Abstract:
In an embodiment, the invention provides a method for measuring properties of light of a photoelectric device. A capacitor is charged through a switch until a first voltage is obtained. After the capacitor is charged to the first voltage, the switch is opened from the capacitor and the capacitor is discharged through a photoelectric device, which conducts current when acted upon by a property of light, until a second voltage is obtained. The capacitor is charged and discharged in the manner previously described until the frequency of the voltage on the capacitor is determined. When the frequency of the voltage on the capacitor is determined, an electrical signal is generated that is proportional to the frequency of the voltage on the capacitor.

Description:
BACKGROUND 
       [0001]    Various devices require the conversion of properties of light into electrical signals. These devices are often used in applications such as ambient light measurement, light absorption/reflection in products, photographic equipment, colorimetry, chemical analyzers and display contrast controls or any system requiring a wide dynamic range and/or high resolution digital measurement of light intensity. Other applications include notebook computers, tablet computers, flat-panel televisions, cell phones, digital cameras, street light control, security lighting, sunlight harvesting, machine vision, and automotive instrumentation clusters. 
         [0002]    A device requiring the conversion of properties of light into electrical properties may perform the functions of light sensing, signal conditioning, and A/D (analog to digital) conversion on a single monolithic IC (integrated circuit). A device may convert light intensity into a digital format for use with a microcontroller. A color sensor may be used to detect a particular frequency of light. A color sensor with a digital output often makes use of pipelined A/D conversion. These devices often require a large amount of area on an IC or on a printed circuit board. In addition to the large amount of area required, these devices often use a large amount of power. 
         [0003]    Analog signal conditioning is often required between a sensor, a photodiode for example, and an A/D converter. A result of having analog signal conditioning between a sensor and an A/D converter is that the speed at which sensing occurs is reduced. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0004]      FIG. 1  is a schematic diagram of an embodiment of a device for converting properties of light into electrical signals. 
           [0005]      FIG. 2  is a timing diagram of an embodiment of a device for converting properties of light into electrical signals. 
           [0006]      FIG. 3  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 10 nA. 
           [0007]      FIG. 4  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 20 nA. 
           [0008]      FIG. 5  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 50 nA. 
           [0009]      FIG. 6  is a flow chart illustrating an embodiment of a method for converting properties of light into electrical signals. 
       
    
    
     DETAILED DESCRIPTION 
       [0010]    An embodiment of the invention converts light intensity into a variable frequency “sawtooth” voltage waveform. In this embodiment, photocurrent from a photodiode is converted to a “sawtooth” voltage waveform by a capacitor and a comparator. In this embodiment, the “sawtooth” voltage waveform frequency varies in proportion to the light intensity. In this embodiment, a frequency converter converts the “sawtooth” voltage waveform frequency into an electrical signal indicating the intensity of light. The electrical signal in this example may be an analog electrical signal or a digital electrical signal. 
         [0011]      FIG. 1  is a schematic diagram of an embodiment of a device,  100 , for converting properties of light into electrical signals. Properties of light include, but are not limited to, the intensity of light and the frequency of light. In this embodiment, a capacitor C 1 ,  110 , is electrically connected to GND and node VCAP,  116 . Electrical switch S 1 ,  108 , is electrically connected to voltage reference VREF 1 ,  112 , COMPOUT,  118 , and VCAP,  116 . A photoelectric device,  102 , is electrically connected to GND and VCAP,  116 . A comparator,  106 , has a first electrical input,  122 , connected to VCAP,  116 , a second electrical input,  124 , connected to voltage reference, VREF 2 ,  114 , and an electrical output,  126 , connected to node COMPOUT,  118 . Node VCAP,  116 , is connected to an electrical input,  128 , of the frequency counter,  104 , and an output,  130 , of the frequency counter,  104 , is connected to node FC_OUT,  120 . In  FIG. 1 , a charging/discharging device is represented by the box  132 . 
