8-bit Microcontroller with 2K Bytes In-System Programmable Flash. ATtiny25/V. Appendix A. Appendix A ATtiny25/V Specification at 105 C
|
|
- Barrie Holland
- 7 years ago
- Views:
Transcription
1 Appendix A ATtiny5/V Specification at 5 C This document contains information specific to devices operating at temperatures up to 5 C. Only deviations are covered in this appendix, all other information can be found in the complete datasheet. The complete datasheet can be found at 8-bit Microcontroller with K Bytes In-System Programmable Flash ATtiny5/V Appendix A Rev. 586N Appendix A AVR 8/
2 . Electrical Characteristics. Absolute Maximum Ratings* Operating Temperature C to +5 C Storage Temperature C to +5 C Voltage on any Pin except RESET with respect to Ground...-.5V to V CC +.5V Voltage on RESET with respect to Ground...-.5V to +3.V *NOTICE: Stresses beyond those listed under Absolute Maximum Ratings may cause permanent damage to the device. This is a stress rating only and functional operation of the device at these or other conditions beyond those indicated in the operational sections of this specification is not implied. Exposure to absolute maximum rating conditions for extended periods may affect device reliability. Maximum Operating Voltage... 6.V DC Current per I/O Pin ma DC Current V CC and GND Pins.... ma. DC Characteristics Table -. DC Characteristics. T A = -4 C to +5 C Symbol Parameter Condition Min. Typ. () Max. Units V IL V IH V IL V IH V IL V IH Input Low-voltage, except XTAL and RESET pin Input High-voltage, except XTAL and RESET pin Input Low-voltage, XTAL pin, External Clock Selected Input High-voltage, XTAL pin, External Clock Selected Input Low-voltage, RESET pin Input High-voltage, RESET pin V IL3 Input Low-voltage, RESET pin as I/O V IH3 Input High-voltage, RESET pin as I/O Output Low-voltage (4), V OL Port B (except RESET) (6) V OH Output High-voltage (5), Port B (except RESET) (6) I IL I IH Input Leakage Current I/O Pin Input Leakage Current I/O Pin V CC =.8V -.4V V CC =.4V - 5.5V V CC =.8V -.4V V CC =.4V - 5.5V V CC ().6V CC ().V CC (3).3V CC (3) V CC +.5 V CC +.5 V CC =.8V - 5.5V -.5.V CC (3) V CC =.8V -.4V V CC =.4V - 5.5V.8V CC ().7V CC () V CC +.5 V CC +.5 V CC =.8V - 5.5V -.5.V CC (3) V V V CC =.8V - 5.5V.9V CC () V CC +.5 V V CC =.8V -.4V V CC =.4V - 5.5V V CC =.8V -.4V V CC =.4V - 5.5V I OL = ma, V CC = 5V I OL = 5 ma, V CC = 3V I OH = - ma, V CC = 5V I OH = -5 ma, V CC = 3V V CC = 5.5V, pin low (absolute value) V CC = 5.5V, pin high (absolute value) V CC ().6V CC () V CC (3).3V CC (3) V CC +.5 V CC V V V V V V V V V V V V V V V <.5 µa <.5 µa ATtiny5 586N Appendix A AVR 8/
3 ATtiny5 Table -. DC Characteristics. T A = -4 C to +5 C (Continued) Symbol Parameter Condition Min. Typ. () Max. Units R RST Reset Pull-up Resistor V CC = 5.5V, input low 3 6 kω R pu I/O Pin Pull-up Resistor V CC = 5.5V, input low 5 kω I CC (7) Power Supply Current Active MHz, V CC = V.3.55 ma Active 4MHz, V CC = 3V.5.5 ma Active 8MHz, V CC = 5V 5 8 ma Idle MHz, V CC = V.. ma Idle 4MHz, V CC = 3V.35.6 ma Idle 8MHz, V CC = 5V. ma Power-down mode (8) WDT enabled, V CC = 3V 4 µa WDT disabled, V CC = 3V. µa Notes:. Typical values at 5 C.. Min means the lowest value where the pin is guaranteed to be read as high. 3. Max means the highest value where the pin is guaranteed to be read as low. 4. Although each I/O port can sink more than the test conditions ( ma at V CC = 5V, 5 ma at V CC = 3V) under steady state conditions (non-transient), the following must be observed: ] The sum of all IOL, for all ports, should not exceed 6 ma. If IOL exceeds the test condition, VOL may exceed the related specification. Pins are not guaranteed to sink current greater than the listed test condition. 5. Although each I/O port can source more than the test conditions ( ma at V CC = 5V, 5 ma at V CC = 3V) under steady state conditions (non-transient), the following must be observed: ] The sum of all IOH, for all ports, should not exceed 6 ma. If IOH exceeds the test condition, VOH may exceed the related specification. Pins are not guaranteed to source current greater than the listed test condition. 6. The RESET pin must tolerate high voltages when entering and operating in programming modes and, as a consequence, has a weak drive strength as compared to regular I/O pins. 7. Values are with external clock using methods described in Minimizing Power Consumption on page 37. Power Reduction is enabled (PRR = xff) and there is no I/O drive. 8. Brown-Out Detection (BOD) disabled. 586N Appendix A AVR 8/ 3
4 .3 Clock Characteristics.3. Calibrated Internal RC Oscillator Accuracy It is possible to manually calibrate the internal oscillator to be more accurate than default factory calibration. Please note that the oscillator frequency depends on temperature and voltage. Voltage and temperature characteristics can be found in Figure -36 on page 8 and Figure -37 on page 8. Table -. Calibration Accuracy of Internal RC Oscillator Calibration Method Target Frequency V CC Temperature Factory Calibration User Calibration Accuracy at given Voltage & Temperature () 8. MHz () 3V 5 C ±% Fixed frequency within: 6 8 MHz Fixed voltage within:.8v - 5.5V (3).7V - 5.5V (4) Fixed temperature within: -4 C to +5 C Notes:. Accuracy of oscillator frequency at calibration point (fixed temperature and fixed voltage).. ATtiny5/V, only: 6.4 MHz in ATtiny5 Compatibility Mode. 3. Voltage range for ATtiny5V. 4. Voltage range for ATtiny5. ±%.4 System and Reset Characteristics Table -3. Reset, Brown-out and Internal Voltage Characteristics Symbol Parameter Condition Min () Typ () Max () Units V RST RESET Pin Threshold Voltage V CC = 3V. V CC.9 V CC V t RST Minimum pulse width on RESET Pin V CC = 3V.5 µs V HYST Brown-out Detector Hysteresis 5 mv t BOD Min Pulse Width on Brown-out Reset µs V BG t BG Bandgap reference voltage Bandgap reference start-up time I BG Bandgap reference current consumption Note:. Values are guidelines only. V CC = 5.5V T A = 5 C V CC =.7V T A = 5 C V CC =.7V T A = 5 C... V 4 7 µs 5 µa 4 ATtiny5 586N Appendix A AVR 8/
