IOTpay: continuous, variable-rate, high-res, device-to-device payment system

What is claimed is: 1. A system to execute payment comprising: a payor device comprising a first processor and a first memory: and a payee device comprising a second processor and a second memory; wherein the first memory stores one or more instructions that, when executed by the first processor, cause the payor device to: hold a string of bits (S), such that each bit in S has a value V and where the identity of each bit in S was randomly assigned from the set {0,1} by a mint that at a previous time loaded S onto the payor device; determine a first number (p) of bits for a first transacted value; execute a payment of the first transacted value by transferring the last p bits of S to the payee device, wherein the transfer of the p bits begins at time point t1 and ends at time point t2 at a first rate of payment defined by ((first transacted value)/t2-t1); determine a second number (p′) of bits for a second transacted value; subsequent to the payment of the first transacted value, execute a payment of the second transacted value by transferring the last p′ bits in S to the payee device, wherein the transfer of the p′ bits begins at time point t3 and ends at time point t4 at a second rate of payment defined by ((second transacted value)/t3-t4); wherein the second memory stores one or more instructions that, when executed by the second processor, cause the payee device to: bill the payor device at the first rate of payment from time point t1 to time point t2 and the second rate of payment from time point t3 to time point t4; send the bits of S received from the payor device to the mint to validate the identity of the bits of S. 2. The system of claim 1 wherein the payor device passes a unique id of the payor device to the payee device; and wherein the payee device trusts the payment before validating it with the mint. 3. The system of claim 1 wherein the payor device and the payee device each include a human-machine interface; wherein the human-machine interface features a display screen showing available balance and payment history, and the payor device also features communication buttons for receiving input from a user. 4. The system of claim 1 wherein the payor device is fitted with an ownership verification apparatus which is either an entry port for a security code, or a biometric port, such that no payment is effected before the ownership-verification apparatus is satisfied. 5. The system of claim 1 wherein the payor device and the payee device are embedded in a larger system and payment takes place without direct human intervention. 6. The system of claim 1 wherein the payment is for the use of home and industrial utilities like electricity, gas, and water; wherein the payee device also includes: (i) a consumption-to-billing processor that computes a billing requirement $B reflecting the monetary value of utility, in the amount C, being consumed, between time point t5 and time point t6; (ii) paid bits container: an electronic storage stored in the payee device, where the paid bits are stored in the order transferred from the payor device to the payee device; (iii) communication facilities to the mint that minted the paid money bits; (iv) a utility flow switch, controlled by the payee device; wherein the consumption-to-billing processor has access to all the factors that are used in translating a variable consumption of the utility to the billing reflecting that consumption; wherein the paid bits container is large enough to contain incoming bits for an arbitrary period of time T by which time the payee device is contacting the mint via an electronic public communication network and verifies the payment of all the bits that were paid during the last T period; wherein the payee device shuts off the utility flow switch in the event that billing is not responded to with due payment, the utility flow switch is being reopened by the payee device when all due money is paid from the payor device to the payee device. 7. The system in claim 6 wherein the utility is an electrical power and where the billing reflects time of day and overall load on a grid; wherein the system of claim 6 also includes a power generator (PGF); wherein, if the PGF generates more electrical power than a consumer consumes, then an extra power, E, is sold to a power supply, using the following pay-back system: the consumption-to-billing processor computes the monetary value U of the extra power E, and the payee device computes a number of bits r=U/V, then the payee device transfers to the payor device r money bits that have been accumulated in the paid bit container; and the r money bits are transferred from the payee device to the payor device in reverse order. 8. The system of claim 1 wherein a need arises for payment in reverse, and a controller of the payor device and a controller of the payee device agree that the payor device becomes the payee device, and the payee device becomes the payor device.