초록 ▼

Building monitoring and control systems including bi-directional radio frequency links between master and remote units wherein the remote units operate in a low power, non-receiving state a majority of the time is disclosed. The bi-directional capability allows coordinated scheduling which aids in a

Building monitoring and control systems including bi-directional radio frequency links between master and remote units wherein the remote units operate in a low power, non-receiving state a majority of the time is disclosed. The bi-directional capability allows coordinated scheduling which aids in allowing the remote units to transmit data only at periodic time intervals to extend battery life. The bi-directional capabilities also allow for re-read requests for alarm validation and for putting remote units in armed and disarmed states for power conservation.

대표청구항 ▼

What is claimed is: 1. A building monitoring and control and control system utilizing bi-directional radio frequency communication comprising: at least one master unit including a radio frequency transmitter and receiver; and a plurality of remote units having a radio frequency transmitter and rece

What is claimed is: 1. A building monitoring and control and control system utilizing bi-directional radio frequency communication comprising: at least one master unit including a radio frequency transmitter and receiver; and a plurality of remote units having a radio frequency transmitter and receiver, the remote units capable of transmitting to and receiving from the master unit of the building monitoring and control system, the remote units having a first low power consumption state in which the remote units can neither receive nor transmit, a second power consumption state in which the units can receive, and a third power consumption state in which the units can transmit; means for validating a sensor event, the means for validating including means for requesting reading of the sensor initiated by the master unit and means for reading the sensor by the remote unit responsive to the means for requesting; wherein the plurality of remote units comprises sensors for detecting one or more of temperature, pressure, humidity, air flow, BTU's, water, damper position, valve position, light, smoke, CO, CO2, movement, noise, vibration, glass breakage, window opening or closure, door opening or closure, or water flow; wherein the remote units have a reading sensor state in which the sensors are read by the coupled remote units, wherein the reading sensor state is entered in response to a read message received from the master unit; wherein the means for validating includes means for transmitting sensor data from the remote unit to the master unit wherein the means for validating sensor data includes at least two different validation processes; and the means for validating includes means for identifying the sensor and means for determining which of the validation processes to use depending on the identified sensor. 2. A building monitoring and control system according to claim 1, wherein at least some of the remote units comprise actuators. 3. A building monitoring and control system as recited in claim 2, wherein: the remote units have an armed state in which the sensors are active and able to measure sensor variables, and a disarmed state in which the remote units are unable to transmit messages; and the remote units have means for switching between the armed and disarmed states, and wherein the means for switching between the armed and disarmed states is responsive to a message received from the master unit. 4. A building monitoring and control system as recited in claim 3, wherein the remote units are unable to measure at least some sensor variables while in the disarmed state. 5. A building monitoring and control system as recited in claim 3, wherein: the remote unit includes a controller logically coupled to the receiver; the means for switching between the armed and disarmed states passes the message from the receiver to the controller, processes the message in the controller, executes arm instructions in response to an arm message, and executes disarm instructions in response to a disarm message; and the disarm instructions prevent the sensor change messages from being transmitted. 6. A building monitoring and control system according to claim 1, wherein the second and third states have higher power consumption than the first state. 7. A building monitoring and control system according to claim 6, wherein the remote units are in the receive state only at predetermined intervals. 8. A building monitoring and control system as recited in claim 7, wherein in normal operation the remote units are in the receive state only after being in the transmit state. 9. A building monitoring and control system as recited in claim 8, wherein the remote units are in the receive state and await an acknowledgment from the master unit only after being in the transmit state. 10. A building monitoring and control system as recited in claim 7, wherein the remote units transmit messages at periodic intervals. 11. A building monitoring and control system as recited in claim 7, wherein the remote units transmit messages after a predetermined event for a discrete period of time and then await an acknowledgment of the message transmission. 12. A building monitoring and control system as recited in claim 11, wherein after the remote units receive the acknowledgment, the remote units do not further transmit the transmitted message. 13. A building monitoring and control system as recited in claim 1, wherein the validation processes waits a predetermined time before requesting an additional sensor reading and the predetermined time to wait is dependent on the identified sensor. 14. A building monitoring and control system as recited in claim 1, wherein: the means for validating includes an indication of whether to request an additional sensor reading; and the indication of whether to request the additional reading is dependent on the identified sensor. 