Abstract:
Disclosed is a circuit, comprising a device having a minimum operating voltage, a voltage supply, wherein the voltage supply may have a value above or below or equal to the minimum operating voltage of the device, a voltage boost converter circuit having a boosted voltage output, a switch coupled between the voltage supply, the boosted voltage output and the device, wherein the switch is capable of passing one of the voltage supply or the boosted voltage output to the device, and a processing element capable of controlling the switch. A system comprising the circuit and a method of using the circuit are further described.

Description:
TECHNICAL FIELD 
   The present invention relates generally to electronic circuits and in particular to circuits for wireless communication powered by battery. 
   BACKGROUND 
   One of the leading challenges facing designers of wireless products is achieving acceptable battery life without requiring large batteries that would impact the weight and form factor of the product. An important step in increasing battery life of wireless devices is to reduce the power consumed by integrated circuits (ICs) inside the device. 
   Integrated circuits are typically specified with a guaranteed operating voltage range. The manufacturer guarantees operation above a minimum voltage termed Vcc(min), and below a maximum operating voltage termed Vcc(max). A somewhat higher “Absolute Maximum” supply voltage is also specified above which damage to the IC may occur. Operation from a supply greater than Vcc(max) but lower than the absolute maximum is not guaranteed, but no damage will result to the IC. 
   In practice, most ICs will operate correctly somewhat below Vcc(min). In order to guarantee operation at a specified Vcc(min), IC manufacturers typically test operation both slightly above the maximum rated temperature, and slightly below the minimum rated temperature at a voltage somewhat below Vcc(min). The voltage at which an IC will cease to operate correctly will generally therefore be below the Vcc(min), and in many cases well below Vcc(min) if the device is operated at room temperature. 
   In one example, an IC may be rated with a Vcc(min) of 2.7V and Vcc(max) of 3.6V, with an operating temperature range of 0 to 70 degrees Celsius. The IC manufacturer may test every device at 2.6V at both minus 10 and plus 80 degrees Celsius. In this example, a typical instance of the IC may work correctly in all respects down to 2.5V, and with degraded performance down to 2.3V, provided that the temperature of operation is constrained to a smaller range than that specified, for example plus 10 to minus 40 degrees. In some cases, it may be easy to determine whether or not an IC being supplied with a lower voltage than specified is performing correctly; in other cases, it may not. 
   Many ICs are used in battery powered applications where the output voltage range of the batteries does not match the operating voltage range of the IC. In such cases, there may be a number of different ICs, with different operating voltage ranges. In this case, it is common to use a direct current to direct current (DC-DC) boost converter to supply an approximately constant voltage to all ICs, ensuring correct operation of the ICs regardless of the output voltage of the batteries. A disadvantage of this approach is that for part of the life of the batteries the output may be being boosted unnecessarily, causing the batteries to be drained more quickly than necessary. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  shows output characteristics of a alkaline AA battery cell. 
       FIG. 2  shows an architecture for a wireless device having increased battery life. 
       FIG. 3  shows a method for increasing battery life of a wireless device. 
       FIG. 4  shows operation of the wireless device having increased battery life. 
       FIG. 5  shows a method of supplying a voltage to a first radio circuit. 
       FIG. 6  is a system with a wireless device having increased battery life. 
   

   DETAILED DESCRIPTION 
   In a wireless optical mouse the main ICs used are a microcontroller (MCU), an optical sensor, and a radio IC. In this example, the mouse is powered from two AA alkaline cells, and the output voltage characteristic of one such cell is shown in  FIG. 1 .  FIG. 1  comprises a graph  100 , having a y-axis  110  showing battery voltage, and an x-axis  120  showing time in terms of hours of battery use. From the slope of  FIG. 1 , for approximately the initial three quarters of the battery life the voltage stays above 1.2 Volts and for the final one quarter of the battery life the voltage is below 1.2 Volts. 
   In an example, the microcontroller has an operating voltage range of 3.0V to 3.6V, the sensor 3.0V to 3.6V, and the radio IC 2.7 to 3.6V. The microcontroller and optical sensor must be powered from a boosted supply because the battery voltage only falls within the operating voltage range of the sensor for a tiny fraction of the battery life. 
   One example of a system where a method of bypassing a DC boost converter would be useful is a wireless optical mouse. In a wireless optical mouse, the radio IC may similarly be powered from the boost converter output, and the boost converter may generate 3.3V in order to guarantee that ripple, tolerance, and other undesirable phenomena did not cause the boost converter output ever to fall below 3.0V, the minimum operating voltage of the sensor. 
   In the wireless optical mouse, there is no easy way to determine whether or not the optical sensor is performing correctly when supplied with a voltage below Vcc(min). Therefore, it is not possible to supply the sensor with a voltage &lt;3.0V and test whether the sensor is operating correctly. However, if the radio IC is a radio transceiver, it may be possible to determine whether or not the radio IC is performing correctly at a voltage below the guaranteed minimum operating voltage, by monitoring the bit error rate (BER) of the output of a device. Alternatively a built in self test (BIST) could be used. 