5 ATtiny5.4. Enhanced Power-On Reset The table below describes the characteristics of the power-on reset. Table -4. Characteristics of Enhanced Power-On Reset. T A = -4 C to +5 C Symbol Parameter Min () Typ () Max () Units V POR Release threshold of power-on reset ()..4.7 V V POA Activation threshold of power-on reset (3) V SR ON Power-On Slope Rate. V/ms Note:. Values are guidelines, only. Threshold where device is released from reset when voltage is rising 3. The Power-on Reset will not work unless the supply voltage has been below V POT (falling) 586N Appendix A AVR 8/ 5
6 .5 ADC Characteristics Preliminary Table -5. ADC Characteristics, Single Ended Channels. T A = -4 C to +5 C Symbol Parameter Condition Min Typ Max Units Resolution Bits Absolute accuracy (Including INL, DNL, and Quantization, Gain and Offset errors) Integral Non-linearity (INL) (Accuracy after offset and gain calibration) Differential Non-linearity (DNL) Gain Error Note:. Values are guidelines only. V REF = 4V, V CC = 4V, ADC clock = khz V REF = 4V, V CC = 4V, ADC clock = MHz V REF = 4V, V CC = 4V, ADC clock = khz Noise Reduction Mode V REF = 4V, V CC = 4V, ADC clock = MHz Noise Reduction Mode V REF = 4V, V CC = 4V, ADC clock = khz V REF = 4V, V CC = 4V, ADC clock = khz V REF = 4V, V CC = 4V, ADC clock = khz LSB 3 LSB.5 LSB.5 LSB LSB.5 LSB.5 LSB V Offset Error REF = 4V, V CC = 4V,.5 LSB ADC clock = khz Conversion Time Free Running Conversion 4 8 µs Clock Frequency 5 khz V IN Input Voltage GND V REF V Input Bandwidth 38.4 khz AREF External Reference Voltage. V CC V Internal Voltage Reference... V V INT Internal.56V Reference () V CC > 3.V V R REF 3 kω R AIN Analog Input Resistance MΩ ADC Output 3 LSB 6 ATtiny5 586N Appendix A AVR 8/
7 ATtiny5 Table -6. ADC Characteristics, Differential Channels (Unipolar Mode). T A = -4 C to +5 C Symbol Parameter Condition Min Typ Max Units Resolution Absolute accuracy (Including INL, DNL, and Quantization, Gain and Offset Errors) Integral Non-Linearity (INL) (Accuracy after Offset and Gain Calibration) Gain Error Offset Error Note:. Values are guidelines only. Gain = x Bits Gain = x Bits Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz. LSB. LSB 4. LSB. LSB Gain = x. LSB Gain = x 5. LSB Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz 3. LSB 4. LSB Conversion Time Free Running Conversion 7 8 µs Clock Frequency 5 khz V IN Input Voltage GND V CC V V DIFF Input Differential Voltage V REF /Gain V Input Bandwidth 4 khz AREF External Reference Voltage. V CC -. V Internal Voltage Reference... V V INT Internal.56V Reference () V CC > 3.V V R REF Reference Input Resistance 3 kω R AIN Analog Input Resistance MΩ ADC Conversion Output 3 LSB 586N Appendix A AVR 8/ 7
8 Table -7. ADC Characteristics, Differential Channels (Bipolar Mode). T A = -4 C to +5 C Symbol Parameter Condition Min Typ Max Units Resolution Absolute accuracy (Including INL, DNL, and Quantization, Gain and Offset Errors) Integral Non-Linearity (INL) (Accuracy after Offset and Gain Calibration) Gain Error Offset Error Note:. Values are guidelines only. Gain = x Bits Gain = x Bits Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz 8. LSB 8. LSB 4. LSB 5. LSB Gain = x 4. LSB Gain = x 5. LSB Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz Gain = x V REF = 4V, V CC = 5V ADC clock = 5 - khz 3. LSB 4. LSB Conversion Time Free Running Conversion 7 8 µs Clock Frequency 5 khz V IN Input Voltage GND V CC V V DIFF Input Differential Voltage V REF /Gain V Input Bandwidth 4 khz AREF External Reference Voltage. V CC -. V Internal Voltage Reference... V V INT Internal.56V Reference () V CC > 3.V V R REF Reference Input Resistance 3 kω R AIN Analog Input Resistance MΩ ADC Conversion Output -5 5 LSB 8 ATtiny5 586N Appendix A AVR 8/
9 ATtiny5.6 Serial Programming Characteristics Figure -. Serial Programming Waveforms SERIAL DATA INPUT (MOSI) MSB LSB SERIAL DATA OUTPUT (MISO) MSB LSB SERIAL CLOCK INPUT (SCK) SAMPLE Figure -. Serial Programming Timing MOSI t OVSH t SHOX t SLSH SCK t SHSL MISO t SLIV Table -8. Serial Programming Characteristics, T A = -4 C to +5 C, V CC =.8-5.5V (Unless Otherwise Noted) Symbol Parameter Min Typ Max Units /t CLCL Oscillator Frequency (V CC =.8-5.5V) 4 MHz t CLCL Oscillator Period (V CC =.8-5.5V) 5 ns /t CLCL Oscillator Frequency (V CC =.7-5.5V) MHz t CLCL Oscillator Period (V CC =.7-5.5V) ns /t CLCL Oscillator Frequency (V CC = 4.5V - 5.5V) MHz t CLCL Oscillator Period (V CC = 4.5V - 5.5V) 5 ns t SHSL SCK Pulse Width High t CLCL* ns t SLSH SCK Pulse Width Low t CLCL* ns t OVSH MOSI Setup to SCK High t CLCL ns t SHOX MOSI Hold after SCK High t CLCL ns t SLIV SCK Low to MISO Valid ns Note:. t CLCL for f ck < MHz, 3 t CLCL for f ck >= MHz 586N Appendix A AVR 8/ 9
