Abstract:
An electronic device includes an indicator that generates an indication of an event responsive to an indicator control signal from an indicator control circuit coupled between a processor and the indicator. The processor generates an indicator off-time value and an indicator on-time value when an indication is desired, and the indicator control circuit receives the indicator off-time value and the indictor on-time value from the processor. More particularly, the indicator control circuit includes an off-time register, an on-time register, and an indicator control circuit. The off-time register stores the off-time value generated by the processor, and the on-time register stores the on-time value generated by the processor. The indicator control signal generator alternatingly enables the indicator control signal for a period of time determined by the on-time value stored in the on-time register and disables the indicator control signal for a period of time determined by the off-time value stored in the off-time register. The electronic device can also include an indicator pulse-duty register and a pulse width modulation circuit. The indicator pulse-duty register can be coupled to the processor and store an indicator pulse-duty generated by the processor. The pulse width modulation circuit can be coupled to the indicator pulse-duty register wherein the pulse width modulation circuit modulates a pulse width of the enabled indicator control signal in response to the indicator pulse-duty stored in the indicator pulse-duty register.

Description:
FIELD OF THE INVENTION 
     The present invention relates to indicators for electronic devices and more particularly to control circuits for indicators. 
     BACKGROUND OF THE INVENTION 
     Many electronic devices such as radiotelephones and pagers include indicators to alert a user that something has happened or that some action is required. For example, an audible ringer can be used to indicate that a telephone call is being received or that a page has been received. Alternately, a vibrator can be used to provide silent indication. 
     Known controllers for devices including these indicators, however, may be software intensive. In particular, software operations may be needed to turn the indicator on, and to turn the indicator off. This may be particularly burdensome if the indicator is turned on and off repeatedly for a single indication. This is common, for example, with radiotelephone ringers that are repeatedly turned on and off until either the user answers the call or the calling party hangs up. In such a situation, individual software processing operations may be needed to turn the ringer on and off for each individual ring and to time the intervals that the ringer is turned on and off. 
     These software processing operations used to control the ringer may reduce time available for other processing operations thereby reducing the performance and/or increasing the complexity of the software as well as the processor running the software. Accordingly, there continues to exist a need in the art for improved circuits and methods to control indicators for electronic devices. 
     SUMMARY OF THE INVENTION 
     It is therefore an object of the present invention to provide improved circuits for controlling electronic indicators and related methods. 
     This and other objects are provided according to the present invention by storing an off-time value in an off-time register, and storing an on-time value in an on-time register. An indicator control signal is alternatingly enabled for a period of time determined by the on-time value stored in the on-time register and disabled for a period of time determined by the off-time value stored in the off-time register. Accordingly, a processor can load the on- and off-time values in the respective registers and then proceed with other operations so that processor overhead is reduced. 
     In particular, an electronic device can include an indicator that generates an indication of an event responsive to an indicator control signal, and a processor that generates an indicator off-time value and an indicator on-time value when an indication is desired. The electronic device can also include an indicator control circuit coupled between the processor and the indicator wherein the indicator control circuit receives the indicator off-time value and the indicator on-time value from the processor. More particularly, this indicator control circuit includes on- and off-time registers and an indicator control signal generator. The off-time register stores the off-time value generated by the processor, and the on-time register stores the on-time generated by the processor. The indicator control signal generator alternatingly enables the indicator control signal for a period of time determined by the on-time value stored in the on-time register and disables the indicator control signal for a period of time determined by the off-time value stored in the off-time register. Control of the indicator is thus handled by the indicator control circuit thereby reducing processor operations. 
     In addition, the indicator control signal can be disabled when the on-time value stored in the on-time register is zero. Accordingly, the indicator control circuit does not perform operations regardless of the off-time value stored in the off-time register. Moreover, the indicator can be turned off by storing an on-time value of zero in the on-time register. 
