This U.S. non-provisional application claims priority under 35 U.S.C. § 119 to Korean Patent Application No. 10-2019-0175903, filed on Dec. 27, 2019 in the Korean Intellectual Property Office (KIPO), the disclosure of which is incorporated by reference herein in its entirety.
Exemplary embodiments of the inventive concept relate generally to semiconductor integrated circuits, and more particularly, to a built-in self-test (BIST) circuit and a temperature measurement circuit including the BIST circuit.
An operation temperature may be monitored and measured to enhance performance of a semiconductor integrated circuit. For example, based on the measured operation temperature, a power level of an electronic device may be controlled, a refresh period of a memory device may be controlled, damage of a circuit may be prevented, and so on. Heat management becomes more important as operation speed and performance levels are increased. On-chip temperature sensors that are integrated with integrated circuits in the same semiconductor die may be used to detect temperatures of various junctions of the integrated circuits. If the on-chip temperature sensors are out of order, the performance of the semiconductor integrated circuit may be degraded or the semiconductor integrated circuit may be damaged due to wrong information on the operation temperature. Particularly, the wrong temperature information of a semiconductor integrated circuit used in a vehicle may directly impact the life of the driver of the vehicle.
According to an exemplary embodiment of the inventive concept, a temperature measurement circuit includes a band-gap reference circuit configured to generate a band-gap reference voltage that is fixed regardless of an operation temperature, a reference voltage generator circuit configured to generate a measurement reference voltage by adjusting the band-gap reference voltage, a sensing circuit configured to generate a temperature-variant voltage based on a bias current, where the temperature-variant voltage is varied depending on the operation temperature, an analog-digital converter circuit configured to generate a first digital code indicating the operation temperature based on the measurement reference voltage and the temperature-variant voltage, and an analog built-in self-test (BIST) circuit configured to generate a plurality of flag signals indicating whether each of the band-gap reference voltage, the measurement reference voltage, and a bias voltage corresponding to the bias current is included in a predetermined range.
According to an exemplary embodiment of the inventive concept, a temperature measurement circuit includes a temperature detection circuit and an analog built-in self-test (BIST) circuit. The temperature detection circuit includes an analog circuit configured to generate a measurement reference voltage that is fixed regardless of an operation temperature and a temperature-variant voltage that is varied depending on the operation temperature, and an analog-digital converter circuit configured to generate a digital code indicating the operation temperature based on the measurement reference voltage and the temperature-variant voltage. The analog BIST circuit generates a plurality flag signals indicating whether each of a plurality of voltages of the analog circuit is included in a predetermined range.
According to an exemplary embodiment of the inventive concept, a built-in self-test (BIST) circuit, configured to monitor a temperature detection circuit including an analog circuit and an analog-digital converter circuit, includes an analog BIST circuit configured to generate a plurality of flag signals indicating whether each of a plurality of monitoring voltages of the analog circuit is included in a predetermined range, and a digital BIST circuit configured to apply a test signal to the analog-digital converter circuit in a test mode to generate a plurality of alarm signals indicating whether the analog-digital converter circuit operates normally.
The above and other features of the inventive concept will be more clearly understood by describing in detail exemplary embodiments thereof with reference to the accompanying drawings.
Exemplary embodiments of the inventive concept provide a built-in self-test (BIST) circuit capable of efficiently monitoring a temperature detection circuit and a temperature measurement circuit including the BIST circuit.
Exemplary embodiments of the inventive concept will be described more fully hereinafter with reference to the accompanying drawings. Like reference numerals may refer to like elements throughout this application.
Referring to
The temperature detection circuit 10 may include an analog circuit 100 and an analog-digital converter ADC 200.
The analog circuit 100 may generate a measurement reference voltage VREF that is fixed regardless of an operation temperature and a temperature-variant voltage VTEM that is varied depending on the operation temperature. The analog-digital converter 200 may generate a digital code DCD indicating the operation temperature based on the measurement reference voltage VREF and the temperature-variant voltage VTEM. The analog-digital converter 200 may be a circuit.
The BIST circuit 20 may include at least one of an analog BIST circuit ABIST 300 and a digital BIST circuit DBIST 400. In exemplary embodiments of the inventive concept, the BIST circuit 20 may include only the analog BIST circuit 300 and the digital BIST circuit 400 may be omitted. In exemplary embodiments of the inventive concept, the BIST circuit 20 may include only the digital BIST circuit 400 and the analog BIST circuit 300 may be omitted. In exemplary embodiments of the inventive concept, the BIST circuit 20 may include both of the analog BIST circuit 300 and the digital BIST circuit 400.
