In an electrical load dimmer, a technique known as zero crossing detection is conventionally employed, wherein the dimmer is synchronized with one or more phases of an input line voltage to enable the dimmer to properly fire a load controlling switch, such as a TRIAC, at specific firing times with respect to the input line phase. More specifically, a zero crossing is detected by detecting a change in voltage polarity of the input line voltage. In other words, zero crossing is detected when the input line voltage changes polarity at the zero volt level, which triggers a signal in the microprocessor that the voltage level has crossed zero volts.
An electrical load dimmer works by “chopping up” an input line voltage so that the line voltage is delivered to an electrical load only during portions of an input line voltage signal. The line voltage that is delivered to the load by control of the electrical dimmer can be regarded as phase controlled input line voltage. In the case of a light source electrical load, an electrical load can include a light source as well as a driver circuit. A driver circuit among other elements can include a rectifier for rectifying portions of the phase controlled line voltage delivered from the dimmer circuit.
In prior art designs, zero-crossings of an input line voltage are detected by detecting a change in the polarity of the voltage across an input line voltage terminal and an output load terminal (that is, in two wire devices without a neutral connection), or across the input line voltage terminal and return neutral or ground wire terminal (in three wire devices with a neutral connection or two wire devices using a ground leakage path).
There is set forth herein a dimmer circuit for controlling delivery of input line voltage to a load. The dimmer circuit can include a switch coupling an input line voltage terminal to a load terminal. The dimmer circuit can be operative to provide one or more switch firing control scheme for latching the switch.
Additional features and advantages are realized through the concepts of the present invention. Other embodiments and aspects of the invention are described in detail herein and are considered a part of the claimed invention.
One or more aspects of the present invention are particularly pointed out and distinctly claimed as examples in the claims at the conclusion of the specification. The foregoing and other objects, features, and advantages of the invention are apparent from the following detailed description taken in conjunction with the accompanying drawings in which:
There is set forth herein as shown in
There is set forth herein as shown in
The dimmer circuit 100 can be operative to provide one or more switch firing control scheme for latching the switch 116. According to a zero crossing detection firing control scheme, dimmer circuit 100 can control a firing a switch 116 based on a detected zero crossing of an input line voltage and based on a selected brightness level selected by an operator. According to an unlatch monitoring switch firing control scheme, dimmer circuit 100 can monitor switch 116 for unlatching of switch 116 when switch 116 is in an OFF (unlatched) state and can control a firing of switch based on a detected unlatching of switch 116. According to a fourth quadrant firing control scheme, dimmer circuit 100 can control switch 116 to unlatch during a fourth quadrant of a half cycle of an input line voltage. According to a negative half cycle zero crossing detection firing control scheme, dimmer circuit 100 can detect an input line voltage during a negative half cycle of an input line voltage and can fire switch 116 based on a detected input line voltage detected during the negative half cycle. An input line voltage of an AC power source 88 appearing between phase side Θ and neutral side N of AC power source 88, phase controlled by dimmer circuit 100, can be applied to load 108.
In one embodiment, a direct connection by dimmer circuit 100 to neutral side N of AC power source 88 can be available and dimmer circuit 100 can be configured as a three wire dimmer circuit. In one embodiment, as is depicted in
Dimmer circuit 100 can include a controller 126 coupled to user accessible user interface 128. Controller 126 can be provided by a microprocessor, which can be incorporated on a microprocessor integrated circuit chip. Controller 126 can include one or more of a complex instruction set computer processor and a reduced instruction set computer processor. Controller 126 can include a memory 1262 and a timer 1264. An operator of dimmer circuit 100 is able to engage one or more actuators of user interface 128, which controller 126 may interpret as a command (or a set of commands) to perform one or more actions for controlling load 108. In response to the received command information, dimmer circuit 100 can control the delivery of electrical power of AC power source 88 to load 108. In one embodiment, dimmer circuit 100 can be configured so that memory 1262 stores a record of events of dimmer circuit 100 including firings of switch 116 and detected voltages detected by dimmer circuit 100. Using an output of timer 1264 a record of events recorded in memory 1262 can be a timestamped record of events, each recorded event having an associated recorded timestamp. Because nominal characteristics of AC power source 88 are known, an output of timer 1264 can indicate a current phase angle of an input line voltage.