         [0012]    Referring to an embodiment of the invention in  FIG. 1 , when switch S 1 ,  108 , is closed, capacitor C 1 ,  110 , is charged to voltage reference VREF 1 ,  112 . When capacitor C 1 ,  110 , is charged to voltage reference VREF 1 ,  112 , the voltage on the first input,  122 , of comparator  106  is at voltage reference VREF 1 ,  112 . The voltage of reference VREF 2 ,  114  is chosen to be lower than the voltage of VREF 1 ,  112 . When the first input,  122 , of the comparator,  106 , is charged to VREF 1 ,  112 , the output,  126 , of the comparator,  106 , drives node COMPOUT,  118 , to “off.” Because node COMPOUT,  118 , is “off” the switch, S 1 ,  108 , is open. When switch S 1 ,  108 , opens, node VCAP,  116 , is not connected to voltage reference, VREF 1 ,  112 . 
         [0013]    With switch S 1 ,  108 , open and voltage reference VREF 1 ,  112 , not connected to node VCAP,  116 , capacitor C 1 ,  110 , begins to discharge through the photoelectric device,  102 . The photoelectric device  102 , for example a photodiode, discharges the capacitor C 1 ,  110 , because a property of light is causing the photoelectric device  102  to conduct current. The current conducted through the photoelectric device  102  discharges the capacitor C 1 ,  110 . The current conducted through the photoelectric device  102  may be caused by the intensity of the light, the frequency of the light, or other properties of light. 
         [0014]    When the voltage on node VCAP,  116 , is discharged below the voltage of voltage reference, VREF 2 ,  114 , the output,  126 , of the comparator,  106 , is turned “on.” When the node COMPOUT,  118  is turned “on”, switch S 1 ,  108 , is closed. With switch S 1 ,  108 , closed, node VCAP,  116 , is electrically connected to voltage reference VREF 1 ,  112 . With VCAP,  116 , electrically connected to voltage reference VREF 1 ,  112 , capacitor C 1 ,  110 , begins to charge. Capacitor C 1 ,  110 , will charge until it reaches the voltage of VREF 1 ,  112 . When capacitor C 1 ,  110 , reaches the voltage of VREF 1 ,  112 , the output,  126 , will switch “off” causing the switch S 1 ,  108 , to open. 
         [0015]    The charging of capacitor C 1 ,  110 , through switch S 1 ,  108 , and the discharging of capacitor C 1 ,  110 , through the photoelectric device will cause the voltage on node VCAP,  116 , to swing between VREF 2 ,  114 , and VREF 1 ,  112 . The frequency at which node VCAP,  116 , swings between VREF 2 ,  114  and VREF 1 ,  112 , is determined by the size of capacitor C 1 ,  110 , the voltage difference between VREF 1 ,  112 , and VREF 2 ,  114 , and the current conducted through the photoelectric device. 
         [0016]      FIG. 2  is a timing diagram of an embodiment of a device for converting properties of light into electrical signals.  FIG. 2  shows two plots of voltage versus time. In plot  1 , the voltage VCAP,  116 , is plotted as function of tine while discharging and charging capacitor C 1 ,  110 . In plot  2 , the voltage on node COMPOUT,  118 , is plotted as function of time while discharging and charging capacitor C 1 ,  110 . 
         [0017]    During phase  1  as shown in  FIG. 2 , node COMPOUT,  118  is “on.” “On” in this example means that node, COMPOUT,  118 , is VDD. VDD may represent a positive value of a power supply used with the comparator  106 . When node COMPOUT,  118  is at VDD, switch S 1 ,  108 , closes connecting VREF 1 ,  112 , to capacitor C 1 ,  110 . During phase  1  the voltage on node VCAP,  116 , charges from VREF 2 ,  114  to VREF 1 ,  112 , as shown in plot  1  of  FIG. 2 . 
         [0018]    During phase  2  as shown in  FIG. 2 , node COMPOUT,  118  is “off.” “Off” in this example means that the node, COMPOUT,  118 , is GND. When node COMPOUT,  118  is at GND, switch S 1 ,  108 , opens disconnecting VREF 1 ,  112 , from capacitor C 1 . During phase  2 , the voltage VCAP,  116 , on capacitor, C 1 ,  110 , is discharged through the photoelectric device  102  from voltage VREF 1 ,  112 , to voltage VREF 2 ,  114  as shown in plot  1  of  FIG. 2 . Repeating phases  1  and  2  creates a “sawtooth” voltage waveform,  202 , as shown in  FIG. 2 . The frequency of the “sawtooth” waveform,  202 , is determined by the size of capacitor C 1 ,  110 , the voltage difference between VREF 1 ,  112 , and VREF 2 ,  114 , and the current conducted through the photoelectric device,  102 . 