The analog BIST circuit 300 may generate a plurality of flag signals FG1˜FGk indicating whether each of a plurality of monitoring voltages VM1˜VMk of the analog circuit 100 is included in a normal range. The normal range may be a predetermined range indicating normal operation of a particular component. The monitoring voltage may indicate a voltage that is used in the analog circuit 100 and/or provided to other components (e.g., the analog-digital converter 200) external to the analog circuit 100. For example, the monitoring voltages VM1˜VMk may include at least one of the measurement reference voltage VREF, the temperature-variant voltage VTEM, and a bias voltage VBS as will be described below with reference to
The digital BIST circuit 400 may apply a test signal TS to the analog-digital converter 200 in a test mode to generate a plurality of alarm signals ALM1˜ALMs indicating whether the analog-digital converter 200 operates normally. The digital BIST circuit 400 may apply the test signal TS instead of the temperature-variant voltage VTEM in the test mode to receive the digital code DCD for generating the plurality of alarm signals ALM1˜ALMs. The plurality of alarm signals ALM1˜ALMs will be described below with reference to
As such, the BIST circuit and the temperature measurement circuit according to exemplary embodiments of the inventive concept may efficiently diagnose failure of the temperature measurement circuit by monitoring whether various voltages are in normal ranges using the BIST circuit. In addition, the BIST circuit and the temperature measurement circuit according to exemplary embodiments of the inventive concept may efficiently diagnose the analog-digital converter included in the temperature measurement circuit by performing various tests using the digital BIST circuit.
Referring to
The band-gap reference circuit 110 may generate a band-gap reference voltage VBGR that is fixed regardless of an operation temperature. The reference voltage generator 120 may generate the measurement reference voltage VREF by adjusting the band-gap reference voltage VBGR. Similar to the band-gap reference voltage VBGR, the measurement reference voltage VREF may be fixed regardless of the operation temperature. The sensing circuit 130 may generate the temperature-variant voltage VTEM based on a bias current IBS such that the temperature-variant voltage VTEM may be varied depending on the operation temperature.
Hereinafter, with reference to
Referring to
The first sensing unit 111 may be implemented with a signal bipolar junction transistor (BJT) and the second sensing unit 112 may be implemented with a plurality of BJTs. Using such band-gap reference circuits, the band-gap reference voltage VBGR and/or a band-gap reference current, which are fixed regardless of the operation temperature, may be provided.
The emitter voltage of the second sensing unit 112 is inversely proportional to the operation temperature. A voltage across the third resistor R3 and a current flowing through the third resistor R3 are proportional to the operation temperature. As a result, the band-gap reference voltage VBGR may be fixed regardless of the operation temperature by the proportional and inversely-proportional characteristics of the circuit. For example, the band-gap reference voltage VBGR may be provided at a connection node of the second PMOS transistor PM12 and the second resistor R2.
Referring to
Referring to
The current-voltage converter 135 may include a current source CST and a sensing unit SU connected between the power supply voltage VDD and the ground voltage VSS. The sensing unit SU may be implemented with a BJT. A sensing voltage VBE corresponding to the emitter voltage of the BJT may be inversely proportional to the operation temperature. The positive terminal of the first amplifier AMP1 may receive the sensing voltage VBE, and the negative terminal may be connected to the output terminal such that the first amplifier AMP1 may form a unity-gain amplifier. The output terminal of the first amplifier AMP1 may be connected through the first resistor R1 to the negative terminal of the second amplifier AMP2. The second amplifier AMP2 may receive a reference voltage VREFi through the positive terminal. The output terminal of the second amplifier AMP2 may be connected through the second resistor R2 to the negative terminal of the second amplifier AMP2.
Through such configuration, the sensing voltage VBE inversely-proportional to the operation temperature may be inverted and amplified to generate the temperature-variant voltage VTEM that is increased as the operation temperature is increased.
As described with reference to
Referring to
The power supply voltage divider 311 may generate a power division voltage VD11 corresponding a lowest limit level of the band-gap reference voltage VBGR by dividing the power supply voltage VDD.
In exemplary embodiments of the inventive concept, as illustrated in
Referring to
For example, the band-gap flag signal FG1 may be deactivated in a first logic level (e.g., a logic low level L) when the band-gap reference voltage VBGR is higher than the lowest limit level, and the band-gap flag signal FG1 may be activated in a second logic level (e.g., a logic high level H) when the band-gap reference voltage VBGR is lower than the lowest limit level.