In one embodiment, load 108 can include a light source 1082 in combination with driver circuit 1081. A driver circuit 1081 of load 108 can include a rectifier 1083 and a holding capacitor 1084. Where load 108 is of a type depicted in
In one embodiment, dimmer circuit 100 can control, for example, the amount of current flowing through load 108 by proper activation of a switch 116. In one embodiment, switch 116 can be provided by a Triode for Alternating Current (TRIAC). Switch 116 when provided by a TRIAC is a bidirectional three terminal semiconductor device that allows bidirectional current flow when an electrical signal of proper amplitude is applied to its “G” (or gate) terminal. Switch 116 when provided by a TRIAC also has a “C” (or cathode terminal) and an “A” or anode terminal.
Electrical energy can be provided to load 108 by AC power source 88 having phase (hot) side Θ and neutral side N. The electrical energy can be controlled by switch 116 to switch on load 108, increase or decrease the intensity of load 108, or switch off electrical load 108. Dimmer circuit 100 can also include a mechanical switch such as an air gap switch 114. When air gap switch 114 is open, no current flows through load 108. Opening up mechanical air gap switch 114 is referred to as a “hard switch off” which allows an operator to, for instance, change or replace a light source in load 108 without risk of an electrical shock.
In one embodiment, dimmer circuit 100 can include a controller 126 which can be coupled to detector circuit 112 and user interface 128. Controller 126, which can be provided by a microprocessor, can control the operation of switch 116. A microprocessor of dimmer circuit 100 can be provided by an off-the-shelf processor semiconductor integrated circuit (i.e., a microprocessor integrated circuit chip). Controller 126 in one embodiment can be provided by a digital control circuit, an analog control circuit, or combined digital and analog control circuit designed to perform certain actions depending on the status of various of its inputs. Controller 126 in one embodiment can be provided by a combination of a microprocessor and a control circuit. The electrical energy flowing through load 108 can be a 120/220 volt AC (alternating current), 60/50 Hz signal, etc. The AC signal (current and/or voltage) can be a sinusoidal voltage signal symmetrically alternating about a zero volt reference point, described herein. Detector circuit 112 can detect a voltage across input line voltage terminal 90 and load terminal 94. In one embodiment, as is set forth herein, detector circuit 112 can include a zero crossing detector. A zero crossing detector of detector circuit 112 can detect the zero crossings (polarity transitions) of an input line voltage which occur every half cycle. Controller 126 can use the output of a zero crossing detector of detector circuit 112 for various timing functions such as the proper timing of signals it generates to control switch 116.
Dimmer circuit 100 can include a power supply 110 coupled to input line voltage terminal 90 and load terminal 94. Power supply 110 can employ circuit elements that are used to convert an AC signal to a direct current (DC) (or voltage) that may be used to power electronic circuit components. In one embodiment, power supply 110 can be provided by a ‘cat ear” power supply circuit that limits charging voltage for charging power supply 110 to manageable and safe power conserving levels.
Controller 126 can control switch 116 through control line 115. Controller 126 can control the amount of current flowing through load 108 by applying a certain signal (e.g. a gating signal) to switch 116 through control line 115. For example, controller 126 can cause bursts of the AC signal to go through switch 116 by switching ON and switching OFF switch 116 at a desired rate. The switch ON time period of switch 116 may be equal to, less than, or more than the switch OFF time period. The amount of current flowing through load 108 can depend on the duty cycle (ratio of switch ON time period to switch OFF time period) of the signal applied to the gate of switch 116 where provided by a TRIAC and, thus, the intensity of load 108, such as the intensity of light emitted if load 108 comprises a lighting element, also will depend on this signal.
