A current detection module capable of differentiating and quantifying contribution to a current signal generated by a sensor in response to stimulation by a certain target source from contributions from sources other than the target source (ambient sources) is disclosed. As long as the contribution from the target source comprises a pulsed signal, the module may synchronize itself to the pulse(s) so that there is a predetermined phase relationship between the pulse(s) and functions carried out by various stages of the module. The module may be re-used to also detect and quantify contributions from ambient sources by presenting these contributions to the module as pulses that trigger synchronization of the module. To that end, a detection system disclosed herein is based on the use of such current detection module and allows mode switching where, depending on the selected mode of operation, the module is configured to perform different measurements.
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20. A detection system comprising:
a sensor configured to generate a current signal indicative of the sensor detecting a stimuli that comprises a pulse or a series of repeating pulses generated by a target source;
a current detection module having a predetermined phase relationship between operation of the current detection module and the pulse or the series of repeating pulses generated by the target source, and configured to determine a contribution to the current signal due to the detected stimuli from the target source.
0. 28. A method for determining the presence of an object using a pulsed electromagnetic field source, the steps comprising:
producing a pulse train from a first electromagnetic field source;
receiving at a first sensor, the pulse train having a predetermined clock phase;
receiving at the first sensor, a background electromagnetic field;
producing a combined signal which includes a pulse train signal based at least on the received pulse train and a background signal at least based on the received background electromagnetic field;
extracting the pulse train signal from the background signal at least based on subtraction and the predetermined clock phase; and,
analyzing the object at least based on the extracted pulse train signal.
0. 47. An apparatus for determining the presence of an object using a pulsed electromagnetic field source comprising:
means for producing a pulse train from a first electromagnetic field source;
means for receiving at a first sensor, the pulse train having a predetermined clock phase;
means for receiving at the first sensor, a background electromagnetic field;
means for producing a combined signal which includes a pulse train signal based at least on the received pulse train and a background signal at least based on the received background electromagnetic field;
means for extracting the pulse train signal from the background signal at least based on subtraction and the predetermined clock phase; and,
means for analyzing the object at least based on the extracted pulse train signal.
0. 38. A system for analyzing the presence of a proximal object using a pulsed electromagnetic field source comprising:
a first electromagnetic field source producing a pulse train, the pulse train having a predetermined clock phase;
a first sensor which senses the pulse train and a background electromagnetic field;
an analog circuit which produces a combined signal, the combined signal comprises a pulse train signal based at least on the received pulse train and a background signal at least based on the received background electromagnetic field;
a clock having the predetermined clock phase;
a module which extracts the pulse train signal from the background signal at least based on subtraction and the predetermined clock phase; and,
a comparator circuit which analyzes the object at least based on the extracted pulse train signal.
18. A detection system comprising:
first means for generating a current signal, the current signal comprising at least a first portion comprising a contribution from a target source and/or a second portion comprising a contribution from one or more sources other than the target source, and generating a digital value indicative of the first portion of the current signal and/or a digital value indicative of the second portion of the current signal; and
second means for setting the first means to operate in one of a first mode, a second mode, and a third mode, wherein:
in the first mode, the first means is configured to generate the digital value indicative of the first portion,
in the second mode, the first means is configured to generate the digital value indicative of at least the second portion when the contribution from the one or more sources other than the target source is in a first range of values, and
in the third mode, the first means is configured to generate the digital value indicative of at least the second portion when the contribution from the one or more sources other than the target source is in a second range of values, the second range of values having an upper end higher than an upper end of the first range of values.
1. A detection system comprising:
a sensor configured to generate a current signal, the current signal comprising at least a first portion comprising a contribution from a target source and/or a second portion comprising a contribution from one or more sources other than the target source;
a current detection module configured to receive the current signal generated by the sensor and generate a digital value indicative of the first portion of the current signal and/or a digital value indicative of the second portion of the current signal; and
a mode switch configured to set the current detection module to operate in one of a first mode, a second mode, and a third mode, wherein:
in the first mode, the current detection module is configured to generate the digital value indicative of the first portion,
in the second mode, the current detection module is configured to generate the digital value indicative of at least the second portion when the contribution from the one or more sources other than the target source is in a first range of values, and
in the third mode, the current detection module is configured to generate the digital value indicative of at least the second portion when the contribution from the one or more sources other than the target source is in a second range of values, the second range of values having an upper end higher than an upper end of the first range of values.
2. The detection system according to
3. The detection system according to
wherein in the fourth mode,
the mode switch is configured to:
set the current detection module to operate in the second mode for a first period of time while the target source is not generating the contribution to the current signal to generate a first digital value indicative of the second portion in absence of the first portion, and
set the current detection module to operate in the second mode for a second period of time while the target source is generating the contribution to the current signal to generate a second digital value indicative of a total of the first portion and the second portion, and
the current detection module is configured to generate the digital value indicative of the first portion by subtracting the first digital value from the second digital value.
4. The detection system according to
5. The detection system according to
6. The detection system according to
7. The detection system according to
8. The detection system according to
9. The detection system according to
a first stage comprising a trans-impedance amplifier configured to amplify the current signal and generate a low noise signal;
a second stage comprising a high pass filter configured to convert the low noise signal into an alternating current (AC) signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude;
a third stage comprising:
a positive integrating amplifier configured to receive the positive amplitude of the AC signal and generate a positive integrated value over an integration period; and
a negative integrating amplifier configured to receive the negative amplitude of the AC signal and generate a negative integrated value over the integration period; and
a fourth stage comprising at least an analog-to-digital converter (ADC) configured to receive the positive and negative integrated values and generate the digital value indicative of the first portion of the current signal and/or the digital value indicative of the second portion of the current signal based on the positive and negative integrated values.
10. The detection system according to
11. The detection system according to
12. The detection system according to
13. The detection system according to
14. The detection system according to
15. The detection system according to
16. The detection system according to
17. The detection system according to
19. The detection system according to
21. The detection system according to
a first stage comprising a trans-impedance amplifier configured to amplify the current signal and generate a low noise signal;
a second stage comprising a high pass filter configured to convert the low noise signal into an alternating current (AC) signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude;
a third stage comprising:
a positive integrating amplifier configured to receive the positive amplitude of the AC signal and generate a positive integrated value over an integration period; and
a negative integrating amplifier configured to receive the negative amplitude of the AC signal and generate a negative integrated value over the integration period; and
a fourth stage comprising at least an analog-to-digital converter (ADC) configured to receive the positive and negative integrated values and determine the contribution to the current signal due to the detected stimuli based on the positive and negative integrated values.
22. The detection system according to
the current detection module is configured to determine the contribution to the current signal due to the detected stimuli from the target source when the current detection module operates in the first mode, and
the current detection module is configured to determine the contribution to the current signal due to the detected stimuli from one or more sources other than the target source when the current detection module operates in the second mode.