Referring to
The band-gap reference voltage divider 321 may generate a first band-gap division voltage VD21 corresponding a highest limit level of the measurement reference voltage VREF and a second band-gap division voltage VD22 corresponding to a lowest limit level of the measurement reference voltage VREF by dividing the band-gap reference voltage VBGR.
In exemplary embodiments of the inventive concept, as illustrated in
The first band-gap division voltage VD21 may be provided at the first division node N21, and the first band-gap division voltage V21 may correspond to a highest limit level to set the normal range of the measurement reference voltage VREF. The second band-gap division voltage VD22 may be provided at the second division node N22, and the second band-gap division voltage V22 may correspond to a lowest limit level to set the normal range of the measurement reference voltage VREF. In other words, it is determined that the measurement reference voltage VREF deviates from the normal range if the band-gap reference voltage VBGR increases or decreases excessively. The highest and lowest limit levels of the measurement reference voltage VREF, or the first and second band-gap division voltages VD21 and VD22, may be controlled properly by adjusting the resistance ratios of the first division resistor R21, the second division resistor R22, and the third division resistor R23.
The measurement reference voltage divider 322 may generate a measurement division voltage VD23 by dividing the measurement reference voltage VREF.
In exemplary embodiments of the inventive concept, as illustrated in
Referring to
For example, the reference voltage flag signal FG2 may be deactivated to a first logic level (e.g., a logic low level L) when the measurement reference voltage VREF is lower than the highest limit level and higher than the lowest limit level, and the reference voltage flag signal FG2 may be activated to a second logic level (e.g., a logic high level H) when the measurement reference voltage VREF is higher than the highest limit level or lower than the lowest limit level.
Referring to
The measurement reference voltage divider 331 may generate a first measurement reference division voltage VD31 corresponding a highest limit level of the bias voltage VBS and a second measurement reference division voltage VD32 corresponding to a lowest limit level of the bias voltage VBS by dividing the measurement reference voltage VREF.
In exemplary embodiments of the inventive concept, as illustrated in
The first measurement reference division voltage VD31 may be provided at the first division node N31, and the measurement reference division voltage VD31 may correspond to a highest limit level to set the normal range of the bias voltage VBS. The second measurement reference division voltage VD32 may be provided at the second division node N32, and the second measurement reference division voltage VD32 may correspond to a lowest limit level to set the normal range of the bias voltage VBS. In other words, it is determined that the bias voltage VBS deviates from the normal range if the bias voltage VBS increases or decreases excessively. The highest and lowest limit levels of the bias voltage VBS, or the first and second measurement reference division voltages VD31 and VD32, may be controlled properly by adjusting the resistance ratios of the first division resistor R31, the second division resistor R32, and the third division resistor R33.
The current-voltage converter 332 may generate the bias voltage VBS based on the bias current IBS. For example, as illustrated in
Referring to
For example, the bias voltage flag signal FG3 may be deactivated in a first logic level (e.g., a logic low level L) when the bias voltage VBS is lower than the highest limit level and higher than the lowest limit level, and the bias voltage flag signal FG3 may be activated in a second logic level (e.g., a logic high level H) when the bias voltage VBS is higher than the highest limit level or lower than the lowest limit level.
Referring to
The band-gap reference voltage monitor 310, as described with reference to
The measurement reference voltage monitor 320, as described with reference to
The bias voltage monitor 330, as described with reference to
In other words, each of the monitors 310, 320, and 330 may generate one of the flag signals FG1, FG2, and FG3 by comparing one monitoring voltage with one comparison reference voltage.
As described with reference to
As such, the monitoring voltage for one voltage monitor may be used as the comparison reference voltage for another voltage monitor. As described above, the band-gap reference voltage VBGR corresponding to the monitoring voltage of the band-gap reference voltage monitor 310 may be applied as the comparison reference voltage of the measurement reference voltage monitor 320, and the measurement reference voltage VREF corresponding to the monitoring voltage of the measurement reference voltage monitor 320 may be applied as the comparison reference voltage of the bias voltage monitor 330. In this way, the deviation of the monitoring voltage of the previous voltage monitor may be propagated to the next voltage monitor, and thus, the last voltage monitor may determine the synthetic deviation of the multiple voltage monitors.