     More particularly, the indicator control signal generator can include a timer, a multiplexer, a comparator, and a latching circuit. The timer generates an incrementing elapsed time, and the multiplexer selects one of the on-time value from the on-time register and the off-time value from the off-time register. The comparator compares the incrementing elapsed time with the selected one of the on-time value and the off-time value and the comparator generates a signal when the elapsed time reaches the selected one of the on-time and the off-time values. The latching circuit switches a state of the indicator control signal and resets the timer responsive to the signal that the elapsed time has reached the selected one of the on-time and the off-time values, and the multiplexer selects the other of the on-time value and the off-time value responsive to the signal. Accordingly, the indicator control circuit can be implemented with hardware elements not requiring processor input other than the loading of the register values. 
     Furthermore, the timer can include a counter coupled to a clock, and the clock can be disabled when either the on-time value stored in the on-time register is zero, or the off-time value stored in the off-time register is zero. When the on-time value is zero, the indicator is turned off so that there is no need to operate the counter. When the off-time value is zero (and the on-time value is non-zero) the indicator is turned on continuously so that there is no need to count the on- and off-time values. In either case, battery drain and/or power consumption can be reduced by disabling the clock when it is not needed. 
     The processor can also generate an indicator pulse-duty value wherein the indicator control circuit receives this indicator pulse-duty value, and the indicator control circuit can include an indicator pulse-duty register and a pulse width modulation circuit. The indicator pulse-duty register stores the indicator pulse-duty value generated by the processor, and the pulse width modulation circuit modulates a pulse width of the enabled indicator control signal in response to the indicator pulse-duty value stored in the indicator pulse-duty register. The intensity of the enabled indicator control signal can thus be varied responsive to the indicator pulse-duty value thereby varying the intensity of the indication. The modulation circuit can thus be used to reduce or increase power consumed by the indicator thereby reducing or increasing battery drain according to battery charge and/or output desired. For example, the brightness, volume, or intensity of the indication can be controlled as a function of output desired and/or battery charge. 
     More particularly, the pulse width modulation circuit can include a timer and a comparator. The timer generates an incrementing elapsed time up to a predetermined value and then starts over, the comparator compares the elapsed time and the indicator pulse-duty value, and the pulse width modulation circuit modulates the pulse width of the enabled indicator control signal responsive to the comparison. In addition, the timer can include a counter coupled to a clock, and the clock can be disabled when the indicator control signal is disabled thereby reducing power consumption and/or battery drain when the clock is not needed. 
     In addition, the electronic device can include a transceiver coupled to the processor wherein the transceiver transmits and receives radio communications under control of the processor, and the indicator can be a buzzer, a ringer, a light, a vibrator, or an annunciator. 
     The devices and methods of the present invention can thus be used to control an indicator with reduced interaction from a device processor. In particular, the processor need only load registers with values defining the operating parameters for the indicator, and the indicator control circuit of the present invention generates the actual control signals for the indicator. In particular, on-time and off-time values can be stored in respective registers. Processor overhead can thus be reduced. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 is a block diagram of a radiotelephone including an indicator control circuit according to the present invention. 
     FIG. 2 is a schematic diagram of the indicator control circuit of FIG.  1 . 
     FIG. 3 is a timing diagram illustrating a modulated indicator control signal generated by the indicator control circuit of FIG.  2 . 
    
    
     DETAILED DESCRIPTION 
     The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein; rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout. 
     A block diagram of a radiotelephone including an indicator control circuit according to the present invention is illustrated in FIG.  1 . As shown, the radiotelephone  20  includes a transceiver  22 , controller  24 , and a user interface  26 . More particularly, the controller  24  includes a processor  28  and an indicator control circuit  30 ; and the user interface  26  includes a keypad  32 , a display  34 , a microphone  36 , a speaker  38 , and an indicator  40 . 