23. The detection system according to
the current detection module is configured to operate in the second mode when the contribution from the one or more sources other than the target source is in a first range of values, and
the current detection module is configured to operate in the third mode when the contribution from the one or more sources other than the target source is in a second range of values, the second range of values having an upper end higher than an upper end of the first range of values, to determine the contribution to the current signal due to the detected stimuli from one or more sources other than the target source.
24. The detection system according to
operate in the second mode for a first period of time during which the sensor is not detecting the stimuli from the target source to determine the contribution to the current signal due to the detected stimuli from one or more sources other than the target source in absence of the contribution to the current signal due to the detected stimuli from the target source,
operate in the second mode for a second period of time during which the sensor is detecting the stimuli from the target source to determine a combined contribution due to the sensor detecting both the stimuli from the target source and the stimuli from one or more sources other than the target source, and
determine the contribution to the current signal due to the stimuli from the target source by subtracting the contribution determined for the first period of time from the combined contribution determined for the second period of time.
25. The detection system according to
the current signal is a first current signal, further comprising a contribution due to the sensor detecting a stimuli from one or more sources other than the target source,
the sensor is configured to generate the first current signal for a first time period during which the sensor is detecting both the stimuli from the target source and the stimuli from one or more sources other than the target source,
the sensor is further configured to generate a second current signal for a second time period during which the sensor is detecting the stimuli from one or more sources other than the target source and not detecting the stimuli from the target source,
the current detection module is configured to determine the contribution to the current signal due to the stimuli from the target source based on a difference between the first current signal and the second current signal.
26. The detection system according to
the pulse generated by the target source or each pulse of the series of repeating pulses generated by the target source has a duration of τ,
the current detection module comprises a trans-impedance amplifier configured to amplify the current signal and generate a low noise signal and a high pass filter configured to convert the low noise signal into an alternating current (AC) signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude, and
the predetermined phase relationship between operation of the current detection module and the pulse or the series of repeating pulses generated by the target source comprisea the bandwidth of the high pass filter being 1/τ, and a corner frequency of the high pass filter being 0.5/τ.
27. The detection system according to
the current detection module comprises a clock, and
the current detection module having the predetermined phase relationship with the pulse or the series of repeating pulses generated by the target source comprises one or more frequencies present in the pulse or the series of repeating pulses generated by the target being synchronized to the clock.
0. 29. The method of claim 28, wherein the electromagnetic field is a quasi-static electric field.
0. 30. The method of claim 29, wherein the first sensor is a first capacitive sensor.
0. 31. The method of claim 28, wherein the first electromagnetic field source is a first light source.
0. 32. The method of claim 31, wherein the first sensor is photodiode.
0. 33. The method of claim 28, further comprising the step of producing a clock signal at least based on the predetermined clock phase.
0. 34. The method of claim 33, further comprising the step of synchronizing the received pulse train signal with the produced clock signal.
0. 35. The method of claim 28, further comprising switching between a first mode associated with the pulse train signal and a second mode associated with the background signal.
0. 36. The method of claim 28, further comprising low-pass filtering at least one of the background and pulse train signals.
0. 37. The method of claim 28, further comprising digitally sampling at least one of the background and pulse train signals.
0. 39. The system of claim 38, wherein the electromagnetic field is a quasi-static electric field.
0. 40. The system of claim 39, wherein the first sensor is a first capacitive sensor.
0. 41. The system of claim 38, wherein the first electromagnetic field source is a first light source.
0. 42. The system of claim 41, wherein the first sensor is photodiode.
0. 43. The system of claim 38, further comprising an analog to digital converter (ADC).
0. 44. The system of claim 43, further comprising a module for which synchronizes the received pulse train signal with a produced clock signal based on the clock.
0. 45. The system of claim 38, further comprising a mode switch configured switch between a first mode associated with the pulse train signal and a second mode associated with the background signal.
0. 46. The system of claim 38, further comprising a low-pass filter configured to filter at least one of the background and pulse train signals.
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This application claims the benefit of and priority from U.S. Provisional Patent Application Ser. No. 62/029,361 filed 25 Jul. 2014 entitled “Circuit Architecture for Mode Switch”, which is incorporated herein by reference in its entirety.
The present disclosure relates to the field of integrated circuits, in particular to current detectors.
A photodiode (also referred to as “photodetector”) is a type of a sensor capable of converting light into current or voltage. Generally, the photodiode is a semiconductor device with a PIN or PN connection structure. When a photon of sufficient energy strikes the photodiode, it excites electrons, creating free electrons and positively charged electron holes. The holes move toward the anode, and electrons toward the cathode, and a photocurrent is produced proportional to the amount of incident light on the photodiode.
Other types of sensors include e.g. pyro-electric, piezo-electric, or capacitive sensors.
All of these sensors are common in that they include a pair of electrodes and, when stimulated by their respective stimuli, the state of charge across the electrodes changes. Current resulting from the changed state of charge across the electrodes can then be used to detect and quantify the stimuli. For example, a photodiode produces a change in the state of charge across its electrodes when the light is incident on the photodiode. In other words, the photodiode generates current (which may be referred to as “photocurrent”) in the presence of light, where the current is proportional to the amount of light incident on the photodiode. Similarly, a pyro-electric sensor produces a change in the state of charge across its electrodes when heated or cooled, a piezo-electric sensor produces a change in the state of charge across its electrodes in response to the change in its mechanical orientation (e.g. strain), while a capacitive sensor is one where changes in the environment change the effective capacitance of the sense element, which in turn changes the capacity to hold charge.
For such sensors, as well as other sensors operating according to similar principles of detecting change of charge state, it may be desirable to be able to detect and quantify stimuli originating from a specific source of interest as well as stimuli originating from all other sources besides the source of interest. For example, in context of a photodiode, it may be desirable to detect and quantify a contribution to the current generated by the photodiode that is due to the detection of light generated by a particular light source of interest, e.g. a particular light emitting diode (LED), as well as to detect and quantify contribution to the photocurrent that is due to the detection of light generated by all other light sources besides this light source of interest.
Overview
Present disclosure relates to a current detection module capable of differentiating and quantifying contribution to a current signal generated by a sensor as a result of stimulation by a certain source of interest (target source) from contributions from sources other than the source of interest (ambient sources). As long as the contribution from the target source comprises a pulsed signal, the module synchronizes itself to the pulse(s) so that there is a predetermined phase relationship between the pulse(s) and functions carried out by various stages of the module. The module may be re-used to also provide high precision detection and quantification of contributions to the sensor-generated current signal from ambient sources by presenting, to the current detection module, the contributions from ambient sources as one or more pulses which, in turn, trigger synchronization of the module. To that end, a detection system is provided that implements the current detection module as described herein and allows mode switching where, depending on the mode of operation being selected, the current detection module is configured to perform different kinds of measurements.