According to exemplary embodiments of the inventive concept, the analog BIST circuit may include one or two of the band-gap reference voltage monitor 310, the measurement reference voltage monitor 320, and the bias voltage monitor 330. In addition, the analog BIST circuit according to exemplary embodiments of the inventive concept may include four or more voltage monitors to monitor whether four or more voltages are included in their respective normal ranges.
Referring to
The first current source CST and the second current source CSM may include PMOS transistors PM1 and PM2, which form a current mirror. In this case, the criteria for the normal operation of the analog circuit 100 may be properly set by generating the temperature-fixed bias voltage VBS and the temperature-variant sensing voltage VBE using the same bias current IBS.
Referring to
The counter 410 may monitor operation timings of the analog-digital converter 200. The counter 410 may generate a count signal CNT corresponding to the operation timings based on a timing signal TIM and a clock signal CLK. For example, the timing signal TIM may include a scan start signal SOS, a conversion start signal SOC, a conversion end signal EOC, etc., as will be described below with reference to
The memory 420 may store information for the operation of the digital BIST circuit 400 and information on test results obtained by the digital BIST circuit 400.
The test signal generator 430 may generate a test signal TS for various tests. In a test mode, the test signal TS may be applied to the analog-digital converter 200 instead of the temperature-variant voltage VTEM.
The digital logic block 440 may receive the digital code DCD, control overall operations of the digital BIST circuit 400, and generate a plurality of alarm signals MONO, LNT, OFF, STC, FLT, FCT, STT, CNV, and PRV according to the test results.
Referring to
The digital logic block 440 may test whether the analog-digital converter 200 operates normally, based on a plurality of values DL1˜DLp that are obtained by applying the ramp voltage VRMP instead of the temperature-variant voltage VTEM to the analog-digital converter 200 in the test mode. For example, the analog-digital converter 200, as illustrated in
Hereinafter, it is assumed that an alarm signal is activated in a logic high level H and deactivated in a logic low level L, but the inventive concept is not limited thereto.
Referring to
The digital logic block 440 may receive the plurality of values DL1˜DLp of the digital code DCD generated while the ramp voltage VRMP is applied to the analog-digital converter 200 (S13). The digital logic block 440 may determine whether the difference DLi+1−DLi between the two adjacent values DLi+1 and DLi among the plurality of values DL1˜DLp is smaller than zero (S14). When the difference DLi+1−DLi is smaller than zero (S14: YES), the digital block 440 may activate a monotony alarm signal MONO to the logic high level H (S15). In contrast, when the difference DLi+1−DLi is not smaller than zero (S14: NO), the digital block 440 may deactivate the monotony alarm signal MONO to the logic low level L (S16).
As such, the digital BIST circuit 400 may generate the monotony alarm signal MONO based on the plurality of values DL1˜DLp of the digital code DCD such that the monotony alarm signal MONO may indicate whether the digital code DCD increases or decreases monotonously.
Referring to
The digital logic block 440 may receive the plurality of values DL1˜DLp of the digital code DCD generated while the ramp voltage VRMP is applied to the analog-digital converter 200 (S23). The digital logic block 440 may determine whether the difference DLi+1−DLi between the two adjacent values DLi+1 and DLi among the plurality of values DL1˜DLp is greater than a reference value RF1 (S24). When the difference DLi+1−DLi is greater than the reference value RF1 (S24: YES), the digital block 440 may activate a linearity alarm signal LNT to the logic high level H (S25). In contrast, When the difference DLi+1−DLi is not greater than the reference value RF1 (S24: NO), the digital block 440 may deactivate the linearity alarm signal LNT to the logic low level L (S26).
As such, the digital BIST circuit 400 may generate the linearity alarm signal LNT based on the plurality of values DL1˜DLp of the digital code DCD such that the linearity alarm signal LNT may indicate whether the digital code DCD increases or decreases uniformly.
The test signal generator 430 in
Test operations as will be described with reference to
Referring to
The digital logic block 440 may receive a measured value DLI′ of the digital code DCD that is generated while the voltage level VI is applied to the analog-digital converter 200 (S33). The digital logic block 440 may determine whether an absolute difference |DLI−DLI′| between the measured value DLI′ and the center value DLI is greater than a reference value RF2 (S34). When the absolute difference |DLI−DLI′| is greater than the reference value RF2 (S34: YES), the digital block 440 may activate an offset alarm signal OFF to the logic high level H (S35). In contrast, when the absolute difference |DLI−DLI′| is not greater than the reference value RF2 (S34: NO), the digital block 440 may deactivate the offset alarm signal OFF to the logic low level L (S35).