The timing diagram of
During a delay period from a zero crossing, tD, switch 116 can remain OFF (unlatched). At time t1 switch 116 can be turned ON (latched) resulting in the input line voltage being delivered to load 108 with a return path of current to neutral side N. Referring to timeline 204, timeline 204 illustrates voltage being delivered to the load 108 under a phase control depicted by timeline 202. Switch 116 can be a self commutation switch so that switch 116 stops conducting when current through switch 116 falls below holding current level. When the current through switch 116 falls below its holding current level, switch 116 can turn OFF again so that voltage will no longer be applied to load 108. As depicted, switch 116 can cut OFF at time t2 (about the zero crossing time) and switch 116 can be turned ON again (latched) at time t3.
Dimmer circuit 100 can include a firing angle ΘF and a conducting angle ΘC. A firing angle ΘF of dimmer circuit 100 is the time (tD) expressed in degrees per half cycle that switch 116 is OFF so that power is not delivered to a load 108. A conducting angle ΘC of dimmer circuit 100 is the time (tC) expressed in degrees that switch 116 is ON so that power is delivered to load 108. When an operator adjusts a dimming level of dimmer circuit 100 using user interface 128 a firing angle ΘF and conducting angle ΘC of dimmer circuit 100 changes. A dimmer circuit 100 can have a non conducting phase which can be active for the time tD prior to an initial firing of switch 116 to latch switch 116 during a half cycle. A dimmer circuit 100 can have a conducting phase which can be active for the time tC after an initial firing of switch 116 during the half cycle. For slight (high brightness) dimming, dimmer circuit 100 can cut OFF delivery of the input line voltage to load for only small portions of a cycle, portions occurring only short times from a zero crossing. For increased dimming (low brightness), dimmer circuit 100 can cut OFF delivery of the line voltage to a load for longer times from a zero crossing. In one example, should maximum brightness be desired, dimmer circuit 100 can be fired immediately by the controller 126 when the controller 126 receives the indication that a zero crossing has occurred, so that the switch 116 can be latched for the longest possible period of time before the power phase again transitions to a next half cycle. In contrast, a longer delay in firing the switch 116 after a zero crossing will maintain the switch 116 in an ON state for a lesser duration of time during the half cycle before the next transition, and will result in less current draw and, in the case of a light source, a dimmer light. A control of dimmer circuit 100 to increase brightness as depicted by timeline 206 reduces a firing angle ΘF and increases a conducting angle ΘC as depicted by arrow 212. A control of dimmer circuit 100 to decrease brightness as depicted by timeline 208 increases a firing angle ΘF as depicted by arrow 214 of dimmer circuit 100 and decreases a conducting angle ΘC also as depicted by arrow 214. Timeline 204 indicates a load voltage provided by a dimmer circuit 100 operating in accordance with the phase control as depicted in timeline 202. Timeline 206 indicates a load voltage provided by dimmer circuit 100 operating to provide increased light source brightness relative to that indicated by the load voltage depicted by timeline 204. Timeline 208 indicates a load voltage provided by dimmer circuit 100 operating to provide decreased light source brightness relative to a brightness that is indicated by the load voltage depicted by timeline 204.
According to methods and apparatus as set forth herein, dimmer circuit 100 can be operative to provide one or more switch firing control scheme so that operation of dimmer circuit 100 can be in accordance with the ideal operation as depicted in
According to one switch firing control scheme that can be provided by dimmer circuit 100, which can be regarded as a zero crossing detection firing control scheme, dimmer circuit 100 can detect zero crossings of an input line voltage using one of a 0V zero crossing detection method or a nonzero threshold voltage detection method that detects for a voltage having a nonzero absolute value of greater than 0 volts as set forth herein.
According to another switch firing control scheme that can be provided by dimmer circuit 100, which firing control scheme can be regarded as a switch unlatch monitoring firing control scheme, dimmer circuit 100 can monitor for changes in a switch voltage, VSWITCH (the voltage across input line voltage terminal 90 and load terminal 94) when switch 116 is in a latched state, the switch voltage indicative of the switch latched/unlatched state. Based on a detection of a switch 116 unlatching, dimmer circuit 100 can fire the switch 116, so that an unlatching period is minimized (e.g. by applying in response to the detection without delay a gating signal in the case switch 116 is provided by a TRIAC).