   In the wireless optical mouse, when the mouse is not moving, the microcontroller, the mouse sensor and the radio are all held in a low power “sleep” mode. Periodically, the microcontroller will wake from this mode, wake the optical sensor, and check for movement; if no movement is detected, the microcontroller and sensor will return to sleep mode. If motion is detected, the microcontroller will wake the radio, and attempt to establish communications with the an interface or “dongle”, which is connected to the computer with which the mouse is designed to operate. A dongle is a term used to describe an interface device that is coupled to a computer to act as a transmitter or receiver or other kind of translator device for input and/or output signals. 
   On receiving communications from the wireless mouse device, the dongle will transmit back to the mouse an “acknowledge” data packet (ACK), and the mouse microcontroller will know that the wireless link is working correctly, and begin periodically transmitting mouse motion data for as long as the mouse is moving. Each such mouse motion data packet will be acknowledged by the dongle, so that in the case of a high bit error rate or a breakdown in the wireless link, the mouse can re-transmit the data which was lost. 
   The wireless mouse described is one of many methods of communicating between the mouse and dongle, and variants are possible. In another example, the MCU and sensor together draw 15 mA when the mouse is being moved, and the radio draws an average of 10 mA. The boost converter is 80% efficient, and the life-average output voltage of the batteries is 1.2V. The average current drawn from the batteries is therefore (3.3/2.4)*(100/80)*25=43 mA. With a battery life of 2850 mAh, the typical battery life of the mouse is 66 hours of cumulative mouse motion (this is equivalent to two to three months of typical mouse usage). 
   An embodiment of an improved method and apparatus for increasing the battery life of a wireless device is described. A schematic of the hardware of an exemplary implementation of the improved method and apparatus is shown in  FIG. 2 . The implementation of  FIG. 2  comprises an architecture  200  for a wireless device having increased battery life. The architecture  200  comprises a battery  210 , a boost converter  220 , a first switch  230 , a second switch  240 , a first resistor  250 , a second resistor  260 , a processing element (in a preferred element a processing element  270 , a mouse sensor  280 , and a radio device  290 . The function of the boost converter  220  is to take an input voltage or range of input voltages and boost it up to a desired output voltage. The output  220  of the boost converter is used in one embodiment to power the microcontroller  270  and the mouse sensor  280 , and indirectly to power the radio IC  290 . In  FIG. 2 , bipolar transistors  230  and  240  together with resistors  250  and  260  are shown as a low-cost option for switching the voltage supply to the radio. Field effect transistors (FETs) or other electrical switching components may be substituted, for example switching diodes. In a preferred embodiment the processing element is a microcontroller, but may also be replaced with a general purpose microprocessor, a digital signal processor, a programmable logic processor, a state machine, or other processing function. 
   The improved method and apparatus improves upon the conventional implementation using a method  300  for increasing battery life of a wireless device, as shown in  FIG. 3 . The method operates by powering the radio IC directly from the battery voltage until the battery voltage has fallen to a level where the radio ceases to perform sufficiently well to maintain a wireless communication link with the dongle. The method  300  comprises a number of steps, as described. In a first step  310 , an event causes the microcontroller to need to establish a communications link with the dongle. In a second step  320 , the microcontroller turns on the transistor between the radio Vcc and the boost converter output, and turns off the transistor between the radio Vcc and the battery (radio powered from 3.3V). In a third step  330 , the microcontroller sends and receives a sequence of radio transmissions establishing the communications link with the dongle. In a fourth step  340 , the microcontroller turns off the transistor between the radio Vcc and the boost converter output, and turns on the transistor between the radio Vcc and the battery (radio powered from the batteries). In a fifth step  350 , the microcontroller makes a test transmission, to determine the quality of the wireless link with the dongle. In a sixth step  360 , the determination is made as to whether the quality of the link is inadequate, and if it is inadequate then the microcontroller turns on the transistor between the radio Vcc and the boost converter output, and turns off the transistor between the radio Vcc and the battery (radio powered from 3.3V). If the quality of the link is good, the MCU leaves the radio powered from the battery. In a seventh step  370 , the microcontroller sends mouse data to the dongle. In an eighth step  380 , if at any time while the radio is powered from the battery the MCU consistently fails to receive ACK handshake packets from the dongle, then the microcontroller will turn on the transistor between the radio Vcc and the boost converter output, and turn off the transistor between the radio Vcc and the battery (so that radio powered from 3.3V). 