Accordingly, in one aspect of the present disclosure, a detection system includes a sensor configured to generate a current signal, where the current signal includes at least a first portion comprising a contribution to the current signal from a predefined source (i.e. a source of interest) and/or a second portion comprising a contribution to the current signal from one or more sources other than the predefined source, such other sources referred to herein as “ambient sources.” The detection system further includes a current detection module configured to receive the current signal generated by the sensor and generate a digital value indicative of the first portion of the current signal and/or a digital value indicative of the second portion of the current signal.
Furthermore, the detection system also includes a mode switch configured to set the current detection module to operate in at least one of a first mode, a second mode, and a third mode. In the first mode, the current detection module is synchronized to the predefined source and is configured to generate the digital value indicative of the first portion (i.e. current detection module is configured to detect the contribution to the current signal from the source of interest, while cancelling, reducing, or rendering below the noise of the current detection module the contribution to the current signal from sources other than the source of interest). In the second mode, the current detection module is configured to generate the digital value indicative of at least the second portion (i.e. the current detection module is configured to only detect the contribution to the current signal from the ambient sources) when the contribution to the current signal from the one or more sources other than the predefined source is in a first range of values. In the third mode, the current detection module is configured to generate the digital value indicative of at least the second portion (i.e. the current detection module is configured to only detect the contribution to the current signal from the ambient sources) when the contribution to the current signal from the one or more sources other than the predefined source is in a second range of values, the second range of values having an upper end higher than an upper end of the first range of values (i.e. ambient sources cause larger currents).
It should be noted that, in various embodiments, both the first and second portion need not always be present (e.g. the source of interest may be off, or there may be no or negligible amount of contributions from the ambient sources), and, if both present, not always do both need to be measured. Furthermore, in some embodiments of the second and third modes, the current detection module may be configured to generate the digital value indicative of not only the second portion but also the first portion (i.e. the current detection module is configured to detect the contribution to the current signal both from the source of interest and ambient sources).
As will be appreciated by one skilled in the art, aspects of the present disclosure may be embodied in various manners—e.g. as a method, a system, a computer program product, or a computer-readable storage medium. Accordingly, aspects of the present disclosure may take the form of an entirely hardware embodiment, an entirely software embodiment (including firmware, resident software, micro-code, etc.) or an embodiment combining software and hardware aspects that may all generally be referred to herein as a “circuit,” “module” or “system.” Functions described in this disclosure may be implemented as an algorithm executed by one or more processing units, e.g. one or more microprocessors, of one or more computers. In various embodiments, different steps and portions of the steps of each of the methods described herein may be performed by different processing units. Furthermore, aspects of the present disclosure may take the form of a computer program product embodied in one or more computer readable medium(s), preferably non-transitory, having computer readable program code embodied, e.g., stored, thereon. In various embodiments, such a computer program may, for example, be downloaded (updated) to the existing devices and systems (e.g. to the existing current detection modules or controllers of such modules, etc.) or be stored upon manufacturing of these devices and systems.
Other features and advantages of the disclosure are apparent from the following description, and from the claims.
To provide a more complete understanding of the present disclosure and features and advantages thereof, reference is made to the following description, taken in conjunction with the accompanying figures, wherein like reference numerals represent like parts, in which:
Embodiments of the present disclosure are based on the use of a current detection module capable of differentiating and quantifying (i.e. measuring) the contribution to the current signal generated by a certain source of interest from contributions from sources other than the predefined source of interest, i.e. ambient sources. As long as the contribution to the current signal from the predefined source comprises a pulsed signal (referred to in the following as “pulse(s) of interest”), the current detection module is configured to synchronize itself to the pulse(s) so that there is a predetermined phase relationship between the pulse(s) and functions carried out by various stages of the current detection module (referred to in the following as a “receiver circuit”). The pulsed signal of the source of interest may include one pulse or multiple pulses, where a pulse may include one or more frequency components. Ambient sources may also contain multiple frequency components, possibly even the same components as those of the pulse of the predefined source of interest. Because the frequencies present in the pulse(s) of interest are synchronized to the receiver circuit (i.e. synchronized to the clock of the current detection module), there is a certain known phase relationship between the current detection module and each of the frequency components of the pulse of interest (which phase relationship could be different for different frequencies in the pulse of interest, but nevertheless known ahead of time). The current detection module is designed to detect pulses synchronously and in a way that requires precise phase relationship between the receiver circuit and the source of interest. While the ambient sources may contain the same frequency components as the source of interest, the ambient sources are unlikely to contain precisely the same amplitudes and phases that make up the pulses of interest (i.e. ambient sources are unlikely to be synchronized to the current detection module). As a result, frequencies present in the ambient are averaged out even if the ambient sources contain very similar or the same frequencies as the pulse of interest.
Much of prior art approaches where it is desired to detect and measure contribution from a predefined source of interest from all other possible sources is based on avoiding interference with the ambient source by choosing a frequency of the source of interest to be different than the frequencies present in the ambient. Inventors of the present application realized that such approaches are not always successful because the content of the ambient is often unpredictable. Inventors of the present application further realized that by synchronizing the receiver circuit to the pulses of the signal of interest, it is possible to detect and measure contributions from the source of interest in presence of contributions from one or more ambient sources without having to choose frequencies for the pulses of the signal of interest that are different from the ambient (i.e. the frequency components could be the same).
An exemplary current detection module and functionality of such a module is now described in greater detail with reference to measurement of photocurrent signal generated by a photodiode in response to detecting light from a light source (i.e. for the example that the current detection module is used to detect photocurrent). However, teachings provided herein are equally applicable to current detection modules configured to detect currents generated by sensors, or charge generators, other than photodiodes, such as, but not limited to, pyro-electric, piezo-electric, or capacitive sensors. For all of these sensors (i.e. some kind of charge generators), a general setting described below for photodiodes is applicable where a sensor generates a current signal that may contain contributions from what may be considered as two “sources.” One “source” is a particular source of interest (i.e. the sensor sensing some event of interest—e.g. light generated by a particular LED as detected by a photodiode, change in temperature due to a particular source of interest detected by a pyro-electric sensor, mechanical deformation caused by a particular force/source of interest as detected by a piezo-electric sensor, touch by e.g. a human or a stylus as detected by a capacitance sensor, etc.). The other “source” may be considered to include everything else besides the source of interest that may cause the change in the charge state of the sensor. Such a source is referred to as an “ambient source.” In other words, the same sensor that senses contributions from the source of interest may also (or instead of, in case the source of interest is not providing any contribution) sense other things—e.g. the photodiode may detect ambient light, the capacitance sensor may sense touch that is not by a human or a stylus, etc. One common goal for all of these sensors may be to be able to distinguish and quantify these separate contributions to the current generated by the sensors.
Referring now to the example of a photodiode as a sensor, some embodiments of the present disclosure provide for measurement of photocurrent signal from a light source, which may be synchronized (e.g., specifically modulated).