As such, the digital BIST circuit 400 may generate the offset alarm signal OFF based on the measured value DLI′ and the center value DLI such that the offset alarm signal OFF may indicate whether the offset of the digital code DCD deviates from its normal range represented by the reference value RF2.
Referring to
The digital logic block 440 may receive a first measured value DLH of digital code DCD that is generated while the voltage level VH is applied to the analog-digital converter 200 (S43). The digital logic block 440 may determine whether the first measured value DLH is equal to the maximum value DLMAX (S44). When the first measured value DLH is not equal to the maximum value DLMAX (S44: NO), the digital block 440 may activate a stuck alarm signal STC to the logic high level H (S45).
When the first measured value DLH is equal to the maximum value DLMAX (S44: YES), the test signal generator 430 may generate the test signal TS having the voltage level VL lower than the voltage level VMIN corresponding to the minimum value DLMIN of the digital code DCD to be applied to the analog-digital converter 200 (S46).
The digital logic block 440 may receive a second measured value DLL of digital code DCD that is generated while the voltage level VL is applied to the analog-digital converter 200 (S47). The digital logic block 440 may determine whether the second measured value DLL is equal to the minimum value DLMIN (S48). When the second measured value DLL is not equal to the minimum value DLMIN (S48: NO), the digital block 440 may activate the stuck alarm signal STC to the logic high level H (S45). When the second measured value DLL is equal to the minimum value DLMIN (S48: YES), the digital block 440 may deactivate the stuck alarm signal STC to the logic low level L (S49).
As such, the digital BIST circuit 400 may generate the stuck alarm signal STC based on the first measured value DLH and the second measured value DLL such that the stuck alarm signal STC may indicate whether each bit of the digital code DCD is fixed regardless of the operation temperature.
Referring to
The pulling control circuit 450 of the digital BIST circuit may include a pull-up resistor RU connected to the power supply voltage VDD and a pull-up switch SWU configured to control an electric connection between the pull-up resistor RU and the output node NO of the digital code DCD. In addition, the pulling control circuit 450 may include a pull-down resistor RD connected to the ground voltage VSS and a pull-down switch SWD configured to control an electric connection between the pull-down resistor RD and the output node NO of the digital code DCD. The pull-up switch SWU and the pull-down switch SWD may be turned on based on switch control signals SCU and SCD, respectively, which are provided from the digital logic block 440 in
In other words, the digital BIST circuit applies the test signal TS having a higher voltage level (VH) than the voltage level VMAX corresponding to the maximum value DLMAX of the digital code DCD to the analog-digital converter circuit when the pull-down switch SWD is turned on and applies the test signal TS having a lower voltage level (VL) than the voltage level VMIN corresponding to the minimum value DLMIN of the digital code DCD to the analog-digital converter 200 when the pull-up switch SWU is turned on in the test mode to generate a floating alarm signal FLT. This will be described further with reference to
Test operations as will be described with reference to
Referring to
The digital logic block 440 may receive a first measured value DLH of the digital code DCD that is generated while the output node NO is pulled down and the voltage level VH is applied to the analog-digital converter 200 (S54). The digital logic block 440 may determine whether the first measured value DLH is equal to the maximum value DLMAX (S55). When the first measured value DLH is not equal to the maximum value DLMAX (S55: NO), the digital block 440 may activate a floating alarm signal FLT to the logic high level H (S56).
When the first measured value DLH is equal to the maximum value DLMAX (S55: YES), the test signal generator 430 may activate the switch control signal SCH and pull up the output node NO by electrically connecting the output node NO to the power supply voltage VDD (S57). Additionally, the test signal generator 430 may generate the test signal TS having the voltage level VL lower than the voltage level VMIN corresponding to the minimum value DLMIN of the digital code DCD to be applied to the analog-digital converter 200 (S58).
The digital logic block 440 may receive a second measured value DLL of digital code DCD that is generated while the output node NO is pulled up and the voltage level VL is applied to the analog-digital converter 200 (S59). The digital logic block 440 may determine whether the second measured value DLL is equal to the minimum value DLMIN (S60). When the second measured value DLL is not equal to the minimum value DLMAX (S60: NO), the digital block 440 may activate the floating alarm signal FLT to the logic high level H (S56). When the second measured value DLL is equal to the minimum value DLMAX (S60: YES), the digital block 440 may deactivate the floating alarm signal FLT to the logic low level L (S61).