10 . Typical Characteristics. Active Supply Current The data contained in this section is largely based on simulations and characterization of similar devices in the same process and design methods. Thus, the data should be treated as indications of how the part will behave. The following charts show typical behavior. These figures are not tested during manufacturing. All current consumption measurements are performed with all I/O pins configured as inputs and with internal pull-ups enabled. A sine wave generator with rail-to-rail output is used as clock source. The power consumption in Power-down mode is independent of clock selection. The current consumption is a function of several factors such as: operating voltage, operating frequency, loading of I/O pins, switching rate of I/O pins, code executed and ambient temperature. The dominating factors are operating voltage and frequency. The current drawn from capacitive loaded pins may be estimated (for one pin) as C L *V CC *f where C L = load capacitance, V CC = operating voltage and f = average switching frequency of I/O pin. The parts are characterized at frequencies higher than test limits. Parts are not guaranteed to function properly at frequencies higher than the ordering code indicates. The difference between current consumption in Power-down mode with Watchdog Timer enabled and Power-down mode with Watchdog Timer disabled represents the differential current drawn by the Watchdog Timer. Figure -. Active Supply Current vs. V CC (Internal RC oscillator, 8 MHz) ACTIVE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, 8 MHz C 5 C I CC (ma) 4 3,5,5 3 3,5 4 4,5 5 5,5 ATtiny5 586N Appendix A AVR 8/
11 ATtiny5 Figure -. Active Supply Current vs. V CC (Internal RC Oscillator, MHz) ACTIVE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, MHz,6,4, 5 C -4 C I CC (ma),8,6,4,,5,5 3 3,5 4 4,5 5 5,5 Figure -3. Active Supply Current vs. V CC (Internal RC Oscillator, 8 khz) ACTIVE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, 8 KHz,5, -4 C 5 C I CC (ma),5,,5,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/
12 . Idle Supply Current Figure -4. Idle Supply Current vs. V CC (Internal RC Oscillator, 8 MHz) IDLE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, 8 MHz,8,6,4 5 C -4 C, I CC (ma),8,6,4,,5,5 3 3,5 4 4,5 5 5,5 Figure -5. Idle Supply Current vs. V CC (Internal RC Oscilllator, MHz) IDLE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, MHz,5,45,4 5 C -4 C I CC (ma),35,3,5,,5,,5,5,5 3 3,5 4 4,5 5 5,5 ATtiny5 586N Appendix A AVR 8/
13 ATtiny5 Figure -6. Idle Supply Current vs. V CC (Internal RC Oscillator, 8 khz) IDLE SUPPLY CURRENT vs. V CC INTERNAL RC OSCILLATOR, 8 khz,,9,8 5 C -4 C I CC (ma),7,6,5,4,3,,,5,5 3 3,5 4 4,5 5 5,5.3 Power-down Supply Current Figure -7. Power-down Supply Current vs. V CC (Watchdog Timer Disabled) POWER-DOWN SUPPLY CURRENT vs. V CC WATCHDOG TIMER DISABLED 3,5 5 C I CC (ua),5,5-4 C,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/ 3
14 Figure -8. Power-down Supply Current vs. V CC (Watchdog Timer Enabled) POWER-DOWN SUPPLY CURRENT vs. V CC WATCHDOG TIMER ENABLED 4 I CC (ua) C 5 C,5,5 3 3,5 4 4,5 5 5,5.4 Pin Pull-up Figure -9. I/O Pin Pull-up Resistor Current vs. Input Voltage (V CC =.8V) I/O PIN PULL-UP RESISTOR CURRENT vs. INPUT VOLTAGE V CC =.8V I OP (ua) 3-4 C 5 C,,4,6,8,,4,6,8 V OP (V) 4 ATtiny5 586N Appendix A AVR 8/
15 ATtiny5 Figure -. I/O Pin Pull-up Resistor Current vs. Input Voltage (V CC =.7V) I/O PIN PULL-UP RESISTOR CURRENT vs. INPUT VOLTAGE V CC =.7V I OP (ua) 4 3,5,5 V OP (V),5-4 C 5 C 3 Figure -. I/O Pin Pull-up Resistor Current vs. Input Voltage (V CC = 5V) I/O PIN PULL-UP RESISTOR CURRENT vs. INPUT VOLTAGE V CC = 5V 6 4 I OP (ua) V OP (V) C 5 C 6 586N Appendix A AVR 8/ 5
16 Figure -. Reset Pull-up Resistor Current vs. Reset Pin Voltage (V CC =.8V) RESET PULL-UP RESISTOR CURRENT vs. RESET PIN VOLTAGE V CC =.8V IRESET (ua) C 5 C,,4,6,8,,4,6,8 V RESET (V) Figure -3. Reset Pull-up Resistor Current vs. Reset Pin Voltage (V CC =.7V) RESET PULL-UP RESISTOR CURRENT vs. RESET PIN VOLTAGE V CC =.7V I RESET (ua) 3-4 C 5 C,5,5,5 3 V RESET (V) 6 ATtiny5 586N Appendix A AVR 8/
17 ATtiny5 Figure -4. Reset Pull-up Resistor Current vs. Reset Pin Voltage (V CC = 5V) RESET PULL-UP RESISTOR CURRENT vs. RESET PIN VOLTAGE V CC = 5V 8 I RESET (ua) C 5 C V RESET (V).5 Pin Driver Strength Figure -5. I/O Pin Output Voltage vs. Sink Current (V CC = 3V) I/O PIN OUTPUT VOLTAGE vs. SINK CURRENT V CC = 3V,,8 5 C V OL (V),6-4 C,4, 5 I OL (ma) N Appendix A AVR 8/ 7
18 Figure -6. I/O Pin Output Voltage vs. Sink Current (V CC = 5V) I/O PIN OUTPUT VOLTAGE vs. SINK CURRENT V CC = 5V,6 5 C,5,4-4 C V OL (V),3,, 5 I OL (ma) 5 5 Figure -7. I/O Pin Output Voltage vs. Source Current (V CC = 3V) I/O PIN OUTPUT VOLTAGE vs. SOURCE CURRENT V CC = 3V 3,5 3 V OH (V),5,5-4 C 5 C,5 5 I OH (ma) ATtiny5 586N Appendix A AVR 8/
19 ATtiny5 Figure -8. I/O Pin Output Voltage vs. Source Current (V CC = 5V) I/O PIN OUTPUT VOLTAGE vs. SOURCE CURRENT V CC = 5V 5 4,9 4,8 4,7 V OH (V) 4,6-4 C 4,5 4,4 5 C 4,3 5 I OH (ma) 5 5 Figure -9. Reset Pin Output Voltage vs. Sink Current (V CC = 3V) RESET AS I/O PIN OUTPUT VOLTAGE vs. SINK CURRENT V CC = 3V,5 5 C V OL (V),5-4 C,5,5 I OL (ma), N Appendix A AVR 8/ 9