Common photodiode circuits (e.g., photodiode amplifiers) are typically configured for one of low noise, wide bandwidth, and high dynamic range. Such circuits do not generally provide all three characteristics (low noise, wide bandwidth, and high dynamic range) simultaneously. Even if some circuits do provide all three characteristics, such circuits may require high power, or may not provide for high signal extraction of a target light source (especially in the presence of a high amount of ambient light, which is considered an interference and acts like noise), or may not be flexible to accommodate different sampling modes or multiple channels.
For example, Burr Brown's OPT201 integrated photo-diode and amplifier provides low noise operation, but does not have any means to distinguish between different types of light sources. In another example, New Focus Inc.'s 1601 and 1611 high-speed photo-receivers have large gain bandwidth (GBW), low noise, high drive capability and large dynamic range to enable wide bandwidth low-noise detection of signals distributed over fiber-optic cables, or found in applications such as high resolution spectroscopy, fiber-optic sensors, and optical metrology. The photo-receivers consist of a silicon or InGaAs PIN photodiode followed by a low-noise amplifier. However, these photo-receives are not capable of sampling multiple channels, and are designed such that there is no need to distinguish between different types of light that fall on the sensor—predefined source of interest and the ambient.
Turning to
According to various embodiments, electrical circuit 10 can provide the following features substantially simultaneously: low noise, high dynamic range, high rejection of uncorrelated ambient sources, high signal extraction of a locked or target source (i.e. the source of interest), low power operation, and flexibility for different sampling modes. Furthermore, electrical circuit 10 can allow for simultaneous sampling of multiple channels for analog-to-digital conversion, improve ambient signal rejection in the first mode, and measure ambient signal in the second mode. One example is ambient light rejection (ALR) in the first mode when a sensor is a photodiode. Multiple channels are serviced by a single and often more precise analog-to-digital converters (ADCs) while maintaining simultaneous measurement on all channels.
According to a specific embodiment, electrical circuit 10 may comprise a sensor 12 that detects a stimuli from a target source of interest 14, e.g. a photodiode 12 that receives light from a light source 14. The current signal generated by the sensor 12 can include a single pulse of low duty cycle or a multiple pulse train of low duty cycle (e.g., depending on the duty cycle of target source 14). In some embodiments, the target source 14 may be modulated by an integrated circuit (not shown) coupled to electrical circuit 10.
According to various embodiments, electrical circuit 10 can comprise four stages 16, 18, 20, and 22. Stage 16 can include a trans-impedance amplifier (TIA), which may amplify the current signal from the sensor 12 and generate a low noise signal. The trans-impedance amplifier can also convert the current signal to a voltage at the output. Stage 16 includes a feedback capacitance 24 (CO in parallel with a feedback resistor 26 (Rf) connected to an operational amplifier (op-amp) 28 in an R-C feedback loop, for example, to reduce noise and stabilize the circuit.
Any source of interest 14 (including DC source, e.g. DC light for the example of a sensor being a photodiode) whose bandwidth is within the amplifier bandwidth may be amplified by amplifier 28. Generally, capacitance of a sensor can affect noise gain based on the relative value of the capacitance to resistance value Rf of feedback resistor 26 and capacitance value Cf of feedback capacitor 24. Configuring stage 16 as a first stage can provide increased flexibility to minimize excess noise gain. In a general sense, two dominant noise sources in electrical circuit 10 include Johnson noise of feedback resistor 26 and amplifier 28's input voltage noise. To reduce Johnson noise, resistance value Rf of feedback resistor 26 can be chosen to be as large as possible consistent with the largest DC current that is expected for a given arrangement of sensor 12 and other components. Such a configuration may provide minimum amplifier noise consistent with the total DC current. Capacitance value Cf of feedback capacitor 24 can be chosen to change the bandwidth of the current signal (which may be of the order of approximately 1/τ, where τ refers to the input pulse duration) as desired. Stage 16 can also include a low pass filter (LPF) 30 that additionally filters out high frequency noise in the photocurrent signal. LPF 30 can also increase the duration of pulses of the current signal generated by sensor 12 (which may coincide with the pulse duration of the (synchronized) target source 14). The frequency threshold of LPF 30 can be configured as desired based on particular needs depending on the expected (or measured) noise characteristics.
Stage 18 may comprise a high pass filter, active or passive, with frequency fac, and a capacitor that provides AC coupling. Stage 18 can eliminate low frequencies (e.g., remove DC) and allow high gain to be provided in subsequent stages. The pulsed output from the stage 16 is filtered by having low frequency components removed by stage 18, thereby providing a zero cross-over point where the amplitude of the current signal changes from positive to negative. Stage 18 can eliminate some of the noise components from stage 16 and high frequency noise and lower frequency currents from ambient signal (e.g. ambient light) or uncorrelated ambient sources.
In some embodiments, a square pulse shaped signal from target source 14 may be modified by the filtering action of LPF 30 and stage 18 to eliminate low frequencies. The corner frequencies (e.g., boundary in the frequency response at which energy flowing through begins to reduce (attenuate or reflect)) of stages 16 and 18 may be chosen to maximize signal measurement and provide ALR. For example, the corner frequency of the high pass filter of stage 18 can be set as large as 0.5/τ. The choice can also be influenced by the integration time chosen in next stage 20.
Stage 20 may comprise integration and demodulation. A single pole changeover switch 34 may switch the incoming signal based on a clock from timer 36. The clock cycle of timer 36 may be configured to match the zero cross-over point of the photocurrent signal from stage 18. When the zero cross-over point occurs, switch 34 may switch from integrating amplifier 38(1) to integrating amplifier 38(2). Two integrating amplifiers 38(1) and 38(2) may be used to integrate in succession on the positive portion of the signal from stage 18 when switch 34 is connected to the positive integrating amplifier 38(1) and on the negative portion of the signal from stage 18 when switch 34 is connected to the negative integrating amplifier 38(2). Each of positive integrating amplifier 38(1) and negative integrating amplifier 38(2) may include a capacitor Cint configured to enable the operational amplifier therein to operate as an integrator. In some embodiments, switches SW2 may be used to reset positive integrating amplifier 38(1) and negative integrating amplifier 38(2), for example, after every conversion cycle or after multiple integration phases.
Each of positive integrating amplifier 38(1) and negative integrating amplifier 38(2) (generally referred to individually as an “integrator” 38) acts like a storage element that produces an output voltage output proportional to the integral of its input current (converted from voltage output of the previous stage) over time. In other words, the magnitude of the output voltage is determined by the length of time (integration period tint) during which an input voltage is present as the current through the feedback loop (comprising Cint) charges or discharges capacitor Cint. The circuit operates by passing a current that charges capacitor Cint over time from the input current of stage 18. When the input current of stage 18 is firstly applied to the integrator, the feedback capacitor Cint begins to charge and the output voltage is determined by the total charge (which is the integral of the input current over time).