According to another switch firing control scheme that can be provided by dimmer circuit 100, which can be regarded as a fourth quadrant firing control scheme, dimmer circuit 100 can control switch 116 to unlatch during a fourth quadrant of a half cycle of an input line voltage.
According to another switch firing control scheme that can be provided by dimmer circuit 100, which can be regarded as a negative half cycle zero crossing detection firing control scheme, dimmer circuit 100 can detect a first input line voltage during a positive half cycle and can detect a second input line voltage during a negative half cycle of an input line voltage and can use the detected first and second voltages for firing the switch 116 during the positive and negative half cycles, respectively, of an input line voltage of the AC power source 88.
Aspects of dimmer circuit 100 providing a zero crossing firing control scheme are set forth in connection with
In the development of methods and apparatus herein, it was determined that a zero crossing approach for dimming where dimming is based on an input AC power source voltage exceeding zero volts can yield error for certain types of loads. In practice, fluctuations in load current can result in a noisy electrical power phase. This occurs in many different types of electrical devices, with some electrical devices (such as loads including LED and CFL light sources with capacitive driver circuits) experiencing more frequent reversals in load current about a zero crossing than are experienced in other types of electrical devices, such as incandescent lamps. In general, the closer the voltage level of the phase is to 0V, the more noise that is experienced. As a result of this noise, multiple changes of polarity occur and are sensed when input line voltage 302 as depicted in
Thus, it can be seen that noise results in several detections of zero crossings when change in voltage polarity (0 V) is sensed for detecting zero crossings. The multiple transitions lead to undesirable ‘false triggering’ whereby one or more zero crossings occur and are detected despite the input line voltage 302 having not yet fully completed the transition from one half phase to another half phase. Resulting from this false triggering are potentially premature and undesired control actions by circuitry of the dimmer circuit 100 to control operation thereof. For instance, multiple zero crossings detections (and signaling thereof) cause a relatively rapid firing of the switch 116, e.g., the TRIAC 1116 (using the above example), and in some applications, such as LED dimming. False triggers can cause undesirable effects to the load, such as flickering, in the case where the load comprises one or more LED or one or more CFL light source.
In accordance with aspects set forth herein, AC power source input line voltage detection can be provided to improve the synchronization capabilities of the dimmer circuit 100, and to avoid false triggering that occurs in the above described approach. In accordance with aspects as set forth herein, rather than detect when the input line voltage crosses zero volts, dimmer circuit 100 can be operative to detect a zero crossing based on a threshold voltage being reached. Dimmer circuit 100 can be operative to detect that a zero crossing has occurred when dimmer circuit 100 detects when the absolute value of the voltage level of the AC power source 88 (the voltage across phase side Θ and neutral side N, as measured by detecting a voltage across an input line voltage terminal 90 and a load terminal 94) reaches a nonzero voltage threshold, such as a predefined nonzero voltage threshold value. By placing this trigger point above (or below) zero volts, false triggering due to the multiple voltage polarity reversals caused by the fluctuations in load current near zero is avoided. While current changes (from increasing to decreasing and vice versa) can occur away from the zero voltage level, these changes are small enough that they do not cause polarity reversals and can be ignored. The significant fluctuations of the load current near the zero voltage level diminish once the line voltage has had a chance to rise above the zero potential. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 5 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 10 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 20 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 30 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 40 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 50 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 60 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 70 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 80 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 90 V. In one embodiment, a nonzero threshold voltage used by detector circuit 112 to detect a zero crossing can be at least 100 V. The nonzero threshold voltage used for zero crossing detection can be a value appreciably above 0 V without negating the ability of dimmer circuit 100 to deliver a majority of power available from AC source 88 to load 108.
In
It has been observed that some electrical loads such as certain types of active light source loads (e.g., certain LED loads and certain CFL loads), are difficult to control even with use of a threshold based zero detection method designed to make dimmer circuit 100 less susceptible to fluctuations in zero crossing.
