The smoke alarm market requires a variety of power supply platforms to fit the needs of a variety of applications, so that that smoke alarm suppliers often develop and sell different power supply versions of their products. Each platform uses a different hardware configuration by changing either discrete components or integrated circuit (IC) chips. Having multiple power supply options with the same components is desirable.
Disclosed embodiments provide an analog front end (AFE) chip for a smoke detector. The AFE chip can accept a wide range of power supply inputs while also supporting the 2020 UL requirements for smoke detectors. A pre-regulator on the AFE chip can accept a power supply input that has a voltage between about two (2) volts and about fifteen (15) volts and provide a safe voltage to other circuits on the AFE chip. This capability provides for the output of a DC/DC boost converter on the AFE chip to be coupled to the AFE power supply input. The DC/DC boost converter is default enabled, but can sense when a higher input voltage is provided and will turn off the DC/DC boost converter when not needed. These two capabilities provide for the AFE chip to be utilized with a variety of smoke detector power configurations.
In one aspect, an embodiment of an AFE chip for a smoke detector is disclosed. The AFE chip includes a DC/DC boost converter having a boost input, a boost output, and a boost upper power supply input, the boost input being coupled to a first pin, the boost output being coupled to a second pin, the first pin being adapted for coupling to a battery through an inductor, and the DC/DC boost converter being configured to not switch when a voltage on the second pin is greater than a programmed boost voltage; and a set of power regulator circuits having a power input and a power output, the power input being coupled to a third pin, the third pin being adapted for receiving an input voltage, the power output being coupled to provide an internal voltage to the digital upper supply input, the set of power regulator circuits being further coupled to the boost upper power supply input.
In another aspect, an embodiment of a smoke detection device is disclosed. The smoke detection device includes an AFE chip including a DC/DC boost converter having a boost input, a boost output, and a boost upper power supply input, the boost input being coupled to a first pin and the boost output being coupled to a second pin, and a set of power regulator circuits having a power input and a power output, the power input being coupled to a third pin, the third pin being adapted for receiving an input voltage, the power output being coupled to provide an internal voltage; and a trace that couples the second pin to the third pin.
In yet another aspect, an embodiment of a process of operating a smoke detector is disclosed. The process coupling an output pin for a DC/DC boost converter on an analog front end (AFE) chip to an input pin for a set of power regulator circuits on the AFE chip through a trace; and coupling a power supply to the AFE chip.
Embodiments of the present disclosure are illustrated by way of example, and not by way of limitation, in the figures of the accompanying drawings in which like references indicate similar elements. It should be noted that different references to “an” or “one” embodiment in this disclosure are not necessarily to the same embodiment, and such references may mean at least one. Further, when a particular feature, structure, or characteristic is described in connection with an embodiment, it is submitted that it is within the knowledge of one skilled in the art to effect such feature, structure, or characteristic in connection with other embodiments whether or not explicitly described. As used herein, the term “couple” or “couples” is intended to mean either an indirect or direct electrical connection unless qualified as in “communicably coupled” which may include wireless connections. Thus, if a first device couples to a second device, that connection may be through a direct electrical connection, or through an indirect electrical connection via other devices and connections.
The accompanying drawings are incorporated into and form a part of the specification to illustrate one or more exemplary embodiments of the present disclosure. Various advantages and features of the disclosure will be understood from the following Detailed Description taken in connection with the appended claims and with reference to the attached drawing figures in which:
Specific embodiments of the invention will now be described in detail with reference to the accompanying figures. In the following detailed description of embodiments of the invention, numerous specific details are set forth in order to provide a more thorough understanding of the invention. However, it will be apparent to one of ordinary skill in the art that the invention may be practiced without these specific details. In other instances, well-known features have not been described in detail to avoid unnecessarily complicating the description.
The smoke alarm market requires a variety of power supply platforms. Commercial smoke alarms and many residential smoke alarms utilize DC power derived from a mains power supply with battery power as a backup when the power supply is lost. For example, one power supply platform uses the combination of 12 V DC input and a 3 V backup battery. Other power supply platforms rely solely on battery power and can utilize a low voltage input, typically a 3 V battery, or a high voltage input, e.g., a 9-12 V battery. These three platforms require different power management configurations because smoke alarm functions require different voltages that can be both lower and higher than these input voltages. For example, a horn driver function requires 10-12 V, while the smoke chamber AFE requires 2-3 V.