Positive integrating amplifier 38(1) may generate a positive integrated value 40 (Q+), which is the integral over time of the positive amplitude of the alternating current signal from stage 18, and negative integrating amplifier 38(2) may generate a negative integrated value 42 (Q−), which is the integral over time of the negative amplitude of the alternating current signal from stage 18. The integration period tint can be configured over a wide range based on particular needs. The start of the integration cycle may be controlled by timer 36 in a microcomputer, a simple programmable circuit, or other suitable component. The gain of the amplifier can be chosen to optimize conversion by an analog-to-digital convertor (ADC) 44 (as DC and low frequency components of ambient light are largely removed after stage 18) at stage 22. At the end of the positive and negative integration cycle, substantially all currents in the integration period tt may be integrated and the voltage may be held at the outputs of stage 20. The voltages may be subtracted either before conversion by a difference amplifier or converted by ADC 44 and then subtracted digitally.
Mathematically, the integration and subtraction are similar to a low pass filter and a “lock-in” filter to further remove noise artifacts of the ambient sources while amplifying the current signal. For example, the phase of switch 34 can be adjusted to provide “lock-in” functionality to a signal originating from a distant system. Assume, merely for illustrative purposes, and not as a limitation, that a distant light source produces a train of N pulses repeating at a rate R. Timer 36 can be configured to lock to the phase of the clock that generates the N pulses. Thus a phase lock loop can be constructed to measure the light intensity of the distant light source. Positive integrating amplifier 38(1) and negative integrating amplifier 38(2) can together provide increased ALR. Outputs 40 and 42 may be fed to ADC (or ADC integrated with a micro-controller) 44 at stage 22 to perform further operations.
ADC 44 can read the output voltage of stage 20 and a controller therein can reset integrators 38(1) and 38(2), for example, by momentarily closing SW2, to start a new integration cycle. The reset can occur at the end of each pulse or at the end of a group of pulses. The voltage at stage 20 may represent a signal charge deposited at the sensor 12 as a result of detecting stimuli from the target source 14 in addition to charge from substantially all ambient interference. In an example embodiment, the pulses may be added together thereby increasing signal strength and reducing noise and interference digitally after ADC 44. In another example embodiment, the pulses may be added in an analog domain until SW2 resets integrating capacitors Cint. Embodiments of electrical circuit 10 can permit extension of the circuit architecture to ultra short pulses, for example in nanosecond and picosecond domain, without substantially increasing the speed of ADC 44. High dynamic range may be facilitated as digital additions of pulses can be carried out over many more pulses, almost without limit, than any analog addition on the integrating capacitors Cint would permit.
According to various embodiments, i nput current generated by sensor 12 may be converted to voltage at stage 16. Any frequency content of the voltage signal may be shaped by the band pass filtering functions at state 18. The output voltage of stage 18 may be converted back to current, for example, using a suitable resistor, and integrated with capacitor Cint over time tint over positive and negative cycles. At least a portion of the behavior of electrical circuit 10 may be indicated by the following equations:
where VTIA is the output voltage at stage 16; ip is the current from sensor 12 (e.g. photovoltaic current for the example of sensor 12 being a photodiode); Rf is the resistance of feedback resistor 26; Vac is the output voltage at stage 18; BPF(ffilt) is a bandpass filter shaping function of stage 18; Vint is the output voltage at stage 20; Rin is the resistance of a resistor (not shown) at stage 20; Cint is the capacitance at stage 20; and tint is the integration time.
For example, Rf may be chosen to prevent saturation at stage 16 with a high amount of low frequency ambient sources, such as e.g. sunlight. The corner frequencies can be chosen to minimize interference while transmitting most of the signal pulse at stage 18. Moreover, the choice of Rin and Cint can allow signal gain at stage 20 to match ADC input range at stage 22. Further, multiple cycles of analog integration over many pulses with digital integration at ADC 44 can allow a large dynamic range.
In some embodiments, an intense short pulse produced by target source 14 may perform better for low power operation as the system of amplifiers and ADC can be powered down between the pulses. Also, for the same net power consumed by synchronous target source 14, signal-to-noise-ratio (SNR) can be maximized by using the shortest possible pulse that can be produced by a driver circuit. (The shortest possible pulse may be limited by the peak current output available.) Electrical circuit 10 may be dynamically or programmatically configured in some embodiments, for example, by changing the Cf, Rf, Cint, and other passive component values and corner frequency values as desired.
In some embodiments, the low frequency (e.g., DC) component of the current signal generated by sensor 12 may be measured by directly connecting stage 16 to the input of ADC 44. Alternatively, the low frequency component may be measured by connecting stage 16 to either positive integrating amplifier 38(1) or negative integrating amplifier 38(2) of stage 20. In embodiments with low levels of ambient signals, one of positive and negative integrating amplifiers 38(1) and 38(2), respectively, may be connected directly to sensor 12, bypassing stages 16 and 18.
According to various embodiments, at least some components of stages 16, 18, and 20 are programmable (e.g., component values adjustable according to user specifications) after electrical circuit has been implemented in a physical form. The component values may be programmable manually, or by a suitable computing device or controller. For example, capacitance Cf of feedback capacitor 24, resistance Rf of feedback resistor 26; bandpass filter shaping function BPF(ffilt), resistance Rin, capacitance Cint etc. can be programmed according to the application in which electrical circuit 10 is to be used. Thus, the same physical representation of electrical circuit 10 may have a first set of component values in one application (e.g., photoplethysmography (PPG) system used in controlled ambient light) and a different, second set of component values in a different application (e.g., wireless sensor used in uncontrolled ambient light).
Turning to
Turning to
Turning to
Graph 80 was generated using 16 pulses, and the input referred integrated current (after stage 22) was calculated as charge on the Y-axis. According to embodiments of electrical circuit 10, ALR of almost a factor of 100 at frequencies below 50 kHz may be observed. Many ambient light sources such as fluorescent lamps and light emitting diode (LED) lights have components at low frequencies. Very low frequencies such as 120 Hz may be suppressed by factors exceeding 1000 and DC light may be completely blocked.
It may be noted that embodiments of electrical circuit 10 may reject electrical noise injected at sensor 12 similar to rejection of currents generated by ambient sources. Indeed, components of electrical circuit 10 may not distinguish between currents generated by the sensor in response to stimuli of ambient sources or electromagnetic interference (EMI) or any other electrical noise injected into the circuit, facilitating robustness in the presence of both electrical interference and interference due to detection by the sensor of ambient source (e.g. optical interference for the example of sensor 12 being a photodiode).
Turning to
The pulse oximeter of application 90 may include photodiode 12 and synchronous light source (e.g., red and infrared light emitting LED) connected to photoplethysmography system 92, which can include electrical circuit 10 and other components, based on the particular application need. The pulse oximeter may be attached to, or otherwise placed in proximity with an organ (e.g., fingertip, wrist, etc.) 94 (e.g., of the patient whose pulse is being monitored). Light emitted by synchronous light source 14 may be partially reflected, transmitted, absorbed, and/or scattered by the organ (e.g., skin, surrounding tissues, and the blood at the fingertip) before it reaches photodiode 12. The photocurrent signal from photodiode 12 can provide a measurement of the organ, for example, indicative of pulse rate, or oxygen content, etc.