In
Referring to
In one aspect of a switch unlatch monitoring firing control scheme for dimmer circuit 100, dimmer circuit 100 can fire switch 116 based on a monitoring of voltage across input line voltage terminal 90 and load terminal 94, the switch voltage, VSWITCH. The unlatch monitoring can be performed with the switch 116 in an ON (latched) state after an initial firing of switch 116 during a current half cycle. In one aspect, dimmer circuit 100 can be configured to monitor for voltage changes as are indicated by feature 414 of the oscilloscope trace of
For the performance of monitoring of voltage across input line voltage terminal 90 and load terminal 94 for determining the latched/unlatched state of switch 116, detector circuit 112 in one embodiment can include appropriate circuitry for digitizing a voltage indicative of the voltage differential across input line voltage terminal 90 and load terminal 94 (the switch voltage, VSWITCH) and for inputting the digitized switch voltage, VSWITCH, into controller 126. For example, controller 126 can monitor the digitized voltage levels for detection of a voltage change with switch 116 in a latched state. ON detection of switch unlatching, controller 126 can transmit a control signal to switch 116 (e.g. a gating signal in the case switch 116 is provided by a TRIAC) to re-fire switch 116 so that the unlatched time within the current half cycle is minimized. Dimmer circuit 100 can be operative to re-fire switch 116 without delay responsively to an unlatching of switch 116 being detected. Detector circuit 112 can detect for changes in a voltage across input line voltage terminal 90 and load terminal 94 using alternative circuitry, as will be set forth herein.
The oscilloscope trace of
It has been observed that monitoring for unlatching of switch 116 can consume a non negligible amount of power and processing time of controller 126. To reduce power and processing budgets, dimmer circuit 100 can be operative so that when switch 116 is fired based on an unlatch monitoring switch firing control scheme, a timing parameter of the unlatch monitoring can be stored into a memory 1262 of dimmer circuit 100 and can be used for control of a firing of switch during a subsequent half cycle. In one embodiment, controller 126, e.g., where provided by a microprocessor IC chip can have an on board memory 1262 and timer 1264. Memory 1262 can store a record of timestamped events of an input line voltage cycle, e.g., zero crossing detections, switch unlatch detections, switch firings, and by virtue of nominal timing characteristics of a input line voltage being known, e.g., having a nominal cycling frequency of 60 Hz, timer 1264 may provide information of a current phase angle of an input line voltage.
Dimmer circuit 100 during a subsequent half cycle or series of half cycles of AC power source 88 can use the timing parameter which can be stored in memory 1262 as set forth herein for firing of the switch 116. Switch 116 can be fired by dimmer circuit 100 at a time within a current half cycle that corresponds to the time of an unlatch monitoring based firing of a prior half cycle in which a switch unlatch was detected by dimmer circuit 100. In one embodiment, the timing parameter can be the time from an initial firing of switch 116 during a half cycle at which dimmer circuit 100 fires switch 116 based on an unlatch monitoring. In one embodiment, an initial firing of switch during a half cycle is a firing responsive to a zero crossing detection (0V based or nonzero threshold voltage based). Accordingly, dimmer circuit 100 can be configured so that if dimmer circuit 100 during a first half cycle detects a voltage change feature 426 10 degrees from an initial switch firing time of that first half cycle, and fires switch 116 15 degrees from the initial half cycle firing time based on that unlatch detection, dimmer circuit 100 can fire switch 116 15 degrees from an initial switch firing time of a subsequent, e.g., a successive half cycle. In one embodiment, the timing parameter can be the time from an initial firing of switch 116 during a half cycle at which dimmer circuit 100 detects an unlatch event in performing an unlatch monitoring. In one embodiment, dimmer circuit 100 can be configured so that if dimmer circuit 100 during a first half cycle detects a voltage change feature 426 10 degrees from an initial switch firing time of that first half cycle, and fires switch 116 15 degrees from the initial half cycle firing time based on that unlatch detection, dimmer circuit 100 can subsequently fire switch 116 10 degrees or less than 10 degrees (a number of degrees that is based on the earlier detection time rather than the earlier firing time) from an initial switch firing time of a subsequent, e.g., a successive half cycle. In such embodiment, dimmer circuit 100 can be configured so that dimmer circuit 100 re-fires switch 116 at or prior to a time it becomes unlatched, effectively preempting an un-latching of switch 116 (and therefore also preempting a re-firing of switch 116).