         [0019]    When the size of capacitor C 1 ,  110 , is fixed and the voltage difference between VREF 1 ,  112 , and VREF 2 ,  114  is fixed, the frequency of the “sawtooth” waveform,  202 , is dependent on the magnitude of the current conducted through the photoelectric device  102 . If the current through the photoelectric device  102  is increased the frequency of the “sawtooth” waveform,  202 , is increased. If the current through the photoelectric device  102  is decreased the frequency of the “sawtooth” waveform,  202 , is decreased. 
         [0020]    Switch S 1 ,  108 , may be implemented using various types of transistors. These transistors include but are not limited to NFET (N-type Field Effect Transistor) transistors, PFET (P-type Field Effect Transistor) transistors or bipolar transistors. The absolute voltage used to turn “on” these transistors as switches varies with each transistor. For example, a logical zero may be used to turn “on” a PFET transistor and a logical one may be used to turn “on” an NFET transistor. 
         [0021]    The photoelectric device  102  shown in  FIG. 1  may implemented with various types of photoelectric devices. These include but are not limited to photodiodes and photocells. The output,  130 , of the frequency counter  104  may increase in magnitude as the frequency increases or the output,  130 , of the frequency counter  104  may decrease in magnitude as frequency increases depending on the requirements of the system using the output  130 . The output,  130 , may be an analog electrical signal or a digital electrical signal. The output,  130 , represents the magnitude of the current generated by a photoelectric device. VREF 1 ,  112 , may be a constant voltage reference or a constant current reference. 
         [0022]      FIG. 3  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 10 nA. Voltage is represented on the Y-axis of the plot and time is represented on the X-axis of the plot. The voltage, VCAP,  116 , on the Y-axis ranges from 0 volts to 1.8 volts in this example. The diode current, Ip, in this example is 10 na. A “sawtooth” voltage, VCAP,  116 , waveform is created by charging and discharging capacitor C 1 ,  110 , between the voltages of VREF 1 ,  112 , and VREF 2 ,  114 . The frequency of this voltage, VCAP,  116 , waveform is proportional to the magnitude of diode current, Ip. 
         [0023]      FIG. 4  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 20 nA. Voltage is represented on the Y-axis of the plot and time is represented on the X-axis of the plot. The voltage, VCAP,  116 , on the Y-axis ranges from 0 volts to 1.8 volts in this example. The diode current, Ip, in this example is 20 na. A “sawtooth” voltage, VCAP,  116 , waveform is created by charging and discharging capacitor C 1 ,  110 , between the voltages of VREF 1 ,  112 , and VREF 2 ,  114 . The frequency of this voltage, VCAP,  116 , waveform is proportional to the magnitude of diode current, Ip. The frequency of the voltage, VCAP,  116 , waveform shown in  FIG. 4  is greater than the frequency of the voltage, VCAP,  116 , waveform shown in  FIG. 3  because the magnitude of the diode current, Ip, in  FIG. 4  is greater than the magnitude of the diode current, Ip, in  FIG. 3 . 
         [0024]      FIG. 5  is a frequency plot of a simulation of an embodiment of a device for converting properties of light into electrical signals where the current through a photodiode is 50 nA. Voltage is represented on the Y-axis of the plot and time is represented on the X-axis of the plot. The voltage, VCAP,  116 , on the Y-axis ranges from 0 volts to 1.8 volts in this example. The diode current, Ip, in this example is 50 na. A “sawtooth” voltage, VCAP,  116 , waveform is created by charging and discharging capacitor C 1 ,  110 , between the voltages of VREF 1 ,  112 , and VREF 2 ,  114 . The frequency of this voltage, VCAP,  116 , waveform is proportional to the magnitude of diode current, Ip. The frequency of the voltage, VCAP,  116 , waveform shown in  FIG. 5  is greater than the frequency of the voltage waveforms shown in  FIGS. 3 and 4  because the magnitude of the diode current, Ip, in  FIG. 5  is greater than the magnitude of the diode current, Ip, shown in  FIGS. 3 and 4 . 