Currently available pulse oximeters and other photoplethysmography systems use caps, light proof enclosures, and other such devices to prevent ambient/background light from generating noise in the photoplethysmography systems. With electrical circuit 10, such light blocking enclosures (e.g., caps, boxes, etc.) need not be used, as electrical circuit 10 includes noise reduction capabilities sufficient to overcome ambient and other background light noise. Moreover, because of the noise reduction characteristics of electrical circuit 10, and its consequent reduced sensitivity to ambient and DC light, the distance between synchronous light source 14 and photodiode 12 may be configured based on convenience factors, rather than noise reduction.
Turning to
Moreover, the output from stage 20 can remain constant after the integration phase until reset, ADC 44 can be multiplexed to sample each of the outputs without compromising performance. Thus embodiments of electrical circuit 10 can allow a relatively lower cost low speed ADC with low frequency switching between channels can be used without compromising performance. Such circuit architecture can be used in specialized sensor applications, for example, that use lateral photodiodes, quad detectors, or optical angle sensors in context of a sensor being a photodiode. With the circuit architecture of embodiments of electrical circuit 19, pulse width of the input light and substantially all components of stages 16, 18, and 20 can be configured with nanosecond pulses without substantially affecting ADC 44's sample rate.
Turning to
Turning to
To summarize the above description, an example electrical circuit is provided and includes a sensor (e.g. a photodiode) that receives a signal (e.g. light signal) from a target source (e.g. a target light source) and generates a current signal (e.g. a photocurrent signal), a trans-impedance amplifier that amplifies the current signal and generates a low noise signal, and a high pass filter that converts the low noise signal into an AC signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude. The electrical circuit also includes a positive integrating amplifier that receives the positive amplitude of the AC signal and generates a positive integrated value over an integration period, and a negative integrating amplifier that receives the negative amplitude of the AC signal and generates a negative integrated value over the integration period. The electrical circuit further includes at least one ADC that receives the positive and negative integrated values.
In a specific embodiment where the sensor is a photodiode, the electrical circuit is coupled to a photoplethysmography system. Light from the light source reflects off, or transmits through an organ before reaching the photodiode, such that the photocurrent signal from the photodiode can provide an indication of a measurement of the organ. The photoplethysmography system does not have to include a light blocking enclosure to keep out ambient light for accurate measurements.
A system is also provided that includes a plurality of sensors (e.g. photodiodes) that receive one or more signals from one or more target sources (e.g. light sources), with each one of the sensors generating a current signal, a plurality of trans-impedance amplifiers, in which each trans-impedance amplifier amplifies the current signal from one of the sensors and generates a low noise signal, a plurality of high pass filters, in which each high pass filter converts the low noise signal from each trans-impedance amplifier into an AC signal having a positive amplitude, a negative amplitude, and a zero cross-over point between the positive amplitude and the negative amplitude and a plurality of integrators. Each integrator includes a positive integrating amplifier that receives the positive amplitude of the AC signal from each high pass filter and generates a positive integrated value over an integration period, and a negative integrating amplifier that receives the negative amplitude of the AC signal from each high pass filter and generates a negative integrated value over the integration period. The system further includes an ADC that receives the positive and negative integrated values from the plurality of integrators.
Using Current Detection Module with Mode Switching
Embodiments of the present disclosure are further based on the recognition that a current detection module as described above may be re-used to not only detect and quantify contribution to the current signal from a predefined, target, source of interest, but also provide high precision detection and quantification of contributions to the sensor-generated current signal from sources other than the predefined source. To that end, a detection system is provided that implements the current detection module as described above and further allows mode switching where, depending on the mode of operation being selected, the current detection module is configured to perform different kinds of measurements.
Current detection module 126 could be implemented as electrical circuit 10 described above.
Sensor 122 could be implemented as sensor 12 described above, which could be e.g. a photodiode, a pyro-electric sensor, a piezo-electric sensor, or a capacitive sensor. In general, sensor 122 may be considered to be a device comprising one or more charge collecting/generating capacitive elements, as shown in
Sensor 122 is configured to detect stimuli, shown in
Mode switch 124 is configured to control operation of current detection module 126 in order to use the same current detection module 126 to perform different measurements in the following modes. In each of what is referred to as a “first mode” and a “fourth mode” described herein, current detection module 126 is configured to detect contribution from the source of interest 128. The first and fourth modes differ in how exactly such contribution is detected. In each of what is referred to as a “second mode” and a “third mode” described herein, current detection module 126 is configured to detect contribution from the ambient source 130. The second and third modes differ in which ranges of signal intensity generated by ambient source 130 may be correctly measured. In particular, the second mode may be used to detect contributions from ambient sources is in a certain first range of amplitudes, while the third mode may be used to detect contribution in a higher range of amplitudes (which amplitudes could oversaturate sensor 122 resulting in incorrect measurement if measured in the second mode). In order to control different modes of operation, mode switch 124 may be configured to ensure that one or more of sensor 122, current detection module 126, and target source 128 are synchronized (which synchronization is described in more detail below), as shown in
In various embodiments, functionality provided by mode switch 124 may be implemented different manners—e.g. in software, hardware, a combination of software and hardware, etc.
Turning to
According to a specific embodiment, circuit architecture 150 may comprise a sensor 152 that detects a stimuli from a target source of interest 154, e.g. a photodiode 152 that receives light from a light source 154. Circuit architecture 150 may further include current detection module 160 comprising four stages (indicated in
Comparison of
Optionally, circuit architecture could include circuitry 180 for using measurements of the circuit 160 in further digital signal processing, e.g. for gesture and/or proximity determinations. Optionally, circuit architecture may be configured to work with more than one target source, as shown with LED2 184. Further, photodiode 152 may be connected to switch 200 for management of photodiode bias, which switch may be shorted during the times the photodiode is off.
In an embodiment, logic signals sent to the LED driver to pulse the target LED 154 (or any other target source) can be simply directed to the switch 172 so that it pulses similar to the LED. This is shown as “PD switching” switch that directs LED pulse signals to the switch 172.
Mode switch 170 may be used to switch between measuring signals from the target source 154 and measuring integrated ambient charge. In one embodiment, as shown in
In a first mode (normal mode), mode switch 170 is used as a bypass to connect the output of sensor 152 to TIA 188 of the first stage of the current detection module 160 and is primarily used to measure the response to an LED pulse, in the same manner as described above with reference to electrical circuit 10 (therefore, all of the discussions provided above for circuit 10 are applicable here). The response of the rest of the circuit is illustrated in
As mentioned above, in the first mode, current detection module 160 can provide two levels of protection from ambient light. First, low DC light is reduced or blocked in stage 2. Then, positive and negative integrations by the integrator of stage 3 further reduce or block any remaining ambient light. Thus, the architecture 150 allows cancelling ambient signals without contributing additional computational load to the circuit. As used herein, in this context, the term “cancelling” refers to cancelling ambient signals, reducing ambient signals, or rendering ambient signals below the noise of the current detection module.