It has been observed that a load characteristic undergoing a switch unlatch event can result in a “mirror image” switch unlatch event occurring between subsequent half cycles. Referring to the oscilloscope trace of
In accordance with the switch unlatch monitoring firing control scheme set forth herein, it will be seen that switch 116 can be fired a variable number of times within a current half cycle of an input line voltage, wherein the number of times that switch 116 is fired during a current half cycle that depends on characteristics of load 108. For example, as depicted in
As shown in
It has been described that the switch voltage, VSWITCH, can be representative of an input line voltage, the voltage between phase side Θ and neutral side N of AC power source 88 (
It has been observed that when a voltage of AC power source 88 is at an amplitude approaching a zero crossing and indicating that a current half cycle is nearly complete, particularly when dimmer circuit 100 is used with active loads, there is a risk of unlatching of switch 116 or other unpredictable control of load 108.
In accordance with another switch firing control scheme that can be provided by dimmer circuit 100 which can be regarded as a forth quadrant firing control scheme, dimmer circuit 100 can be operative so that dimmer circuit 100 fires switch 116 proximate in time but prior to an input line voltage of AC power source 88 reaching a zero crossing. Referring to
In another example, a firing time of switch 116 for a half cycle fourth quadrant firing can be based on detected switch voltage, VSWITCH, and further based on known characteristics of an input line voltage. For example, the firing time can be determined based on a detected zero crossing of an input line voltage and further based on a known characteristics of a nominally operating AC power source, e.g., the known nominal frequency of nominal AC power source 88 to which dimmer circuit 100 can be connected. A known characteristic of AC power source 88 can include the characteristic that a half cycle time of such voltage source will be approximately 1/120 second in the case of a 60 Hz AC power source. In one example, a firing time of a fourth quadrant firing of switch 116 can be determined based on a detected zero crossing (e.g., 0V based or threshold voltage based) indicative of a beginning of a current half cycle and based on the known time delay to a predetermined time before the end of the current half cycle using the known characteristic of power source 88 that a half cycle time of such voltage source will be approximately 1/120 second in the case of a 60 Hz AC power source. A firing time can be determined as a predetermined time (phase angle) before the end of a current half cycle. Referring to the example illustrated with timeline 422 of the oscilloscope trace of
In one aspect, in order to prevent an unlatching of switch 116 after it is latched initially during a half cycle of an input line voltage, dimmer circuit 100 can be made to fire switch 116 continuously for a remainder of a half cycle after an initial half cycle firing. While such switch control can be advantageous in some embodiments, the noted continuous fire switch control has been observed to be disadvantageous in various aspects. It has been observed that continuous firing of switch 116 can have negative effects. In one aspect, continuous firing of switch 116 can consume significant power. In another aspect, continuous firing of switch 116 can heat up switch 116 causing thermal stresses that can limit the expected lifetime of switch 116.
Referring to a zero crossing detection set forth herein, dimmer circuit 100 can perform a zero crossing detection and based on the zero crossing detection after a delay can fire switch 116 for an initial firing of a switch during a half cycle. The delay can be based on an input of an operator. If an operator using user interface 128 increases brightness, the delay can be reduced so that the firing is closer to the detected zero crossing. If an operator using user interface 128 decreases brightness, the delay can be increased so that the initial firing is a longer period from the zero crossing. The zero crossing can be, e.g., 0V based or threshold voltage based as set forth herein. In one embodiment, dimmer circuit 100 can detect a zero crossing (e.g., using a 0V based or threshold voltage based method) once per cycle during the positive voltage half cycle of each voltage cycle of power source 88 and can cause an initial firing of switch 116 at an initial firing time during each positive half cycle based on the detected zero crossing and based on the operator's selected brightness level. Dimmer circuit 100 could then cause initial firing of switch 116 during each negative voltage half cycle of power source 88 by interpolation using the initial firing time of each preceding positive half cycle and known characteristics of a nominally operating AC power source. In a nominally operating voltage source such as AC power source 88 half cycles are separated in time by time periods of 1/120 sec. in the case of a nominal 60 Hz AC power source. Accordingly, dimmer circuit 100 in one embodiment can be configured to activate an initial firing of switch 116 during a negative voltage half cycle that is based on the initial firing time of the immediately previous positive half cycle and subsequent in time from the initial firing of switch 116 during the previous (positive voltage) half cycle by the time period of 1/120 sec. (the nominal known time period of an input line voltage half cycle).