   In the exemplary embodiment, the radio IC will typically operate down to 2.4V. Above the 2.4V level the radio is consistently powered directly from the batteries. The battery voltage is above this voltage for about 75% of its life. During the remaining 25% of the battery life, the radio will be supplied from the boost converter. This operation is illustrated in the diagram of  FIG. 4 .  FIG. 4  comprises a graph  400  showing operation of the wireless device having increased battery life. A first y-axis  410  shows the battery voltage, and x-axis  430  shows time elapsed. A second y-axis  420  shows the voltage supplied to the radio IC over the time shown in the X axis  430 . Note that in  FIG. 4 , the x-axis is not shown to scale. Line  440  shows the drop in battery voltage over time used and line  450  shows the voltage supplied to the radio IC device. This voltage is supplied from the boost converter or the battery depending on whether the battery voltage is above the trip point (non-shaded area) or below the trip point (shaded area) The shaded area is an area of uncertainty, the radio supply may be switched at any point between the best and worst case Vcc (min). 
   In one exemplary embodiment the battery life may be calculated in the following manner. For the microcontroller and sensor, the average battery current is (3.3V/2.4V)*(100/80)*15, resulting in 26 mA current consumption. For the first approximately 75% of the battery life, the battery current required to supply the radio is 10 mA. For the remaining approximately 25% of the battery life, the average battery voltage is 1.05V, so the current is (3.3/2.1)*(100/80)*10, resulting in 19 mA. The overall average radio current is therefore 12 mA across the full lifetime of the battery. 
   In this exemplary embodiment, the overall average battery current is therefore 38 mA, giving a battery life of 75 hours. In this exemplary embodiment, the improved method and apparatus has extended battery life by 13%. This may be valuable, particularly in reducing the support burden on IT personnel by lowering the frequency at which batteries must be replaced, in reducing the expenditure on batteries, and on reducing the inconvenience to the user of having to have batteries replaced. 
     FIG. 5  shows a method  500  for supplying a voltage to a first radio circuit. A first step  510  comprises powering the first radio circuit with a first fixed boosted voltage supply. A second step  520  comprises establishing a wireless communications link between the first radio circuit and a second radio circuit. A third step  530  comprises switching a second voltage supply to the first radio circuit so that the first radio circuit is powered from a variable voltage. A fourth step  540  comprises testing the integrity of the wireless communications link powered by the second variable voltage. 
     FIG. 6  shows a system  600  with a wireless device having increased battery life. The system comprises a computer  610 , a dongle interface  620 , a wireless device such as a wireless keyboard  630  or a wireless mouse  640 , and a wireless link  650 . The computer  610  communicates with the wireless device  630  or  640  through the dongle  620  and over the wireless link  650 . 
   In a first alternative embodiment, the improved method and apparatus may be applied to any wireless device, in which the radio IC has a minimum operating voltage higher than the minimum battery voltage. The improved method and apparatus may also be applied to wireless devices where the radio is constructed from discrete components, and where the radio circuit may typically operate at a voltage below the calculated worst-case minimum. 
   The improved method and apparatus may be extended to any battery powered application in which an IC or circuit has a minimum operating voltage higher than the minimum battery voltage, and where it is possible to determine whether or not the IC or circuit is performing correctly when the supply voltage is lower than the guaranteed minimum operating voltage of the IC. 
   In a second alternate embodiment of the improved method and apparatus, the fixed-output boost converter is replaced with a variable output boost converter, the output being controlled by the microcontroller (or other processing element). In this variant, the microcontroller reduces the voltage of the boost converter output to a level just above that at which the radio (or other circuit) ceases to operate correctly. 
   The improved method and apparatus has the advantages of enabling longer battery life by powering the radio from the battery until the battery voltage falls to a level at which the radio ceases to operate satisfactorily. 
   For purposes of clarity, many of the details of wireless mouse controllers and the methods of designing and manufacturing the same that are widely known and are not relevant to the present invention have been omitted from the following description. 
   It should be appreciated that reference throughout this specification to “one embodiment” or “an embodiment” means that a particular feature, structure or characteristic described in connection with the embodiment is included in at least one embodiment of the present invention. Therefore, it is emphasized and should be appreciated that two or more references to “an embodiment” or “one embodiment” or “an alternative embodiment” in various portions of this specification are not necessarily all referring to the same embodiment. Furthermore, the particular features, structures or characteristics may be combined as suitable in one or more embodiments of the invention. 
   Similarly, it should be appreciated that in the foregoing description of exemplary embodiments of the invention, various features of the invention are sometimes grouped together in a single embodiment, figure, or description thereof for the purpose of streamlining the disclosure aiding in the understanding of one or more of the various inventive aspects. This method of disclosure, however, is not to be interpreted as reflecting an intention that the claimed invention requires more features than are expressly recited in each claim. Rather, as the following claims reflect, inventive aspects lie in less than all features of a single foregoing disclosed embodiment. Thus, the claims following the detailed description are hereby expressly incorporated into this detailed description, with each claim standing on its own as a separate embodiment of this invention.