Thus, the mode switch 170 is used as a bypass and the rest of the circuit architecture cancels ambient light. In one example, pulsed LED light falls on the mode switch 170.
The timing diagram for the first mode is illustrated in
Values of the stimulus generated by the target source (e.g. width of the LED pulse) as well as various circuit elements of the current detection module, such as e.g. bandwidth of the TIA 188, corner frequencies of the BPF 190, etc., define the time delay (shown in
It should be noted that the timing diagram for the first mode illustrated in
In a second mode (which could be referred to as a “floating” sensor mode), one goal is to measure the ambient contributions only. In such a case, there is no natural pulsing of ambient sources, as was the case with the pulsed target source 154, (because, unlike target sources that may be controlled, ambient sources are typically not controlled). However, in this mode, the mode switch 170 may be operated in such a way that the sensor 152 itself can be used as the integrator, artificially generating what looks, to the current detection module 160, as a current pulse similar to that generated in the first mode when LED pulse is detected. To that end, capacitance associated with the sensor 152 (e.g. the designated capacitive elements as well as parasitic capacitive elements as shown in
The cycle of the second mode may begin by the mode switch 170 ensuring that the output of sensor 122 is not connected to anything (this may be achieved e.g. by having mode switch in position 144 illustrated in
At the time the mode switch 170 is open, signals generated by one or more ambient sources are detected by the sensor 152, resulting in the sensor 152 generating charge on the capacitors of the sensor. Target sources 154 may be off (i.e. not generating signals that are detected by the sensor 152), as shown in the second row of
After this certain time period, the mode switch 170 connects the output of sensor 152 to the current detection module 160, as shown in the first row of
Thus, in the second mode of operation of the current detection module 160, providing an artificially generated current pulse to the current detection module 160 (by means of the mode switch 170) allows benefiting from the synchronization between the elements provided by the module to accurately measure the pulse. In this mode, because the pulse is generated as a result of the sensor 152 detecting contributions from the ambient sources only (target sources were off), the value generated by the current detection module is representative of contributions to the sensorgenerated current signal due to the ambient sources. In other words, a current pulse artificially generated in the second mode, when integrated, directly represents the total accumulated charge and hence the strength of the ambient.
In some embodiments of the second mode, stage 2 (i.e. BPF 190) of the current detection module 160 may be removed/bypassed because in this mode it is not necessary to eliminate low frequency/DC contributions typical of ambient light in the first mode. Thus, the current pulse shaped by the TIA 188 may be integrated directly, without passing through the BPF stage. In such embodiments, the timing of the integration switch may be adjusted to include the entire integration of the pulse in the positive or the negative cycle. When the second stage is bypasses, zero-crossing point is defined in the output of the TIA 188.
The switching integrator stage (stage 3) is maintained in the second mode. The positive-negative cycle removes many integrator offsets. If the integration time on the sensor (i.e. the time the sensor 152 is floating) is τ and contributions from the ambient sources result in sensor 152 generating current iamb, the total charge Q=iambτ can be measured by the detection system as described herein with high SNR by simply increasing the floating time until the charge accumulated on the sensor 152 is greater than the measurement noise floor.
In some implementations, internal leakage currents may limit the floating time. For example, for a relatively large photodiode of 100 μm in size, one lux of light will make for roughly 4-5 pA of current, which, when integrated for 1 ms, results in 8 fC of accumulated charge that can be measured.
As the foregoing illustrates, the same current detection module can be used to either measure contributions from the ambient sources or contributions from synchronous pulse(s) generated by a target source.
In an embodiment, mode switching functionality used to create a pulse in the ambient input as described for the second mode may be implemented with the mode switch 170 comprising the switches 172 and 174. In such an embodiment, the first switch 172 may be connected to the second switch 174. When the second switch 174 is open, the charge from the sensor 152 has nowhere to go and the mode switch 170 integrates the accumulated charge on the sensor. Then the second switch 174 is closed to the TIA 188, and the charge is transmitted through to the TIA 188 like a pulse of target source in the first mode. In this manner, ambient signals are captured and turned into pulsed signals. The pulses are then processed by the rest of the circuit in the same manner as the target source pulses were processed in the first mode.
A third operating mode may also be used to measure ambient contributions only, but this mode may be used particularly advantageously in a presence of fairly strong contributions from ambient sources (e.g. in presence of strong ambient light). In such situations, it may be undesirable to integrate the charge on the sensor 152 as was done in the second mode because, when ambient contributions are strong, such integration is likely to lead to saturation of the sensor 152 (i.e. reaching the maximum amount of charge that the capacitive elements of the sensor 152 are able to hold) in a very short amount of time. A saturated sensor cannot produce accurate measurements because it is clipped at the maximum values. This mode of operation may also be advantageously used with certain types of sensors that may function better when the voltage remains constant during the measurement, e.g. pyro sensors biased at a constant voltage and photodiodes for measuring intense light. In all these situations, it may be desirable to measure the current generated by the sensor 152 directly, without integrating the charge on the sensor as was done in the second mode. In such situations, the mode switch 170 can be used, again, to effectively generate what looks like a current pulse that can be processed by the current detection module 160. Thus, similar to the second mode, in the third mode, there is no natural pulsing of ambient sources but the mode switch 170 may be operated to artificially generate what looks, to the current detection module 160, as a current pulse similar to that generated in the first mode when LED pulse is detected. The rest of the architecture of the current detection module 160 may then be used in a manner analogous to how a current pulse was processed in the first mode because it is the receipt of this current pulse by the current detection module that defines the timing of other operations and elements of the current detection module (i.e., as in the second mode, it is possible to benefit from the synchronization between the elements provided by the module to accurately measure the pulse).
In the third mode, at certain times (shown in
At certain other times (shown in
Thus, in the third mode, the mode switch 170 is configured to effectively generate what looks like a current pulse from a constant stimulus arriving at the sensor 152. This is done by pulsing the mode switch 170 to connect for a specific amount of time to the amplifier's input (tpulse) and otherwise the sensor 152 remains connected to a fixed reference voltage, e.g. to the common mode voltage of the amplifier through the switch 174 shown in
In one embodiment, the third mode described herein could be modified by measuring sensor node between two different reference voltages, thereby measuring the changes to the sensor itself as the voltage is pulsed. This embodiment may be implemented in the same manner as the third mode described above, except that, at times shown in
A fourth operating mode, illustrated in the timing diagram of
After that, the sensor 152 is floating again for a certain time period (shown in
In some embodiments of the fourth mode, the mode switch 170 may be disconnect the output of the sensor 152 from the TIA 188 immediately following the discharge of the sensor 152 in the first current pulse, as shown in
Considerations provided above for the second mode are applicable, except for the differences in that target source is sometimes on, to the fourth mode, and, therefore, are not repeated here. In particular, in the fourth mode (as well as in the third mode), in some embodiments, the second stage (BPF) of the current detection module 160 may be bypassed and the output of the TIA 188 may be presented directly to the integrator stage.