It has been observed that due to the unpredictable operation of certain loads, such as active loads, implementation of a switch firing control wherein an initial firing of switch 116 during a negative half cycle is based on interpolation can produce unwanted results. Particularly with active loads, there is an increased risk of a detected zero crossing being unrepresentative of a zero crossing of an input line voltage source. It has been determined that use of interpolation to establish a timing of a switch firing during a negative half cycle of an input line voltage can result in a switch firing error being repeated between successive half cycles.
Therefore, in accordance with another aspect of a dimmer circuit 100, dimmer circuit 100 can be operative to detect a zero crossing during both negative voltage half cycles and positive voltage half cycles of an input line voltage provided by AC power source 88. The zero crossing detection during each half cycle can be, e.g., 0 V based or nonzero threshold voltage based as set forth herein. In one embodiment, there is set forth herein a switch 116 for controlling delivery of power of an AC power source 88 to a load 108, the switch 116 coupling an input line voltage terminal 90 and a load terminal 94. The dimmer circuit 100 within a non conducting phase of the dimmer circuit 100 occurring during a positive half cycle of the AC power source 88 can detect a first voltage across the input line voltage terminal 90 and the load terminal 94. The dimmer circuit 100 within a non conducting phase of the dimmer circuit 100 occurring during a negative half cycle of the AC power source 88 can detect a second voltage across the input line voltage terminal 90 and the load terminal 94. During the positive half cycle of the AC power source 88, the dimmer circuit 100 can be operative to fire the switch at a time based on the detecting a first voltage (and based on a selected brightness level selected by an operator), and during the negative half cycle of the AC power source 88 the dimmer circuit 100 can be operative to fire the switch 116 at a time based on the detecting a second voltage (and based on a selected brightness level selected by an operator).
In one embodiment, detector circuit 112 can include analog circuit hardware for performing zero crossing detection. An example of a circuit 1122 for detecting a zero crossing of an input line voltage is depicted in
In another aspect, diodes D1 and D2 can be provided as shown in
Referring to
In one embodiment, circuit 1122 and circuit 1124 can be co-located so that a functionality of circuit 1124 is provided by circuit 1122. In one embodiment, circuit 1122 and circuit 1124 can include on board circuitry of a microprocessor integrated circuit chip which includes controller 126. In one embodiment, circuit 1122 and circuit 1124 can include on board common circuitry of a microprocessor integrated circuit chip which includes controller 126. In one embodiment, a microprocessor integrated circuit which includes controller 126 can be configured so that values of resistors R3, and R4 are programmable in such manner as to be changeable within a time of a current half cycle. Accordingly, circuit elements of a common comparator configured in accordance with circuit 1122 and circuit 1224 can be repurposed and used for determining each of (a) a zero crossing detection (0V based or nonzero threshold based) and (b) one or more unlatch events pursuant to an unlatch monitoring during a current half cycle.
In one embodiment, it can be undesirable for circuit 1124 to trigger latching of switch 116 when circuit 1122 is operating to detect a zero crossing. It can also be undesirable for circuit 1122 to trigger latching of switch 116 when circuit 1124 is operating to detect an unlatching of switch 116. In one embodiment, dimmer circuit 100 can be configured so that circuit 1124 is restricted from triggering latching of switch 116 when circuit 1122 is operating to detect a zero crossing of an input line voltage. In one embodiment, dimmer circuit 100 can be configured so that circuit 1122 is restricted from triggering a latching of switch 116 after an initial firing of switch 116 during a current half cycle.