Depending on the power supply for a specific platform, the smoke alarm typically has either a DC/DC boost converter to provide higher voltage from low input voltage or a buck converter to provide lower voltages from a high input voltage; some configurations use both. A DC/DC boost converter typically generates 10-12 V from a lower voltage input, e.g., 3 V, while a buck converter typically generates 2-3 V from a higher voltage input like 9 V or 12 V. Smoke alarm suppliers historically develop and sell different power supply versions of their products. Each platform uses a different hardware configuration, varying either discrete components or IC chips. This situation is not ideal, both because of the costs of development for multiple platforms and the need to stock each of the multiple platforms' components. Within these platforms, the AFE ICs for a smoke detector generally accept only a lower voltage input, e.g., up to 5 V, because the AFE typically works with 2-3 V.
Applicants have designed a single IC chip that integrates an AFE with the power management to support multiple power supply combinations; this IC chip may be referred to herein as an AFE chip. The power input for the AFE chip is designed to have a wide input range, e.g., between 2-15 V. At the same time, a DC/DC boost converter on the AFE chip is enabled by default and is designed to be coupled to the power input for the AFE. The power supply input for the AFE is received at a pre-regulator, which is designed to receive the high voltage and to provide a power output that is in the range of 4-5 V. The output of the pre-regulator provides power to the DC/DC boost converter and to additional voltage regulators that provide power to other elements of the smoke detector.
The combination of a pre-regulator able to receive high voltages and a default-enabled DC/DC boost converter whose output is coupled to the input of the pre-regulator provides for the AFE chip to function with multiple power configurations. Using this combination, the disclosed AFE chip is able to support power configurations that can include a low voltage (3 V) battery only platform, a high voltage (9 V) battery only platform and a platform that combines 12 V DC power with a 3 V battery backup.
Not only does the disclosed IC chip provide versatility for use with different power platforms, but the overall power requirements are low. Underwriters Laboratories (UL) provided new requirements for certification of smoke alarms in 2018, with implementation of the requirements to be completed by early 2020. These requirements include the ability for the smoke alarm to be powered from a 3-volt lithium battery for a ten-year life span of the smoke alarm, which imposes very strict limitations on power usage. The disclosed AFE chip supports this requirement.
DC/DC boost converter 102 has a boost input that is coupled to a first pin P1, a boost output that is coupled to a second pin P2 and a boost upper power supply input 110. First pin P1 can be coupled to a low-voltage battery, e.g., a battery that provides 3.0-3.6 V, although over time, the battery power can diminish to about 2 V and still provide power to AFE chip 101, attached sensors, and an attached MCU (not specifically shown in these figures). DC/DC boost converter 102 operates with a wide range of input and output voltages and can support multiple battery configurations and driver voltages. A programmed boost voltage VPGM can be set to indicate a desired boosted output voltage Vbst. DC/DC boost converter 102 provides a power-good signal BST_PG that can be sent to a register in the digital core (not specifically shown in this figure) to notify the MCU when the boost converter is above 95% of the programmed boost voltage VPGM. The power-good signal BST_PG is set low when the DC/DC boost converter 102 is disabled.
Several register bits can be used to control the activity of the DC/DC boost converter 102. A boost enable register bit BST_EN is set to “1” if DC/DC boost converter 102 is to be enabled and is set to “0” if DC/DC boost converter 102 is to be disabled. A boost sleep register bit SLP_BST can be set to “1” if the DC/DC boost converter 102 is to be disabled during a sleep mode, e.g., for low-voltage battery operation, and can be set to “0” if the DC/DC boost converter 102 is to remain unchanged during a sleep mode, e.g., when operating from an AC/DC converter. When the smoke detection device 100 is in a sleep mode, which will be explained in greater detail below, boost sleep register bit SLP_BST disables DC/DC boost converter 102 if the DC/DC boost converter 102 is enabled with boost enable register bit BST_EN. The boost charge register bit BST_CHARGE can enable the boost converter until the power-good signal BST_PG is high, at which point boost charge register bit BST_CHARGE resets to “0” and the DC/DC boost converter 102 is disabled. Other register bits can be used to enable the DC/DC boost converter 102 in cases where certain errors occur in pre-regulator circuit 104 or MCU LDO regulator 108.