The fourth mode may be particularly advantageous for situations where ambient light is weak or has low modulation frequency compared to pulse width, in which cases the fourth mode can provide enhanced SNR when compared to multiple pulses in the first mode.
The four modes described above are summarized in the table in
For the example of sensor 152 being a photodiode, according to various implementations, the LED light can be any color. For example, a red or a green LED light may be used. Similarly, the LED pulse width can be any selected width, and in one example, the LED pulse width is about 3 μs. In other examples, the LED pulse width is less than about 3 μs, or more than about 3 μs. Pulse width of few ns to 100's of microsecond is a typical range for LED pulsewidths. The measurements can be repeated first as a burst of pulses, which are themselves repeated at various rates ranging from 0.01 Hz to many kHz.
In other embodiments when sensor 152 is a photodiode, the target light source could be any controllable light source, not necessarily a LED. Thus, target light sources could be, but are not limited to, e.g. laser diodes, high/low pressure gas discharge sources, inorganic/organic light emitting diodes, incandescent sources, halogen sources, etc.
Variations and Implementations
Note that in this Specification, references to various features (e.g., elements, structures, modules, components, steps, operations, characteristics, etc.) included in “one embodiment”, “example embodiment”, “an embodiment”, “another embodiment”, “some embodiments”, “various embodiments”, “other embodiments”, “alternative embodiment”, and the like are intended to mean that any such features are included in one or more embodiments of the present disclosure, but may or may not necessarily be combined in the same embodiments.
In one example embodiment, parts or entire electrical circuits of the FIGURES may be implemented on a motherboard of an associated electronic device. The motherboard can be a general circuit board that can hold various components of the internal electronic system of the electronic device and, further, provide connectors for other peripherals. More specifically, the motherboard can provide the electrical connections by which the other components of the system can communicate electrically. Any suitable processors (inclusive of digital signal processors, microprocessors, supporting chipsets, etc.), memory elements, etc. can be suitably coupled to the motherboard based on particular configuration needs, processing demands, computer designs, etc. Other components such as external storage, additional sensors, controllers for audio/video display, and peripheral devices may be attached to the motherboard as plug-in cards, via cables, or integrated into the motherboard itself.
In another example embodiment, parts or entire electrical circuits of the FIGURES may be implemented as standalone modules (e.g., a device with associated components and circuitry configured to perform a specific application or function) or implemented as plug-in modules into application specific hardware of electronic devices. Note that particular embodiments of the present disclosure may be readily included in a system on chip (SOC) package, either in part, or in whole. An SOC represents an IC that integrates components of a computer or other electronic system into a single chip. It may contain digital, analog, mixed-signal, and often radio frequency functions: all of which may be provided on a single chip substrate. Other embodiments may include a multi-chip-module (MCM), with a plurality of separate ICs located within a single electronic package and configured to interact closely with each other through the electronic package. In various other embodiments, the amplification functionalities may be implemented in one or more silicon cores in Application Specific Integrated Circuits (ASICs), Field Programmable Gate Arrays (FPGAs), and other semiconductor chips.
It is also imperative to note that all of the specifications, dimensions, and relationships outlined herein (e.g., the number of processors and memory elements, logic operations, etc.) have only been offered for purposes of example and teaching only. Such information may be varied considerably without departing from the spirit of the present disclosure, or the scope of the appended claims. The specifications apply only to one non-limiting example and, accordingly, they should be construed as such. In the foregoing description, example embodiments have been described with reference to particular processor and/or component arrangements. Various modifications and changes may be made to such embodiments without departing from the scope of the appended claims. The description and drawings are, accordingly, to be regarded in an illustrative rather than in a restrictive sense.
Note that with the numerous examples provided herein, interaction may be described in terms of two, three, four, or more electrical components. However, this has been done for purposes of clarity and example only. It should be appreciated that the system can be consolidated in any suitable manner. Along similar design alternatives, any of the illustrated components, modules, and elements of the FIGURES may be combined in various possible configurations, all of which are clearly within the broad scope of this Specification. In certain cases, it may be easier to describe one or more of the functionalities of a given set of flows by only referencing a limited number of electrical elements. It should be appreciated that parts or entire electrical circuits of the FIGURES and its teachings are readily scalable and can accommodate a large number of components, as well as more complicated/sophisticated arrangements and configurations. Accordingly, the examples provided should not limit the scope or inhibit the broad teachings of parts or entire electrical circuits as potentially applied to a myriad of other architectures.
Numerous other changes, substitutions, variations, alterations, and modifications may be ascertained to one skilled in the art and it is intended that the present disclosure encompass all such changes, substitutions, variations, alterations, and modifications as falling within the scope of the appended claims.
Although the claims are presented in single dependency format in the style used before the USPTO, it should be understood that any claim can depend on and be combined with any preceding claim of the same type unless that is clearly technically infeasible.
Deliwala, Shrenik, Koker, Gregory T., Decker, Steven J., Weinberg, Dan M.
Patent | Priority | Assignee | Title |
Patent | Priority | Assignee | Title |
5684294, | Oct 17 1996 | RPX CLEARINGHOUSE LLC | Proximity and ambient light monitor |
5739652, | Dec 20 1996 | Delphi Technologies, Inc | Method and apparatus for sensorless operation of brushless permanent magnet motors |
7960679, | Sep 25 2006 | SHANGHAI XUANYAN ELECTRONIC TECHNOLOGIES, INC | Photo detector array with thin-film resistor-capacitor network for use with a display device |
7978311, | May 09 2008 | Analog Devices, Inc. | Method of locating an object in 3D |
8692200, | Jan 06 2010 | AVAGO TECHNOLOGIES INTERNATIONAL SALES PTE LIMITED | Optical proximity sensor with improved dynamic range and sensitivity |
9130070, | Apr 25 2013 | Analog Devices, Inc | Four-stage circuit architecture for detecting pulsed signals |
9733275, | Jul 25 2014 | Analog Devices, Inc. | Circuit architecture for mode switch |
20050258885, | |||
20070080905, | |||
20090127461, | |||
20100087718, | |||
20110114842, | |||
20110163233, | |||
20110186714, | |||
20140285472, | |||
20140323844, | |||
20140323874, | |||
20150333712, | |||
20160025777, | |||
DE102014105398, | |||
KR101701560, | |||
KR11506544, | |||
WO2016015033, | |||
WO9818205, |
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