20 Figure -. Reset Pin Output Voltage vs. Sink Current (V CC = 5V) RESET AS I/O PIN OUTPUT VOLTAGE vs. SINK CURRENT V CC = 5V,8 V OL (V),6,4 5 C -4 C,,5,5 I OL (ma),5 3 Figure -. Reset Pin Output Voltage vs. Source Current (V CC = 3V) RESET AS I/O PIN OUTPUT VOLTAGE vs. SOURCE CURRENT V CC = 3V 3,5 3,5 V OH (V),5,5-4 C 5 C,5 I OH (ma),5 ATtiny5 586N Appendix A AVR 8/
21 ATtiny5 Figure -. Reset Pin Output Voltage vs. Source Current (V CC = 5V) RESET AS I/O PIN OUTPUT VOLTAGE vs. SOURCE CURRENT V CC = 5V 5 4,5 4 V OH (V) 3,5 3-4 C,5 5 C,5,5 I OH (ma).6 Pin Threshold and Hysteresis Figure -3. I/O Pin Input Threshold Voltage vs. V CC (V IH, IO Pin Read as ) I/O PIN INPUT THRESHOLD VOLTAGE vs. V CC VIH, IO PIN READ AS '' 3,5 5 C -4 C Threshold (V),5,5,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/
22 Figure -4. I/O Pin Input Threshold Voltage vs. V CC (V IL, IO Pin Read as ) I/O PIN INPUT THRESHOLD VOLTAGE vs. V CC VIL, IO PIN READ AS '' 3,5 5 C -4 C Threshold (V),5,5,5,5 3 3,5 4 4,5 5 5,5 Figure -5. I/O Pin Input Hysteresis vs. V CC I/O PIN INPUT HYSTERESIS vs. V CC,6,5-4 C Input Hysteresis (V),4,3, 5 C,,5,5 3 3,5 4 4,5 5 5,5 ATtiny5 586N Appendix A AVR 8/
23 ATtiny5 Figure -6. Reset Input Threshold Voltage vs. V CC (V IH, IO Pin Read as ) RESET INPUT THRESHOLD VOLTAGE vs. V CC VIH, IO PIN READ AS '',5-4 C 5 C Threshold (V),5,5,5,5 3 3,5 4 4,5 5 5,5 Figure -7. Reset Input Threshold Voltage vs. V CC (V IL, IO Pin Read as ) RESET INPUT THRESHOLD VOLTAGE vs. V CC VIL, IO PIN READ AS '',5 5 C -4 C Threshold (V),5,5,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/ 3
24 Figure -8. Reset Pin Input Hysteresis vs. V CC RESET PIN INPUT HYSTERESIS vs. V CC,5,45,4,35-4 C Input Hysteresis (V),3,5,,5, 5 C,5,5,5 3 3,5 4 4,5 5 5,5.7 BOD Threshold and Analog Comparator Offset Figure -9. BOD Threshold vs. Temperature (BOD Level is 4.3V) BOD THRESHOLDS vs. TEMPERATURE BODLEVEL = 4.3V 4,4 4,38 Rising VCC 4,36 Threshold (V) 4,34 4,3 4,3 Falling VCC 4,8 4, Temperature (C) 4 ATtiny5 586N Appendix A AVR 8/
25 ATtiny5 Figure -3. BOD Threshold vs. Temperature (BOD Level is.7v) BOD THRESHOLDS vs. TEMPERATURE BODLEVEL =.7V,8,78 Rising VCC,76 Threshold (V),74,7,7 Falling VCC, Temperature (C) Figure -3. BOD Threshold vs. Temperature (BOD Level is.8v) BOD THRESHOLDS vs. TEMPERATURE BODLEVEL =.8V,85,845 Rising VCC Threshold (V),84,835,83,85,8,85,8 Falling VCC,85,8, Temperature (C) 586N Appendix A AVR 8/ 5
26 Figure -3. Bandgap Voltage vs. Supply Voltage BANDGAP VOLTAGE vs. V CC,,8,6,4 Bandgap Voltage (V),,,8,6,4 5 C -4 C,,5,5 3 3,5 4 4,5 5 5,5 Vcc (V) Figure -33. Bandgap Voltage vs. Temperature BANDGAP VOLTAGE vs. Temperature,,8,6 Bandgap Voltage (V),4,,,8.8 V 3 V 5 V,6,4, Temperature 6 ATtiny5 586N Appendix A AVR 8/
27 ATtiny5.8 Internal Oscillator Speed Figure -34. Watchdog Oscillator Frequency vs. V CC WATCHDOG OSCILLATOR FREQUENCY vs. V CC,8,6,4-4 C F RC (MHz),,,8,6,4, 5 C,,5 3 3,5 4 4,5 5 5,5 Figure -35. Watchdog Oscillator Frequency vs. Temperature WATCHDOG OSCILLATOR FREQUENCY vs. TEMPERATURE,,8,6 FRC (MHz),4,,,8,6.8 V.7 V 3.3 V 4. V 5.5 V, Temperature 586N Appendix A AVR 8/ 7
28 Figure -36. Calibrated 8 MHz RC Oscillator Frequency vs. V CC CALIBRATED 8 MHz RC OSCILLATOR FREQUENCY vs. V CC C 8 F RC (Hz) C ,5,5 3 3,5 4 4,5 5 5,5 Figure -37. Calibrated 8 MHz RC Oscillator Frequency vs. Temperature CALIBRATED 8 MHz RC OSCILLATOR FREQUENCY vs. TEMPERATURE V 3. V 8.8 V F RC (Hz) Temperature 8 ATtiny5 586N Appendix A AVR 8/
29 ATtiny5 Figure -38. Calibrated 8 MHz RC Oscillator Frequency vs. OSCCAL Value CALIBRATED 8.MHz RC OSCILLATOR FREQUENCY vs. OSCCAL VALUE C -4 C F RC (MHz) OSCCAL (X).9 Current Consumption of Peripheral Units Figure -39. Brownout Detector Current vs. V CC BROWNOUT DETECTOR CURRENT vs. V CC BOD level =.8V C -4 C I CC (ua) 5 5,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/ 9
30 Figure -4. ADC Current vs. V CC (AREF = AV CC ) ADC CURRENT vs. VCC AREF = AVCC,5, 5 C -4 C,5 I CC (ma),,5,5,5 3 3,5 4 4,5 5 5,5 Figure -4. Analog Comparator Current vs. V CC ANALOG COMPARATOR CURRENT vs. V CC,7,6,5 I CC (ma),4,3 5 C -4 C,,,5,5 3 3,5 4 4,5 5 5,5 3 ATtiny5 586N Appendix A AVR 8/
31 ATtiny5 Figure -4. Programming Current vs. V CC PROGRAMMING CURRENT vs. Vcc Ext Clk 9-4 C I CC (ma) C,5,5 3 3,5 4 4,5 5 5,5. Current Consumption in Reset and Reset Pulsewidth Figure -43. Minimum Reset Pulse Width vs. V CC MINIMUM RESET PULSE WIDTH vs. V CC 5 Pulsewidth (ns) C -4 C,5,5 3 3,5 4 4,5 5 5,5 586N Appendix A AVR 8/ 3
32 3. Ordering Information Speed (MHz) Power Supply Ordering Code () Package () Operational Range.8-5.5V.7-5.5V ATtiny5V-SN ATtiny5V-SNR ATtiny5V-SSN ATtiny5V-SSNR ATtiny5-SN ATtiny5-SNR ATtiny5-SSN ATtiny5-SSNR Notes:. Code indicators: N: matte tin R: tape & reel. All packages are Pb-free, halide-free and fully green and they comply with the European directive for Restriction of Hazardous Substances (RoHS). 8S 8S S8S S8S 8S 8S S8S S8S Industrial (-4 C to +5 C) Industrial (-4 C to +5 C) Package Type 8S S8S 8-lead,." Wide, Plastic Gull-Wing Small Outline (EIAJ SOIC) 8-lead,.5" Wide, Plastic Gull-Wing Small Outline (JEDEC SOIC) 3 ATtiny5 586N Appendix A AVR 8/
33 ATtiny5 4. Revision History Revision No. History 586A Appendix A AVR 6/ Initial revision 586B Appendix A AVR 7/ Added Ordering Codes -SN and -SNR (package 8S) 586N Appendix A AVR 8/ Removed Preliminary status, updated contact information 586N Appendix A AVR 8/ 33