The default enabled DC/DC boost converter 102 can support powering up from an AC/DC power supply that provides about 12 V and a backup battery that provides about 3 V. When the AC/DC power supply is connected and the power supply at second pin P2 is greater than the boosted output voltage Vbst, the DC/DC boost converter 102 does not switch and no power is drawn from the battery. When the AC/DC power supply is lost, the DC/DC boost converter 102 is automatically enabled and generates boosted output voltage Vbst from the battery voltage Vbat. If only a 3 V battery is connected, the default enabled DC/DC boost converter can provide the higher voltage. This guarantees that the power supply input for AFE chip 101 can be powered with high voltage when any of a battery, a 12 V DC power supply, or both are connected.
Pre-regulator circuit 104 has a pre-regulator input that is coupled to a third pin P3 and a pre-regulator output 112 that is coupled to the boost upper power supply input 110 and is also coupled to a fourth pin P4. As noted previously, pre-regulator circuit 104 can receive an input voltage Vcc that can range between about 2 V, e.g., during startup, and about 15 V. When the power supply input is less than about 4 V, pre-regulator circuit 104 will simply pass the input voltage Vcc on to the other circuits that use the power. Once the power supply input rises above about 4 V, the output of pre-regulator circuit 104 is regulated, with an output in the range of about 4 V to about 5.5 V.
Internal LDO regulator 106 has an internal-LDO upper power supply input 114 that is coupled to the pre-regulator output 112 and an internal-LDO output that is coupled to a fifth pin P5. During operation of internal LDO regulator 106, internal LDO regulator 106 receives the voltage provided by pre-regulator circuit 104, which is not as tightly regulated as needed by some of the internal circuits, and provides a well-regulated internal voltage Vint to analog blocks and to a digital core, which are not specifically shown in these figures. In one embodiment, the voltage provided by internal LDO regulator 106 is about 2.3 V.
MCU LDO regulator 108 has an MCU-LDO upper power supply input 116, an MCU-LDO output, and an MCU-select input 118. The MCU-LDO upper power supply input 116 is coupled to the pre-regulator output 112, the MCU-LDO output is coupled to a sixth pin P6, and the MCU-select input 118 is coupled to a seventh pin P7. In one embodiment, MCU LDO regulator 108 is also coupled to receive an MCU-voltage-setting signal VMCUSET 122 and an MCU-enable signal MCUENA 120. In one embodiment, MCU LCO regulator 108 can provide an MCU voltage Vmcu that can be set between about 1.5 V to about 3.3 V. The MCU-select input 118 and the seventh pin P7 are used to set an initial value of the MCU voltage Vmcu from a selection of possible settings, while MCU-voltage-setting signal VMCUSET 122 is stored in an internal register on AFE chip 101 (not specifically shown in this figure) that can be programmed by the MCU to a final voltage setting once the MCU is operating. MCU-enable-signal MCUENA 120 is an internal signal that can be used to signal when the MCU should be woken up after entering a sleep period. Similar to DC/DC boost converter 102, MCU LDO regulator 108 can be disabled during a sleep mode if an MCU sleep register bit SLP_MCU is set to “1” and can be left unchanged during the sleep mode if MCU sleep register bit SLP_MCU is set to “0”. If the MCU LDO 108 was enabled prior to sleep mode, the MCU LCO 108 is re-enabled when sleep mode is exited.