     Accordingly, the radiotelephone  20  can be used to transmit and receive radiotelephone communications using the transceiver  22  under the control of the processor  28  as will be understood by those having skill in the art. More particularly, a user&#39;s speech can be received by the microphone  36  of the user interface  26  and transmitted to a radiotelephone communications system using the transceiver  22  under the control of the processor  28 . In the other direction, speech from a distant party can be received by the transceiver  22  under the control of the processor  28  and reproduced by the speaker  38  of the user interface  26 . The processor  28  can accept user input from the keypad  32  of the user interface  26 , and information can be provided to the user through the display  34  of the user interface responsive to the controller  24 . 
     According to the present invention, the indicator  40  of the user interface  26  operates under the control of the indicator control circuit  30  of the controller  24  thereby reducing the overhead within the processor  28  that may otherwise be needed to support the operation of the indicator  40 . In particular, the indicator  40  is used to provide an indication of some event such as an incoming call, an incoming page, etc., and the indicator can be a buzzer, a ringer, a light such as a light emitting diode, a vibrator, an annunciator, or other indicator known to those having skill in the art. Furthermore, an audible indicator can be implemented, at least in part, using the speaker  38 , or a visible indicator can be implemented, at least in part, using the display  34 . 
     As an example, the indicator  40  can be a ringer used to indicate that there is an incoming call. In response to an incoming call, the indicator can be alternatingly turned on and off for one second intervals until either the radiotelephone  20  user answers the call, or the calling party hangs up. By controlling the indicator  40  using the indicator control circuit  30  of the present invention, the software overhead and/or complexity of the processor  28  can be reduced. In particular, the processor  28  need only provide on-time and off-time values to the indicator control circuit  30  in response to an incoming call. The actual activation and deactivation of the indicator  40  can be controlled by the indicator control circuit  30 . In other words, the processor  28  is not required to perform any step at the beginning and end of each individual ring. The indicator control circuit  30  of the present invention can also provide pulse width modulation responsive to a pulse-duty value provided by the processor  28 . 
     A schematic diagram of an indicator control circuit according to the present invention is provided in FIG.  2 . As shown, the on-time value is saved in the on-time register  50 , the off-time value is saved in the off-time register  52 , and the pulse-duty value is saved in the pulse-duty register  54 , and these stored values are used to generate the indicator control signal provided to the indicator  40 . Accordingly, the processor  40  need only provide the on-time, off-time, and pulse-duty values to the respective registers in the indicator control circuit  30 , to initiate or change operation of the indicator. The indicator control circuit will then proceed to operate the indicator according to the stored values until new values are stored. For example, an on-time value of zero can be stored in the on-time register  50  to terminate operations of the indicator  40 . 
     The indicator control circuit  30  also includes up-counter  100 , multiplexer  104 , comparator  106 , flip-flop  108 , multiplexer  110 , clock  112 , and logic circuit  114 , which together enable and disable an indicator control signal on control line Ctrl used to control the indicator  40 . The indicator control signal on the control line Ctrl can be inverted using inverter  116 . Moreover, the intensity of an enabled indicator control signal can be varied using pulse width modulation techniques implemented responsive to a pulse-duty value stored in the pulse-duty register  54  using up-counter  120 , clock  122 , comparator  124 , and OR gate  126 . In addition, the exclusive OR (XOR) gate  130  and the single bit value stored in the output sense register  132  can be used to control the output state, and the driver  134  can be used to provide sufficient current to drive the indicator  40 . 
     As shown, the logic circuit  114  generates the indicator control signal on the control line Ctrl responsive to the on-time and off-time values and responsive to the Q-output of flip-flop  108 . In particular, if all bits of the on-time value stored in the on-time register  50  are zero, NOR gate  202  will generate a “one” output, OR gate  204  will generate a “one” output, OR gate  206  will generate a “one” output, and NAND gate  208  will generate a “zero” output on the control line Ctrl (a disabled indicator control signal). In addition, inverter  210  will generate a “zero” output, and AND gate  212  will generate a “zero” output thereby disabling the clock  112 . Accordingly, a zero on-time value will result in a disabled input control signal, and by disabling the clock  112 , power consumption and/or battery drain can be reduced during periods when the indicator is not activated. The clock  112  will also be disabled when all bits of the off-time value stored in the off-time register are “zero”. In this situation, the OR gate  214  will generate a “zero” output, and the AND gate  212  will generate a “zero” output thereby disabling the clock  112 . 