34 Headquarters International Atmel Corporation 35 Orchard Parkway San Jose, CA 953 USA Tel: (+)(48) 44-3 Fax: (+)(48) Atmel Asia Limited Unit -5 & 6, 9F BEA Tower, Millennium City 5 48 Kwun Tong Road Kwun Tong, Kowloon HONG KONG Tel: (+85) 45-6 Fax: (+85) Atmel Munich GmbH Business Campus Parkring 4 D Garching b. Munich GERMANY Tel: (+49) Fax: (+49) Atmel Japan 9F, Tonetsu Shinkawa Bldg Shinkawa Chuo-ku, Tokyo 4-33 JAPAN Tel: (+8)(3) Fax: (+8)(3) Product Contact Web Site Technical Support avr@atmel.com Sales Contact Literature Requests Disclaimer: The information in this document is provided in connection with Atmel products. No license, express or implied, by estoppel or otherwise, to any intellectual property right is granted by this document or in connection with the sale of Atmel products. EXCEPT AS SET FORTH IN ATMEL S TERMS AND CONDI- TIONS OF SALE LOCATED ON ATMEL S WEB SITE, ATMEL ASSUMES NO LIABILITY WHATSOEVER AND DISCLAIMS ANY EXPRESS, IMPLIED OR STATUTORY WARRANTY RELATING TO ITS PRODUCTS INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTY OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE, OR NON-INFRINGEMENT. IN NO EVENT SHALL ATMEL BE LIABLE FOR ANY DIRECT, INDIRECT, CONSEQUENTIAL, PUNITIVE, SPECIAL OR INCIDEN- TAL DAMAGES (INCLUDING, WITHOUT LIMITATION, DAMAGES FOR LOSS OF PROFITS, BUSINESS INTERRUPTION, OR LOSS OF INFORMATION) ARISING OUT OF THE USE OR INABILITY TO USE THIS DOCUMENT, EVEN IF ATMEL HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES. Atmel makes no representations or warranties with respect to the accuracy or completeness of the contents of this document and reserves the right to make changes to specifications and product descriptions at any time without notice. Atmel does not make any commitment to update the information contained herein. Unless specifically provided otherwise, Atmel products are not suitable for, and shall not be used in, automotive applications. Atmel s products are not intended, authorized, or warranted for use as components in applications intended to support or sustain life. Atmel Corporation. All rights reserved. Atmel, logo and combinations thereof, and others are registered trademarks or trademarks of Atmel Corporation or its subsidiaries. Other terms and product names may be trademarks of others. 586N Appendix A AVR 8/
AVR32138: How to optimize the ADC usage on AT32UC3A0/1, AT32UC3A3 and AT32UC3B0/1 series. 32-bit Microcontrollers. Application Note.
AVR32138: How to optimize the ADC usage on AT32UC3A0/1, AT32UC3A3 and AT32UC3B0/1 series 1 Introduction This application note outlines the steps necessary to optimize analog to digital conversions on AT32UC3A0/1,
More informationAVR125: ADC of tinyavr in Single Ended Mode. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR125: ADC of tinyavr in Single Ended Mode Features Up to 10bit resolution Up to 15kSPS Auto triggered and single conversion mode Optional left adjustment for ADC result readout Driver source code included
More information3-output Laser Driver for HD-DVD/ Blu-ray/DVD/ CD-ROM ATR0885. Preliminary. Summary. Features. Applications. 1. Description
Features Three Selectable Outputs All Outputs Can Be Used Either for Standard (5V) or High Voltage (9V) Maximum Output Current at All Outputs Up to 150 ma On-chip Low-EMI RF Oscillator With Spread-spectrum
More informationAPPLICATION NOTE. Atmel AVR134: Real Time Clock (RTC) Using the Asynchronous Timer. Atmel AVR 8-bit Microcontroller. Introduction.
APPLICATION NOTE Atmel AVR134: Real Time Clock (RTC) Using the Asynchronous Timer Introduction Atmel AVR 8-bit Microcontroller This application note describes how to implement a real time counter (RTC)
More information1Mb (64K x 16) One-time Programmable Read-only Memory
Features Fast read access time 45ns Low-power CMOS operation 100µA max standby 30mA max active at 5MHz JEDEC standard packages 40-lead PDIP 44-lead PLCC Direct upgrade from 512K (Atmel AT27C516) EPROM
More information256K (32K x 8) Battery-Voltage Parallel EEPROMs AT28BV256
Features Single 2.7V - 3.6V Supply Fast Read Access Time 200 ns Automatic Page Write Operation Internal Address and Data Latches for 64 Bytes Internal Control Timer Fast Write Cycle Times Page Write Cycle
More informationAVR1301: Using the XMEGA DAC. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR1301: Using the XMEGA DAC Features 12 bit resolution Up to 1 M conversions per second Continuous drive or sample-and-hold output Built-in offset and gain calibration High drive capabilities Driver source
More informationGeneral Porting Considerations. Memory EEPROM XRAM
AVR097: Migration between ATmega128 and ATmega2561 Features General Porting Considerations Memory Clock sources Interrupts Power Management BOD WDT Timers/Counters USART & SPI ADC Analog Comparator ATmega103
More informationAVR1321: Using the Atmel AVR XMEGA 32-bit Real Time Counter and Battery Backup System. 8-bit Microcontrollers. Application Note.
AVR1321: Using the Atmel AVR XMEGA 32-bit Real Time Counter and Battery Backup System Features 32-bit Real Time Counter (RTC) - 32-bit counter - Selectable clock source 1.024kHz 1Hz - Long overflow time
More informationAVR353: Voltage Reference Calibration and Voltage ADC Usage. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR353: Voltage Reference Calibration and Voltage ADC Usage Features Voltage reference calibration. - 1.100V +/-1mV (typical) and < 90ppm/ C drift from 10 C to +70 C. Interrupt controlled voltage ADC sampling.