Taken as a whole, the set of power regulator circuits 113 has a power input and a power output. In the present embodiment, the power input is coupled to the third pin to receive input voltage Vcc and the power output is coupled within the AFE 100 to a number of analog blocks and to the digital core (neither specifically shown in this figure) to provide internal voltage Vint. The set of power regulator circuits 113 is also coupled to the boost upper power supply input 110. While
AC/DC converter 103 is coupled to the trace T1 through a second diode D2. It can be noted here that the voltage on second pin P2 is referred to as boosted output voltage Vbst herein, even when the DC/DC boost converter 102 is not supplying the power. This convention is used because the boosted output voltage Vbst on second pin P2 is provided through internal metallization layers to other circuits on AFE chip 101, e.g., a horn driver circuit and an interconnect I/O buffer (neither of which are specifically shown in this figure). When mains power is available, AC/DC converter 103 supplies a boosted output voltage Vbst that can be equal to or greater than the programmed boost voltage VPGM, e.g., about 11.5-15 V. The DC/DC boost converter 102 senses the voltage on second pin P2 and does not switch when the boosted output voltage Vbst is equal to or greater than the programmed boost voltage VPGM, so that no power is drawn from the battery. When mains power fails, the current provided by AC/DC converter 103 disappears. When the voltage drop is sensed, the DC/DC boost converter is automatically enabled and generates the boosted output voltage Vbst at the programmed boost voltage VPGM from the 3 V battery backup 105.
When the boosted output voltage Vbst is below the programmed boost voltage VPGM, a charging cycle is initiated. When the boosted output voltage Vbst is above the programmed boost voltage VPGM, the DC/DC boost converter does not switch. In a battery backup system, no power is drawn from the battery while the AC/DC converter is providing a boosted output voltage Vbst above the boost regulation voltage. The boost starts switching if the AC/DC supply drops, drawing power from the battery to regulate boosted output voltage Vbst. In one embodiment a boost timer BST_nACT monitors the time that the boost is not switching and notifies the MCU if the boost is inactive. Boost timer BST_nACT can be programmable, e.g., from 100 μs to 100 ms and can be used to determine if the power is being received from a battery having a voltage higher than the programmed boost voltage VPGM or from an AC/DC converter.
Several power-saving options have been incorporated into AFE chip 101. The pre-regulator circuit 104 is able to operate with only 2-3 V as a power supply, as are other circuits powered by the pre-regulator circuit 104. However, an attached horn and other circuits that will be explained below require the higher voltage provided by DC/DC boost converter 102. When AFE chip 101 is operating on 3-V battery power and the programmed boost voltage VPGM is not currently needed, e.g., when none of the circuits that require the programmed boost voltage VPGM are active, DC/DC boost converter 102 can be disabled while first diode D1 provides for a current to flow directly from the battery to the pre-regulator circuit 104, bypassing DC/DC converter 102. However, when powering-up with a low-voltage battery, an attached MCU may require an MCU voltage Vmcu that is greater than the battery voltage but less than the voltage required by the horn driver. In this situation, DC/DC boost converter 102 is changed to provide an intermediate voltage to provide the necessary MCU voltage Vmcu.
During operation of smoke alarm 100B, DC/DC boost converter 102 will be turned on during periods when the higher voltage is necessary, e.g., during operation of the horn (not specifically shown in this figure) or during operation of other circuits that need a higher voltage. These additional circuits will be explained below. When the higher voltage is not necessary, power is received at pre-regulator circuit 104 directly from battery 107 through first diode D1 and is provided by pre-regulator circuit 104 directly to internal LDO regulator 106 and MCU LDO regulator 108. The DC/DC boost converter 102 generates 10-12 V for horn driver supply from battery 107 when needed. This DC/DC boost converter 102 is automatically enabled on power-up to support power-up from a battery as low as 2 V. Once the device is powered up, the battery voltage can drop further and keep the device powered through the DC/DC boost converter.
Of particular interest is a situation in which battery 107 or backup battery 105 is coupled to AFE chip 101, but the battery has been depleted to 2 V and no other supply is coupled beforehand. In this setting, if an MCU coupled to AFE chip 101 requires 3.3 V, there is no means to provide power to the MCU except by turning on DC/DC boost converter 102 on. DC/DC boost converter 102 is automatically turned on and determines a voltage required for an MCU, e.g., based on the how the seventh pin P7 is coupled. DC/DC boost converter 102 then provides a voltage appropriate to turn on the MCU without any external programming.
