_α(t + 1) using

(20) $$\hat{\mu}_{\alpha}\lpar t + 1\rpar = \gamma_1 \mu_{\alpha}\lpar t\rpar + \cdots + \gamma_l \mu_{\alpha}\lpar t - l + 1\rpar.$$

Finally, based on the estimated $\hat{\mu}_{\alpha}\lpar t+1\rpar $ , the power substation computes the reference price at time t + 1 using the following equation:

(21) $$p^r\lpar t + 1\rpar = \lambda \left[W - {D^{target}\lpar t + 1\rpar - Q \over \hat{\mu}_{\alpha}\lpar t + 1\rpar } \right].$$