More informationAVR1922: Xplain Board Controller Firmware. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR1922: Xplain Board Controller Firmware Features USB interface - Mass-storage to on-board DataFlash memory Atmel AVR XMEGA TM reset control 1 Introduction The Xplain board controller, an AT90USB1287,
More informationAPPLICATION NOTE Atmel AT02509: In House Unit with Bluetooth Low Energy Module Hardware User Guide 8-bit Atmel Microcontroller Features Description
APPLICATION NOTE Atmel AT259: In House Unit with Bluetooth Low Energy Module Hardware User Guide Features 8-bit Atmel Microcontroller Low power consumption Interface with BLE with UART Bi-direction wake
More informationAtmel AVR1017: XMEGA - USB Hardware Design Recommendations. 8-bit Atmel Microcontrollers. Application Note. Features.
Atmel AVR1017: XMEGA - USB Hardware Design Recommendations Features USB 2.0 compliance - Signal integrity - Power consumption - Back driver voltage - Inrush current EMC/EMI considerations Layout considerations
More information64K (8K x 8) Parallel EEPROM with Page Write and Software Data Protection AT28C64B
Features Fast Read Access Time 150 ns Automatic Page Write Operation Internal Address and Data Latches for 64 Bytes Fast Write Cycle Times Page Write Cycle Time: 10 ms Maximum (Standard) 2 ms Maximum (Option
More informationAVR127: Understanding ADC Parameters. Introduction. Features. Atmel 8-bit and 32-bit Microcontrollers APPLICATION NOTE
Atmel 8-bit and 32-bit Microcontrollers AVR127: Understanding ADC Parameters APPLICATION NOTE Introduction This application note explains the basic concepts of analog-to-digital converter (ADC) and the
More informationAT91SAM ARM-based Flash MCU. Application Note
Modbus Slave Stack for the Atmel Family of SAM3 Microcontrollers (Free Modbus Stack from Embedded Solutions) 1. Scope This application note provides directions and instructions to application engineers
More information8-bit. Application Note. Microcontrollers. AVR282: USB Firmware Upgrade for AT90USB
AVR282: USB Firmware Upgrade for AT90USB Features Supported by Atmel FLIP program on all Microsoft O/S from Windows 98SE and later FLIP 3.2.1 or greater supports Linux Default on chip USB bootloader In-System
More informationAtmel AVR4921: ASF - USB Device Stack Differences between ASF V1 and V2. 8-bit Atmel Microcontrollers. Application Note. Features.
Atmel AVR4921: ASF - USB Device Stack Differences between ASF V1 and V2 Features Advantages Implementation differences Integration Migration from stack V1 to stack V2 8-bit Atmel Microcontrollers Application
More informationAtmel AVR4920: ASF - USB Device Stack - Compliance and Performance Figures. Atmel Microcontrollers. Application Note. Features.
Atmel AVR4920: ASF - USB Device Stack - Compliance and Performance Figures Features Compliance to USB 2.0 - Chapters 8 and 9 - Classes: HID, MSC, CDC, PHDC Interoperability: OS, classes, self- and bus-powered
More informationAPPLICATION NOTE. Atmel AT01095: Joystick Game Controller Reference Design. 8-/16-bit Atmel Microcontrollers. Features.
APPLICATION NOTE Features Atmel AT01095: Joystick Game Controller Reference Design 8-/16-bit Atmel Microcontrollers Joystick Game Controller Atmel ATxmega32A4U microcontroller In System Programming (ISP)
More information32-bit AVR UC3 Microcontrollers. 32-bit AtmelAVR Application Note. AVR32769: How to Compile the standalone AVR32 Software Framework in AVR32 Studio V2
AVR32769: How to Compile the standalone AVR32 Software Framework in AVR32 Studio V2 1. Introduction The purpose of this application note is to show how to compile any of the application and driver examples
More informationAVR055: Using a 32kHz XTAL for run-time calibration of the internal RC. 8-bit Microcontrollers. Application Note. Features.
AVR055: Using a 32kHz XTAL for run-time calibration of the internal RC Features Calibration using a 32 khz external crystal Adjustable RC frequency with maximum +/-2% accuracy Tune RC oscillator at any
More informationAVR033: Getting Started with the CodeVisionAVR C Compiler. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR033: Getting Started with the CodeVisionAVR C Compiler Features Installing and Configuring CodeVisionAVR to Work with the Atmel STK 500 Starter Kit and AVR Studio Debugger Creating a New Project Using
More informationAVR1900: Getting started with ATxmega128A1 on STK600. 8-bit Microcontrollers. Application Note. 1 Introduction
AVR1900: Getting started with ATxmega128A1 on STK600 1 Introduction This document contains information about how to get started with the ATxmega128A1 on STK 600. The first three sections contain information
More informationHow To Use An Atmel Atmel Avr32848 Demo For Android (32Bit) With A Microcontroller (32B) And An Android Accessory (32D) On A Microcontroller (32Gb) On An Android Phone Or
APPLICATION NOTE Atmel AVR32848: Android Accessory Demo 32-bit Atmel Microcontrollers Features Control an accessory from an Android device Send data to and from an Android device to an accessory Supported
More information8-bit Microcontroller. Application Note. AVR415: RC5 IR Remote Control Transmitter. Features. Introduction. Figure 1.
AVR415: RC5 IR Remote Control Transmitter Features Utilizes ATtiny28 Special HW Modulator and High Current Drive Pin Size Efficient Code, Leaves Room for Large User Code Low Power Consumption through Intensive
More informationAVR1510: Xplain training - XMEGA USART. 8-bit Microcontrollers. Application Note. Prerequisites. 1 Introduction
AVR1510: Xplain training - XMEGA USART Prerequisites Required knowledge AVR1500: Xplain training XMEGA Basics AVR1502: Xplain training XMEGA Direct Memory Access Controller Software prerequisites Atmel
More informationAVR305: Half Duplex Compact Software UART. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR305: Half Duplex Compact Software UART Features 32 Words of Code, Only Handles Baud Rates of up to 38.4 kbps with a 1 MHz XTAL Runs on Any AVR Device Only Two Port Pins Required Does Not Use Any Timer
More informationAtmel AVR4903: ASF - USB Device HID Mouse Application. Atmel Microcontrollers. Application Note. Features. 1 Introduction
Atmel AVR4903: ASF - USB Device HID Mouse Application Features USB 2.0 compliance - Chapter 9 compliance - HID compliance - Low-speed (1.5Mb/s) and full-speed (12Mb/s) data rates Standard USB HID mouse
More informationAVR1309: Using the XMEGA SPI. 8-bit Microcontrollers. Application Note. Features. 1 Introduction SCK MOSI MISO SS
AVR1309: Using the XMEGA SPI Features Introduction to SPI and the XMEGA SPI module Setup and use of the XMEGA SPI module Implementation of module drivers Polled master Interrupt controlled master Polled
More informationAVR32788: AVR 32 How to use the SSC in I2S mode. 32-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR32788: AVR 32 How to use the SSC in I2S mode Features I²S protocol overview I²S on the AVR32 I²S sample rate configurations Example of use with AT32UC3A on EVK1105 board 32-bit Microcontrollers Application
More informationAPPLICATION NOTE. Atmel AVR443: Sensor-based Control of Three Phase Brushless DC Motor. Atmel AVR 8-bit Microcontrollers. Features.