The AFE chip 201 includes a DC/DC boost converter 202, a pre-regulator circuit 204, an internal LDO regulator 206, an MCU LDO regulator 208 and a voltage divider 210. As shown in smoke detection device 200, DC/DC boost converter 202, pre-regulator circuit 204, internal LDO regulator 206, and MCU LDO regulator 208 correspond to their respective counterparts in
AFE chip 201 also includes sensor drivers, e.g., a CO detection circuit 212, a photo-detection circuit 214, and an ion detection circuit 216. In one embodiment as shown, CO detection circuit 212 has a CO upper power supply input that is coupled to receive power from the internal LDO 206; CO detection circuit 212 is further coupled to a plurality of CO pins 220. Photo-detection circuit 214 has a photo upper power supply input that is coupled to receive power from the internal LDO 206; photo-detection circuit 212 is further coupled to a plurality of photo-detection pins 222. In one embodiment, photo-detection circuit 214 includes a first light-emitting diode (LED) driver 224 and a second LED driver 226. Ion detection circuit 216 has an ion upper power supply input that is coupled to receive power from DC/DC boost converter 202; ion detection circuit 216 is further coupled to a plurality of ion pins 228.
In order to supply the information collected by the sensors 205, multiplexor 230 is coupled to a CO output from the CO detection circuit 212, a first photo output and a second photo output from the photo-detection circuit 214, an ion output from the ion detection circuit 216, and VCC voltage divider 210, which provides divided voltage Vccdiv. By passing divided voltage Vccdiv to MCU chip 209, MCU chip 209 is able to monitor the voltage that pre-regulator circuit 204 is able to provide. This can be especially important when smoke detection device 200 is operating from a low-voltage battery, such as battery backup 105 or battery 107. Multiplexor 230 has a MUX upper power supply input that is coupled to receive power from the internal LDO 206. Multiplexor 230 is further coupled to selectively provide the data from the detection circuits through a buffer amplifier 232 to a MUX pin Pmux. The final elements of the AFE circuitry in AFE chip 201 as shown are an interconnect I/O buffer 234 and a horn driver 236. Interconnect I/O buffer 234 has an upper power supply input that is coupled to receive power from DC/DC boost converter 202 and interconnect I/O buffer 234 is further coupled to a first interconnect pin Pi1 and a second interconnect pin Pi2 and will be further explained below. Horn driver 236 is also coupled to receive power from boosted output voltage Vbst and is further coupled to a plurality of horn pins 238.
Power source 203 will generally include a battery, which may be used to as backup power in case of a power outage or as the primary power source for smoke detection device 200, and may also include a connection to mains power through an AC/DC converter. As seen in
Sensors 205 can include CO sensors 244, photo sensor(s) 246, LEDs 248, and ion sensor 250 or some combination of these sensors. For example, not every smoke detection device 200 will contain a CO sensor 244 and not every smoke detection device 200 will contain an ion sensor 250. When present, CO sensor 244 is coupled to CO detection circuit 212 through the plurality of CO pins 220 and ion sensor 250 is coupled to ion detection circuit 216 through the plurality of ion pins 228.
Current UL standards require the ability to distinguish between different types of fires, which have different particle sizes. To address this, many smoke detection devices 200 now include two different LEDs 248, e.g., a blue LED and an infrared LED. Each of the LEDs 248 is coupled to either the first LED driver 224 or to second LED driver 226 and each is used with a different photo sensor 246. Both photo sensor(s) 246 and LEDs 248 are coupled to photo-detection circuit 214 through the plurality of photo pins 246.
Warning system 207 is the means by which problems detected by smoke detection device 200 can be conveyed to people who are in the affected building and/or monitoring the building. As shown, warning system 207 can include an attached horn 252, horn driver 236, and interconnection capabilities for connecting to a centralized alarm system, e.g., interconnect I/O buffer 234. When a horn is used, horn 252 can be attached to horn pins 236. If it is desired to connect multiple residential smoke detection devices 200 together, interconnect I/O buffer 234 provides the means for the smoke detection devices to communicate with each other. Commercial smoke detection systems generally do not utilize either a horn within the individual smoke alarms or the interconnection capabilities, but use a signal line circuit (SLC) instead. Both interconnect I/O buffer 234 and horn driver 236 are also designed to be compatible with SLC and both the plurality of horn pins 238 and second interconnect pin Pi2 can be used for coupling to the centralized alarm system and for communicating therewith. As will be seen, first pin Pi1 is coupled to MCU chip 209, so that the MCU chip 209 can communicate with the centralized alarm system.