As such, the digital BIST circuit 400 may generate the floating alarm signal FLT based on the first measured value DLH and the second measured value DLL such that the floating alarm signal FLT may indicate whether the output node NO of the digital code DCD is opened.
Referring to
The scan voltage generator 210 may generate a plurality of scan voltages VS0˜VSq having different voltage levels based on the measurement reference voltage VREF, and output the plurality of scan voltages VS0˜VSq one by one by a unit scan time tS as will be described below with reference to
The comparator 220 may generate a plurality of comparison result values CMP by comparing the temperature-variant voltage VTEM or the test signal TS with the plurality of scan voltages VS0˜VSq. The converter 230 may generate the digital code DCD based on the plurality of comparison result values CMP.
The controller 240 may control the scan voltage generator 210, the comparator 220, and the converter 230. The controller 240 may generate the selection signal SEL to control the selector 212. The controller 240 may generate a scan start signal SOS and a conversion start signal SOC to control the converter 230. The controller may receive a conversion end signal EOC from the converter 230.
Referring to
The counter 410 in
Test operations as will be described with reference to
Referring to
The digital logic block 440 may determine whether the first measured value DLa is equal to the second measured value DLb (S76). When the first measured value DLa is not equal to the second measured value DLb (S76: NO), the digital block 440 may activate a fluctuation alarm signal FCT to the logic high level H (S77). In contrast, when the first measured value DLa is equal to the second measured value DLb (S76: YES), the digital block 440 may deactivate a fluctuation alarm signal FCT to the logic low level L (S78).
As such, the digital BIST circuit 400 may generate the fluctuation alarm signal FCT based on the first measured value DLa corresponding to the first unit scan time tSa and the second measured value DLb corresponding to the second unit scan time tSb such that the fluctuation alarm signal FCT may indicate whether the unit scan time is included in the normal range.
Referring to
The main sensing unit SUM may be disposed at a main position POSM and generate a main sensing voltage VBEM that is varied depending on a main operation temperature at the main position POSM.
The plurality of local sensing units SUL1˜SUL3 may be disposed at a plurality of local positions POSL1˜POSL3 and generate a plurality of local sensing voltages VBEL1˜VBEL3 that are varied depending on local operation temperatures at the plurality of local positions POSL1˜POSL3.
As illustrated in
Test operations as will be described with reference to
Referring to
The digital logic block 440 may determine whether an absolute difference |DLM−DLL1| between the first and second measured values DLM and DLL1 is greater than a reference value RF3 (S86). When the absolute difference |DLM−DLL1| is greater than the reference value RF3 (S86: YES), the digital block 440 may activate a probe-check alarm signal PRV to the logic high level H (S87). In contrast, when the absolute difference |DLM−DLL1| is not greater than the reference value RF3 (S86: NO), the digital block 440 may deactivate a probe-check alarm signal PRV to the logic low level L (S88).
As such, the digital BIST circuit 400 may generate the probe-check alarm signal PRV based on the first measured value DLM corresponding to the main sensing voltage VBEM and the second measured value DLL1 corresponding to the local sensing voltage VBEL1.
Referring to
Referring to
As described above, the BIST circuit and the temperature measurement circuit according to exemplary embodiments of the inventive concept may efficiently diagnose failure of the temperature measurement circuit by monitoring whether various voltages are in normal ranges using the BIST circuit.
In addition, the BIST circuit and the temperature measurement circuit according to exemplary embodiments of the inventive concept may efficiently diagnose the analog-digital converter included in the temperature measurement circuit by performing various tests using the digital BIST circuit.
The inventive concept may be applied to any electronic devices and systems requiring information on an operation temperature. For example, the inventive concept may be applied to systems such as a memory card, a solid state drive (SSD), an embedded multimedia card (eMMC), a universal flash storage (UFS), a mobile phone, a smart phone, a personal digital assistant (PDA), a portable multimedia player (PMP), a digital camera, a camcorder, a personal computer (PC), a server computer, a workstation, a laptop computer, a digital TV, a set-top box, a portable game console, a navigation system, a wearable device, an internet of things (IoT) device, an internet of everything (IoE) device, an e-book, a virtual reality (VR) device, an augmented reality (AR) device, etc.
While the inventive concept has been shown and described with reference to exemplary embodiments thereof, it will be apparent to those of ordinary skill in the art that various modifications in form and details may be made thereto without departing from the spirit and scope of the inventive concept as set forth by the appended claims.
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