     When the on-time and off-time values are both non-zero, the NOR gate  202  will generate a “zero” output, and the OR gate  214  will generate a “one” output. The OR gate  206  will thus generate a “one” output, and the output of the OR gate  204  will be dependent on the Q-output of the flip-flop  108 . The output of the NAND gate  208  in turn will thus also be dependent on the Q-output of the flip-flop  108 . Accordingly, when the Q-output is “one” with non-zero on-time and off-time values, the NAND gate  208  will generate a “zero” output (a disabled indicator control signal). When the Q-output is non-zero on-time and off-time values, the NAND gate  208  will generate a “one” output (an enabled indicator control signal). 
     With non-zero on-time and off-time values, the Q-output of the flip-flop  108  will alternate between “one” and “zero” so that the indicator control signal is alternatingly enabled and disabled for periods of time determined by the on-time and off-time values. For example, the flip-flop  108  can be designed so that the Q-output generates a “zero” output when initially powered on. This initial value will be maintained until the D-input is changed responsive to the multiplexer  110  and the comparator  106 . lf the initial value of the Q-output of flip-flop  108  is “zero”, the initial value of the QB-output (the inverse of the Q-output) will be “one”. 
     As shown in FIG. 2, the QB-output of flip-flop  108  is provided to the S 2 -input of multiplexer  110  and to the C-input of multiplexer  104 . Accordingly, the QB-output of flip-flop  108  controls the selection by multiplexer  104  of either the off-time value stored in off-time register  52  or the on-time value stored in on-time register  50 . In particular, a QB-output of “one” can result in the selection of the on-time value, a QB-output of “zero” can result in the selection of the off-time value, and the selected value is provided to the B-input of the comparator  106 . If the QB-output of flip-flop  108  is initially set to “one”, the multiplexer can select the on-time value stored in the on-time register  52  and provide this value to the B-input of the comparator  106 . 
     The up-counter  100  generates an incrementing elapsed time responsive to the clock  112 , and this incrementing elapsed time is provided to the A-input of the comparator  106 . In the example of FIG. 2, the incrementing elapsed time increases until the incrementing elapsed time reaches the on-time value at which point the output of the comparator  106  goes from “zero” to “one”. In the context of this disclosure, the term reaches can mean that the incrementing elapsed time is equal to or exceeds the B-input of the comparator  106  when an up-counter is used. In addition, incrementing elapsed time is defined to include either an increasing or decreasing incrementing elapsed time so that either an up-counter or a down-counter can be used. In the context of a down-counter, reaches can mean that the incrementing elapsed time is equal to or less than the B-input of the comparator  106 . 
     When the incrementing elapsed time generated by the up-counter reaches the on-time value, the comparator output transitions from “zero” to “one” for one clock cycle. This “one” output is applied to the reset input for the up-counter  108  so that the incrementing elapsed time is reset to zero. Once the incrementing elapsed time is reset to zero, the output of the comparator  106  will return to “zero” so that the comparator  106  output is only “one” for a single clock cycle. This “one” output from the comparator  106  is also applied to the C-input of multiplexer  110  for one clock cycle. Accordingly, the multiplexer  110  selects the QB-output from the flip-flop  108  for one clock cycle, and the QB-output value is fed back by multiplexer  110  to the D-input of the flip-flop  108  thereby switching the Q-output to “one” and switching the QB-output to “zero”. When the comparator  106  output returns to “zero”, the multiplexer  110  reselects the Q-output of the flip-flop  108  so that the Q-output is latched to “one” and the QB-output is latched to “zero”. With the QB-output of flip-flop  108  latched to “zero” the multiplexer  104  selects the off-time stored in the off-time register  52 . 