15. A method for communicating between a remote unit and a master unit in a radio-frequency building monitoring and control system, wherein: the remote unit is capable of transmitting to and receiving messages from the master unit of the building monitoring and control system; the remote unit has a non-communicating low power consumption state in which the remote unit can neither receive nor transmit, a receiving state in which the remote unit can receive, and a transmitting state in which the remote unit can transmit; the remote unit has at least one sensor for producing a sensor change event; and wherein the at least one sensor may be for detecting temperature, BTU's, pressure, humidity, air flow, water, damper position, valve position, light, smoke, CO, CO2, movement, noise, vibration, glass breakage, window opening or closure, door opening or closure, or water flow; the method comprises: waiting for the sensor change event while in the non-communicating state; entering the transmitting state and transmitting a message upon detecting the sensor change event; entering the receiving state and waiting for acknowledgment of the data transmission; validating the sensor event, wherein the validating step comprises: receiving a request for a sensor re-read from the master unit, and the remote unit responding to the sensor re-read request by reading the sensor and transmitting a message to the master unit: wherein validating sensor data step includes at least two different validation processes; the validating step further comprising identifying the sensor, and determining which of the validation processes to use depending on the identified sensor; and returning to the waiting for sensor change step. 16. A method as recited in claim 15, further including: changing to a disarmed state upon reception of a disarm message from the master unit, wherein, while in the disarmed state, the remote unit does not, in combination, both sense sensor data from the sensor and transmit sensor data; and changing to an armed state upon reception of an arm message from the master unit, wherein, while in the armed state, the remote unit does, in combination, sense sensor data from the sensor and transmit sensor data. 17. A building monitoring and control system utilizing bi-directional radio frequency communication comprising: at least one master unit including a radio frequency transmitter and receiver; and a plurality of remote units each having a radio frequency transmitter and receiver; and wherein: the remote units are capable of transmitting to and receiving from the master unit of the building monitoring and control system and capable of generating polling events in response to a poll message received from the master unit; the remote units each have at least one timer for generating a timeout event; the remote units each have at least one sensor for measuring selected variables; the selected variables comprise temperature, pressure, humidity, air flow, water, BTU's, damper position, valve position, light, smoke, CO, CO2, movement, noise, vibration, glass breakage, window opening or closure, door opening or closure, or water flow; the remote units are capable of generating a sensor event in response to a sensor change of measurement; and the remote units each have a non-communicating state with low power consumption and in which the remote units can neither receive nor transmit, and a receiving state having higher power consumption than the non-communicating state and in which the units can receive, and the selected remote units are in the receiving state only after selected event occurrences; the selected events are selected from the group consisting of timeout events, polling events, and sensor events; wherein the remote units have a reading sensor state in which the sensors are read by the coupled remote units, wherein the reading sensor state is entered in response to a read message received from the master unit; the system further including means for validating a sensor event, the means for validating including means for requesting reading of the sensor initiated by the master unit and means for reading the sensor by the remote unit responsive to the means for requesting; the means for validating includes means for transmitting sensor data from the remote unit to the master unit; wherein the means for validating sensor data includes at least two different validation processes; and the means for validating include means for identifying the sensor and means for determining which of the validation processes to use depending on the identified sensor. 18. A building monitoring and control system as recited in claim 17, wherein: the remote units each have a transmitting state in which the remote unit can transmit and in which power consumption is higher than in the non-communicating state; and the polling event causes the remote unit to enter the transmitting state followed by entering the receiving state. 19. A building monitoring and control system as recited in claim 17, wherein: the remote units each have a transmitting state in which the remote unit can transmit and in which power consumption is higher than in the non-communicating state; the sensor event causes the remote unit to enter the transmitting state followed by entering the receiving state; and the sensor event is caused by a change in a measured variable. 20. A building monitoring and control system as recited in claim 17, wherein the remote units comprise actuators. 21. A building monitoring and control system as recited in claim 20, wherein the actuators may comprise opening, adjusting and closing valves, dampers, blinds, sprinklers, or heating control. 22. A building monitoring and control and control system utilizing bi-directional radio frequency communication comprising: at least one master unit including a radio frequency transmitter and receiver; and a plurality of remote units having a radio frequency transmitter and receiver, the remote units capable of transmitting to and receiving from the master unit of the building monitoring and control system; wherein the plurality of remote units comprises sensors for detecting one or more of temperature, pressure, humidity, air flow, BTU's, water, damper position, valve position, light, smoke, CO, CO2, movement, noise, vibration, glass breakage, window opening or closure, door opening or closure, or water flow; wherein the remote units have a reading sensor state in which the sensors are read by the coupled remote units; wherein the reading sensor state is entered in response to a read message received from the master unit, the system including means for validating a sensor event, the means for validating including means for requesting reading of the sensor initiated by the master unit and means for reading the sensor by the remote unit responsive to the means for requesting; the means for validating includes means for transmitting sensor data from the remote unit to the master unit; wherein the means for validating sensor data includes at least two different validation processes; and the means for validating include means for identifying the sensor and means for determining which of the validation processes to use depending on the identified sensor.