         [0025]    It can be seen that when comparing the frequency of the voltage waveforms shown in  FIGS. 3 ,  4  and  5  the frequency of the voltage waveforms increases as the diode current, Ip, increases. In these three examples, the value of the capacitor, C 1 ,  110 , remains constant. In addition, in these examples the values VREF 1 ,  112 , and VREF 2  remain constant. It may be appreciated that changing the value of C 1 ,  110 , VREF 1 ,  112 , or VREF 2 ,  114  will result in a change in the frequency of the voltage waveforms shown in  FIGS. 3 ,  4  and  5 . 
         [0026]      FIG. 6  is a flow chart illustrating an embodiment of a method for converting properties of light into electrical signals. Box  602  describes a capacitor C 1 ,  110 , that is charged through switch S 1 ,  108 , until the voltage on node VCAP,  116 , reaches the voltage of voltage reference, VREF 1 ,  112 . Box  604  describes a switch S 1 ,  108 , that is opened from the capacitor C 1 ,  110 , when the voltage on node VCAP,  116 , reaches the voltage of voltage reference VREF 1 ,  112 . Box  606  describes a capacitor C 1 ,  110 , that begins to discharge through an active photoelectric device  102  after switch S 1 ,  108 , is opened from the capacitor, C 1 ,  110 , and continues to discharge until the voltage on node VCAP,  116 , falls below the reference voltage VREF 2 ,  112 . Box  608  describes a condition that when the voltage on node VCAP,  116 , falls below the reference voltage VREF 2 ,  112 , the switch S 1 ,  108 , closes to capacitor C 1 ,  110 . The process of charging capacitor, C 1 ,  110  to the voltage of voltage reference VREF 1 ,  112  and discharging capacitor, C 1 ,  110 , until the voltage on node VCAP,  116 , falls below the reference voltage, VREF 2 ,  112 , is repeated until the frequency of the voltage on node VCAP,  116 , is determined,  610 . When the frequency of the voltage on node VCAP,  116 , is determined,  612 , the output,  130  of the frequency counter,  104 , outputs an electrical signal, FC_OUT,  120 , that is proportional to the current conducted through the photoelectric device  102 . The electrical signal, FC_OUT,  120 , may be an analog electrical signal or a digital electrical signal. 
         [0027]    One advantage, among others, of an embodiment of this invention is that it operates nearly independent of process and temperature variation. When VREF 1 ,  112 , and VREF 2 ,  114 , are derived from the same voltage reference, their variation with process and temperature variation has a minimal effect on its operation because VREF 1 ,  112 , and VREF 2 ,  114 , nearly track each other resulting in a constant VREF 1 −VREF 2  difference. 
         [0028]    Another advantage of an embodiment of this invention is that it operates nearly independent of noise. When VREF 1 ,  112 , and VREF 2 ,  114 , are derived from the same voltage reference, noise presented on nodes VREF 1 ,  112 , and VREF 2 ,  114 , is nearly canceled because the noise is presented nearly equally on both VREF 1 ,  112 , and VREF 2 ,  114 . 
         [0029]    Other advantages of this invention include that it requires very little area to implement and that it consumes less power than other similar sensor devices. In addition, an embodiment of this invention converts light intensity into meaningful information faster than other similar sensor devices without reducing accuracy. 
         [0030]    The foregoing description has been presented for purposes of illustration and description. It is not intended to be exhaustive or to limit the invention to the precise form disclosed, and other modifications and variations may be possible in light of the above teachings. The exemplary embodiments were chosen and described in order to best explain the applicable principles and their practical application to thereby enable others skilled in the art to best utilize various embodiments and various modifications as are suited to the particular use contemplated. It is intended that the appended claims be construed to include other alternative embodiments except insofar as limited by the prior art.