     With the off-time value selected by the multiplexer  104  and applied to the B-input of the comparator  106 , the incrementing elapsed time is compared to the off-time value. When the incrementing elapsed time generated by the up-counter  100  reaches the off-time value, the comparator  106  output goes from “zero” to “one” for one clock cycle resetting the up-counter  100  and reversing the flip-flop  108  outputs so that the Q-output is “zero” and the QB-output is “one”. The on-time value stored in the on-time register is thus reselected by the multiplexer  104  and applied to the B-input of the comparator  106 , and the cycle is repeated. 
     Accordingly, when the on-time and off-time values are both non-zero, the output of NAND gate  208  (on control line Ctrl) switches back and forth between “one” (enabled indicator control signal) for a period of time determined by the on-time value stored in the on-time register  50  and “zero” (disabled indicator control signal) for a period of time determined by the off-time value stored in the off-time register  52 . This operation continues until new values are stored in the on-time and/or off-time registers. For example, zero can be stored in the on-time register  50  so that the output of NAND gate  208  generates a “zero” on the control line Ctrl (disabled indicator control signal). As discussed above, when the on-time value is zero, the clock  112  is disabled to save power. 
     When the on-time value is non-zero but the off-time value is zero, the NAND gate  208  output is “one” and does not switch. Accordingly, the indicator control signal is continuously enabled until either a non-zero value is stored in the off-time register  52 , or zero is stored in the on-time register  50 . In addition, the clock  112  is disabled when the off-time value is zero to reduce power consumption. 
     In a particular example of the indicator control circuit of FIG. 2, the clock  112  can be an 8 Hz clock, the on-time and off-time registers  50  and  52  can be five bit registers, and the up-counter  100  can be a five bit counter. Accordingly, the on-time and the off-time can be varied over a range of 0.125 seconds to 3.875 seconds in 0.125 second intervals. These intervals and ranges can be adapted to different applications by changing the frequency of the clock  112  and by changing the sizes of the registers  50  and  52  and the counter  100 . 
     The indicator control signal generated on the control line Ctrl can be used to drive the indicator through inverter  116 , driver  134 , and/or other circuitry used to provide desired signal levels. As will be understood, the driver  134  can be defined as a portion of the indicator control circuit  30 , as a portion of the user interface  26 , or as a portion of indicator  40 . In addition, the enabled indicator control signal can be pulse width modulated using the clock  122 , the up-counter  120 , the pulse-duty register  54 , the comparator  124 , and the OR gate  126 . 
     In particular, the up-counter  120  generates an incrementing elapsed time in response to the clock  122 . The up-counter counts from an initial value up to a predetermined number and starts over at the initial value, and the comparator  124  compares the incrementing elapsed time generated by up-counter  120  with the pulse-duty value stored in the pulse-duty register  54 . In this example, the comparator  124  output generates a “zero” as long as the incrementing elapsed time is less than or equal to the pulse-duty value, and the comparator  124  generates a “one” when the incrementing elapsed time is greater than the pulse-duty value. The comparator  124  output is combined with the inverted indicator control signal using the OR gate  126 . In summary, an enabled indicator control signal will generate a “zero” at the output of the inverter  116  so that an active low pulse width modulated wave form is generated responsive to the comparator  124  output. A disabled indicator control signal will generate a “one” at the output of the inverter  116  so that the indicator is disabled. 
     An enabled indicator control signal with a “one” on the control line Ctrl thus results in a “zero” out of inverter  116  that is combined with the output of the comparator  124 . Moreover the output of the comparator  124  switches between “one” and “zero” at a frequency determined by the counter  120  and the clock  122 , and the proportion of a cycle at “zero” is directly proportional to the magnitude of the pulse-duty value. At one extreme where the pulse duty value is one, the comparator  124  output will have a 12.5% duty cycle so that the indicator duty cycle is effectively 12.5%. At the other extreme where the pulse duty value is equal to the highest value (in this case zero signifying eight) of the incrementing elapsed time, the comparator  124  output will always be “zero” so that the indicator duty cycle is effectively 100%. When the pulse-duty value is equal to one half of the highest value of the incrementing elapsed time, the comparator  124  output will be “zero” for half of each cycle and “one” for half of each cycle so that the indicator duty cycle is effectively 50%. 