MCU chip 209 is coupled to AFE chip 201 through a plurality of MCU pins 254, which include sixth pin P6, MUX pin Pmux, first interconnect pin Pi1, and a number of additional pins that can be utilized for general purpose I/O, for programming registers (not specifically shown in this figure) in a digital core 256, and for controlling various functions through AFE chip 201.
In one embodiment, the AFE chip 201 integrates a sleep timer to help manage critical analog and regulator circuits independent of the MCU chip 209. When a sleep mode is enabled by MCU chip 209, the sleep timer starts. A number of circuits on AFE chip 201, e.g., MCU LDO regulator 208, DC/DC boost converter 202, multiplexor 230, portions of photo-detection circuit 214, and portions of ion detection circuit 216 may be disabled. In one embodiment, whether or not the DC/DC boost converter 202, the MCU LDO regulator 208, and the analog blocks are disabled depends on respective settings in the boost sleep register bit SLP_BST, the MCU sleep register bit SLP_MCU, and an analog sleep register bit SLP_ANALOG. After the sleep timer finishes, the AFE chip 201 notifies MCU chip 209 that the sleep mode can be exited. When AFE chip 201 exits the sleep mode, the circuits on AFE chip 201 are set to their pre-sleep state.
Sleep mode reduces power consumption in three ways:
During sleep mode operation, the MCU chip 209 can enter its lowest power idle state and monitor a general purpose I/O pin for the indication that the sleep period is exited. This monitoring provides for the clocks on MCU chip 209 to be disabled as AFE chip 201 signals the MCU to wake up after a precise programmed time, which in one embodiment is programmable.
The register bits 260 contain a large number of registers/register bits that can be utilized to provide parameters and control for smoke detection device 200. Only a few of the register bits 260 are shown in
The boost sleep register bit SLP_BST 272, the MCU sleep register bit SLP_MCU 274, and the analog sleep register bit SLP_ANALOG 276 are used to determine whether the respective circuits DC/DC boost converter 202, MCU LDO regulator 208, and the analog blocks are disabled during sleep mode. The analog blocks can include, e.g., the high-power amplifiers and drivers such as multiplexor 230, horn driver 236, interconnect I/O buffer 234, and photo-detection circuit 214, which includes first LED driver 224 and second LED driver 226. The MCU-voltage-setting signal VMCUSET 213 is set by MCU chip 209, stored in MCU-voltage-setting register VMCUSETR 278, and indicates an operating voltage to be provided to the MCU chip 209 by MCU LDO regulator 208. The MCU enable signal MCUENA 211 can be provided to MCU LDO regulator 208 from either the MCU enable register bit MCUENAR 280 or from a sleep timer. In one embodiment, the sleep timer is provided as sleep timer register SLP_TIMER 282.
In
In
Applicants have disclosed an AFE chip for a smoke detection device and a smoke detection device that uses the disclosed AFE chip. The AFE chip is designed for versatility with multiple power supply sources and can be utilized with a battery that is rated between 2 V and 15 V, as well as being able to accept mains power through an AC/DC converter. The DC/DC boost converter on the AFE chip is able to detect the voltage at the boost output and to access additional information to determine whether the DC/DC boost converter is needed or not. The pre-regulator circuit can accept a wide range of input voltages and provide an output voltage that is safe for other power circuits on the AFE chip. A process of operating a smoke detector is also disclosed.
Although various embodiments have been shown and described in detail, the claims are not limited to any particular embodiment or example. None of the above Detailed Description should be read as implying that any particular component, element, step, act, or function is essential such that it must be included in the scope of the claims. Reference to an element in the singular is not intended to mean “one and only one” unless explicitly so stated, but rather “one or more.” All structural and functional equivalents to the elements of the above-described embodiments that are known to those of ordinary skill in the art are expressly incorporated herein by reference and are intended to be encompassed by the present claims. Accordingly, those skilled in the art will recognize that the exemplary embodiments described herein can be practiced with various modifications and alterations within the spirit and scope of the claims appended below.
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