APPLICATION NOTE Features Atmel AVR443: Sensor-based Control of Three Phase Brushless DC Motor Less than 5µs response time on Hall sensor output change Theoretical maximum of 1600k RPM Over-current sensing
More informationAPPLICATION NOTE. AT03155: Real-Time-Clock Calibration and Compensation. SAM3 / SAM4 Series. Scope
APPLICATION NOTE AT03155: Real-Time-Clock Calibration and Compensation Scope SAM3 / SAM4 Series In most low-cost, low-power systems, the Real Time Clock (RTC) accuracy is inherited from a 32.768kHz crystal
More informationUsing CryptoMemory in Full I 2 C Compliant Mode. Using CryptoMemory in Full I 2 C Compliant Mode AT88SC0104CA AT88SC0204CA AT88SC0404CA AT88SC0808CA
Using CryptoMemory in Full I 2 C Compliant Mode 1. Introduction This application note describes how to communicate with CryptoMemory devices in full I 2 C compliant mode. Full I 2 C compliance permits
More informationAVR319: Using the USI module for SPI communication. 8-bit Microcontrollers. Application Note. Features. Introduction
AVR319: Using the USI module for SPI communication Features C-code driver for SPI master and slave Uses the USI module Supports SPI Mode 0 and 1 Introduction The Serial Peripheral Interface (SPI) allows
More informationAVR115: Data Logging with Atmel File System on ATmega32U4. Microcontrollers. Application Note. 1 Introduction. Atmel
AVR115: Data Logging with Atmel File System on ATmega32U4 Microcontrollers 01101010 11010101 01010111 10010101 Application Note 1 Introduction Atmel provides a File System management for AT90USBx and ATmegaxxUx
More informationAVR1324: XMEGA ADC Selection Guide. 8-bit Atmel Microcontrollers. Application Note. Features. 1 Introduction
AVR1324: XMEGA ADC Selection Guide Features The Atmel AVR XMEGA A family Pipelined architecture Up to 2M samples per second Up to 12-bit resolution Signed and unsigned mode Selectable gain 2MHz maximum
More information3-output Laser Driver for HD-DVD/ Blu-ray/DVD/ CD-ROM ATR0885. Preliminary. Summary
Features Three Selectable Outputs All Outputs Can Be Used Either for Standard (5V) or High Voltage (9V) Maximum Output Current at All Outputs Up to 150 ma On-chip Low-EMI RF Oscillator With Spread-spectrum
More informationAVR151: Setup and Use of the SPI. Introduction. Features. Atmel AVR 8-bit Microcontroller APPLICATION NOTE
Atmel AVR 8-bit Microcontroller AVR151: Setup and Use of the SPI APPLICATION NOTE Introduction This application note describes how to set up and use the on-chip Serial Peripheral Interface (SPI) of the
More informationAVR1600: Using the XMEGA Quadrature Decoder. 8-bit Microcontrollers. Application Note. Features. 1 Introduction. Sensors
AVR1600: Using the XMEGA Quadrature Decoder Features Quadrature Decoders 16-bit angular resolution Rotation speed and acceleration 1 Introduction Quadrature encoders are used to determine the position
More informationApplication Note. Atmel ATSHA204 Authentication Modes. Prerequisites. Overview. Introduction
Application Note Atmel Authentication Modes Prerequisites Hardware Atmel AT88CK454BLACK Evaluation Board Atmel AT88CK109STK8 Kit Software Atmel Crypto Evaluation Studio (ACES) Overview Understand which
More informationAVR32701: AVR32AP7 USB Performance. 32-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR32701: AVR32AP7 USB Performance Features Linux USB bulk transfer performance ATSTK1000 (32-bit SDRAM bus width) ATNGW100 (16-bit SDRAM bus width) GadgetFS driver and gadgetfs-test application USB performance
More informationAVR126: ADC of megaavr in Single Ended Mode. Introduction. Features. AVR 8-bit Microcontrollers APPLICATION NOTE
AVR 8-bit Microcontrollers AVR126: ADC of megaavr in Single Ended Mode APPLICATION NOTE Introduction Atmel megaavr devices have a successive approximation Analog-to- Digital Converter (ADC) capable of
More informationAVR317: Using the Master SPI Mode of the USART module. 8-bit Microcontrollers. Application Note. Features. Introduction
AVR317: Using the Master SPI Mode of the USART module Features Enables Two SPI buses in one device Hardware buffered SPI communication Polled communication example Interrupt-controlled communication example
More information8051 Flash Microcontroller. Application Note. A Digital Thermometer Using the Atmel AT89LP2052 Microcontroller
A Digital Thermometer Using the Atmel AT89LP2052 Microcontroller Features Temperature range -55 C to +125 C in.5 C increments LCD Display RS485 Interface Applicable to any AT89LP Microcontroller C and
More informationApplication Note. 8-bit Microcontrollers. AVR270: USB Mouse Demonstration
AVR270: USB Mouse Demonstration Features Runs with AT90USB Microcontrollers at 8MHz USB Low Power Bus Powered Device (less then 100mA) Supported by any PC running Windows (98SE or later), Linux or Mac
More informationDescription. Table 1. Device summary. Order code Temperature range Package Packaging Marking
14-stage ripple carry binary counter/divider and oscillator Applications Automotive Industrial Computer Consumer Description Datasheet - production data Features Medium speed operation Common reset Fully
More informationAPPLICATION NOTE. Atmel AT04389: Connecting SAMD20E to the AT86RF233 Transceiver. Atmel SAMD20. Description. Features
APPLICATION NOTE Atmel AT04389: Connecting SAMD20E to the AT86RF233 Transceiver Description Atmel SAMD20 This application note describes a method to connect an Atmel ATSAMD20E microcontroller to an Atmel
More informationAVR134: Real Time Clock (RTC) using the Asynchronous Timer. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR134: Real Time Clock (RTC) using the Asynchronous Timer Features Real Time Clock with Very Low Power Consumption (4 μa @ 3.3V) Very Low Cost Solution Adjustable Prescaler to Adjust Precision Counts
More informationAVR1318: Using the XMEGA built-in AES accelerator. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR1318: Using the XMEGA built-in AES accelerator Features Full compliance with AES (FIPS Publication 197, 2002) - Both encryption and decryption procedures 128-bit Key and State memory XOR load option
More informationNTE2053 Integrated Circuit 8 Bit MPU Compatible A/D Converter
NTE2053 Integrated Circuit 8 Bit MPU Compatible A/D Converter Description: The NTE2053 is a CMOS 8 bit successive approximation Analog to Digital converter in a 20 Lead DIP type package which uses a differential