     In a particular example of the indicator control circuit of FIG. 2, the clock  122  can be a 512 Hz clock, the pulse-duty register  54  can be a three bit register, and the up-counter  120  can be a 3-stage binary up-counter. This structure provides an active low 64 Hz pulse width modulated waveform. Accordingly, the intensity of the output drive can be controlled in a range from 100% (maximum intensity) down to 12.5% (minimum intensity) in steps of 12.5%. These intervals and ranges can be adapted to different applications by changing the frequency of the clock  122  and by changing the sizes of the register  54  and the size of the counter  120 . In addition, to controlling the intensity of the indicator, the pulse-duty control can be used to reduce battery drain and/or power consumption by reducing the average current drawn by the indicator. 
     Moreover, when the indicator is a light emitting diode (LED), a 64 Hz modulation is sufficient to make flicker imperceptible. Other indicator devices, such as vibrators, may have sufficiently slow responses that they act as low pass filters to integrate the pulses. In addition, incrementing elapsed time is defined to include an increasing or decreasing incrementing elapsed time so that either an up-counter or a down-counter can be used. 
     The exclusive OR (XOR) gate  130  can be used to provide output sense control responsive to a single bit output-sense value stored in the output-sense register  132 . In other words, the XOR gate  130  can be used to convert the active low signal from the OR gate  126  to an active high signal. The driver  134  can be used to convert the logic signals generated by XOR gate  130  to drive signals with adequate current to drive the indicator. 
     In addition, the indicator control signal on control line Ctrl can be provided to the clock  122  so that the clock  112  is disabled when the indicator control signal is disabled (“zero” on the control line Ctrl). By disabling the clock  122  when the indicator is disabled, power consumption and battery drain can be reduced. 
     FIG. 3 graphically illustrates an example of a pulse width modulated indicator control signal at the output of the XOR gate  130  of FIG.  2 . In particular, the signal of FIG. 3 is an active low signal with a 50% duty factor. During the “OFF time”, the signal is maintained at a high level for a period of time determined by the off-time value stored in the off-time register  52 . During the “ON-time”, the signal is pulse width modulated a frequency determined by the clock  112  and the counter  120  with a duty cycle determined by the pulse-duty value stored in the pulse-duty register  54  for a period of time determined by the on-time value stored in the on-time register  50 . As shown in FIG. 3, the duty cycle can be approximately 50%. The active low signal is provided by storing an output-sense value of “zero” in the output-sense register  132 . Alternately, an active high signal can be provided by storing an output-sense value of “one” in the output-sense register  132 . 
     The controller  24  of the present invention including the processor  28  and the indicator control circuit  30  can be implemented as one or more standard and/or custom integrated circuit devices and/or discrete devices. For example, the processor and the indicator control circuit can be implemented as an application specific integrated circuit device. Alternately, the processor and the indicator control circuit can be implemented as separate devices. 
     According to the circuits and methods of the present invention, an indicator can be alternatingly enabled and disabled for predetermined periods of time based on values stored in on-time and off-time registers. Accordingly, processing overhead can be reduced because the on- and off-time values can be stored by the processor in the registers so that the processor is not required to initiate repeated on and off instructions and/or calculations. Instead, the indicator control circuit of the present invention handles the control of the indicator responsive to the stored on- and off-time values. The indicator control circuit of the present invention can also provide pulse width modulation based on a pulse-duty value stored in a pulse duty register. 
     In the drawings and specification, there have been disclosed typical preferred embodiments of the invention and, although specific terms are employed, they are used in a generic and descriptive sense only and not for purposes of limitation, the scope of the invention being set forth in the following claims. While the present invention has been discussed above with reference to radiotelephones, the methods and circuits of the present invention can be used in other electronic devices. For example, the methods and systems of the present invention can also be used in pagers.