Dimmer circuit 100, in accordance with features set forth herein, can include a memory 1262 for storing data providing a record of latching events of switch 116 during a current half cycle and can also include a timer 1264, an output of which, based on known characteristics of a nominally operating AC power source 88 indicates a current phase angle. In one embodiment, dimmer circuit 100 can be configured so that dimmer circuit 100, using data stored in memory 1262 providing a record of prior latching events of switch 116 and using an output timer 1264 that indicates a current phase angle, is restricted from being responsive to a zero crossing (0V based or nonzero threshold voltage based) detection by circuit 1122 for triggering a switch 116 unless switch 116 has not been previously fired during a current half cycle. In one embodiment, dimmer circuit 100 can be configured so that dimmer circuit 100 using data stored in memory 1262 providing a record of prior latching events of switch 116 during a current half cycle and an output timer 1264 that indicates a current phase angle, is restricted from being responsive to monitoring of a switch voltage, VSWITCH, for triggering switch 116 based on unlatching of switch 116 as detected by circuit 1124 unless switch 116 has been initially fired during a current half cycle.
Referring to
Resistors R5 and R6 can be sized so that a comparator C2 outputs a logic “1” when a input line voltage falls below 0V or a nonzero threshold negative voltage selected to be indicative of a negative half cycle zero crossing. In one aspect, signal conditioning circuitry of circuit 1122 of
In one embodiment, a nonzero threshold voltage used by comparator C1 of circuit 1122 as shown in
In one embodiment, a nonzero threshold voltage used by comparator C2 of detector 1122 as shown in
In one embodiment, circuit 1122 as shown in
By employing one or more of the switch firing control schemes set forth herein, predictable control over a wide range of lighting loads can be provided with economized switch firings that result in reduced power consumption and reduced device degradation.
A switch firing control scheme as set forth herein can be provided alone or in combination with one or more other switch firing control scheme set forth herein. In one embodiment, an initial firing of switch 116 during a voltage half cycle of an AC power source (which can be performed based on a zero crossing detection which can be, e.g., 0V based or threshold based) can be performed alone or in combination with one or more additional switch firing control scheme as set forth herein, e.g., one or more of the unlatch monitoring firing control scheme, the fourth quadrant firing control scheme, or the negative half cycle zero crossing detection firing control scheme as set forth herein.
The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprise” (and any form of comprise, such as “comprises” and “comprising”), “have” (and any form of have, such as “has” and “having”), “include” (and any form of include, such as “includes” and “including”), and “contain” (and any form contain, such as “contains” and “containing”) are open ended linking verbs. As a result, a method or device that “comprises”, “has”, “includes” or “contains” one or more steps or elements possesses those one or more steps or elements, but is not limited to possessing only those one or more steps or elements. Likewise, a step of a method or an element of a device that “comprises”, “has”, “includes” or “contains” one or more features possesses those one or more features, but is not limited to possessing only those one or more features. Similarly, the term “based on” herein means “based on at least” unless the context indicates otherwise and the term “responsive to” means “responsive to at least” unless the context indicates otherwise. Furthermore, a device or structure that is configured in a certain way is configured in at least that way, but may also be configured in ways that are not listed. In addition, a device or structure described as having a certain number of elements can be practiced with less than or more than the certain number of elements.
The description of the present invention has been presented for purposes of illustration and description, but is not intended to be exhaustive or limited to the invention in the form disclosed. Many modifications and variations will be apparent to those of ordinary skill in the art without departing from the scope and spirit of the invention. The embodiment was chosen and described in order to best explain the principles of the invention and the practical application, and to enable others of ordinary skill in the art to understand the invention for various embodiment with various modifications as are suited to the particular use contemplated.
This patent application is a continuation of U.S. patent application Ser. No. 14/302,255, filed Jun. 11, 2014, and entitled “Power Efficient Line Synchronized Dimmer,” which issued on ______, as U.S. Pat. No. ______, the entire subject matter of this application being incorporated herein by reference.
Number | Date | Country | |
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Parent | 14302255 | Jun 2014 | US |
Child | 15457503 | US |