More informationAVR120: Characterization and Calibration of the ADC on an AVR. 8-bit Microcontrollers. Application Note. Features. Introduction
AVR120: Characterization and Calibration of the ADC on an AVR Features Understanding Analog to Digital Converter (ADC) characteristics Measuring parameters describing ADC characteristics Temperature, frequency
More informationCold-Junction-Compensated K-Thermocoupleto-Digital Converter (0 C to +1024 C)
19-2235; Rev 1; 3/02 Cold-Junction-Compensated K-Thermocoupleto-Digital General Description The performs cold-junction compensation and digitizes the signal from a type-k thermocouple. The data is output
More informationAtmel AT32UC3A3256 microcontroller 64MBit SDRAM Analog input (to ADC) Temperature sensor RC filter
APPLICATION NOTE Features Atmel AVR32918: UC3-A3 Xplained Hardware User s Guide Atmel AT32UC3A3256 microcontroller 64MBit SDRAM Analog input (to ADC) Temperature sensor RC filter I/O One mechanical button
More informationAPPLICATION NOTE. Atmel LF-RFID Kits Overview. Atmel LF-RFID Kit. LF-RFID Kit Introduction
APPLICATION NOTE Atmel LF-RFID Kits Overview Atmel LF-RFID Kit LF-RFID Kit Introduction Atmel offers several design and evaluation kits for a fast and easy way to test the LF-RFID technology but also developing
More information2-wire Serial EEPROM AT24C512
Features Low-voltage and Standard-voltage Operation 5.0 (V CC = 4.5V to 5.5V). (V CC =.V to 5.5V). (V CC =.V to.v) Internally Organized 5,5 x -wire Serial Interface Schmitt Triggers, Filtered Inputs for
More informationICS650-44 SPREAD SPECTRUM CLOCK SYNTHESIZER. Description. Features. Block Diagram DATASHEET
DATASHEET ICS650-44 Description The ICS650-44 is a spread spectrum clock synthesizer intended for video projector and digital TV applications. It generates three copies of an EMI optimized 50 MHz clock
More informationAVR131: Using the AVR s High-speed PWM. Introduction. Features. AVR 8-bit Microcontrollers APPLICATION NOTE
AVR 8-bit Microcontrollers AVR131: Using the AVR s High-speed PWM APPLICATION NOTE Introduction This application note is an introduction to the use of the high-speed Pulse Width Modulator (PWM) available
More informationApplication Note. C51 Bootloaders. C51 General Information about Bootloader and In System Programming. Overview. Abreviations
C51 General Information about Bootloader and In System Programming Overview This document describes the Atmel Bootloaders for 8051 family processors. Abreviations ISP: In-System Programming API : Applications
More informationAVR1003: Using the XMEGA Clock System. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR1003: Using the XMEGA Clock System Features Internal 32 khz, 2 MHz, and 32 MHz oscillators External crystal oscillator or clock input Internal PLL with multiplication factor 1x to 31x Safe clock source
More informationThe 74LVC1G11 provides a single 3-input AND gate.
Rev. 8 17 September 2015 Product data sheet 1. General description The provides a single 3-input AND gate. The input can be driven from either 3.3 V or 5 V devices. This feature allows the use of this
More informationHEF4011B. 1. General description. 2. Features and benefits. 3. Ordering information. 4. Functional diagram. Quad 2-input NAND gate
Rev. 6 10 December 2015 Product data sheet 1. General description 2. Features and benefits 3. Ordering information The is a quad 2-input NAND gate. The outputs are fully buffered for the highest noise
More informationAtmel AVR ATxmega384C3 microcontroller OLED display with 128 32 pixels resolution Analog sensors. Ambient light sensor Temperature sensor
APPLICATION NOTE AVR1925: XMEGA-C3 Xplained Hardware User s Guide Features Atmel AVR ATxmega384C3 microcontroller OLED display with 128 32 pixels resolution Analog sensors Ambient light sensor Temperature
More information1-of-4 decoder/demultiplexer
Rev. 6 1 April 2016 Product data sheet 1. General description 2. Features and benefits 3. Applications The contains two 1-of-4 decoders/demultiplexers. Each has two address inputs (na0 and na1, an active
More informationApplication Note. 8-bit Microcontrollers. AVR272: USB CDC Demonstration UART to USB Bridge
AVR272: USB CDC Demonstration UART to USB Bridge Features Supported by Windows 2000 or later No driver installation Virtual COM Port Enumeration USB to RS232 Bridge with dynamic baudrate Bus powered 8-bit
More informationUSER GUIDE EDBG. Description
USER GUIDE EDBG Description The Atmel Embedded Debugger (EDBG) is an onboard debugger for integration into development kits with Atmel MCUs. In addition to programming and debugging support through Atmel
More informationAVR2006: Design and characterization of the Radio Controller Board's 2.4GHz PCB Antenna. Application Note. Features.
AVR26: Design and characterization of the Radio Controller Board's 2.4GHz PCB Antenna Features Radiation pattern Impedance measurements WIPL design files NEC model Application Note 1 Introduction This
More informationNE555 SA555 - SE555. General-purpose single bipolar timers. Features. Description
NE555 SA555 - SE555 General-purpose single bipolar timers Features Low turn-off time Maximum operating frequency greater than 500 khz Timing from microseconds to hours Operates in both astable and monostable
More informationAT15007: Differences between ATmega328/P and ATmega328PB. Introduction. Features. Atmel AVR 8-bit Microcontrollers APPLICATION NOTE
Atmel AVR 8-bit Microcontrollers AT15007: Differences between ATmega328/P and ATmega328PB APPLICATION NOTE Introduction This application note assists the users of Atmel ATmega328 variants to understand
More informationICS514 LOCO PLL CLOCK GENERATOR. Description. Features. Block Diagram DATASHEET
DATASHEET ICS514 Description The ICS514 LOCO TM is the most cost effective way to generate a high-quality, high-frequency clock output from a 14.31818 MHz crystal or clock input. The name LOCO stands for
More information1 TO 4 CLOCK BUFFER ICS551. Description. Features. Block Diagram DATASHEET
DATASHEET 1 TO 4 CLOCK BUFFER ICS551 Description The ICS551 is a low cost, high-speed single input to four output clock buffer. Part of IDT s ClockBlocks TM family, this is our lowest cost, small clock
More informationHCC4541B HCF4541B PROGRAMMABLE TIMER
HCC4541B HCF4541B PROGRAMMABLE TIMER 16 STAGE BINARI COUNTER LOW SYMMETRICAL OUTPUT RESISTANCE, TYPICALLY 100 OHM AT DD = 15 OSCILLATOR FREQUENCY RANGE : DC TO 100kHz AUTO OR MASTER RESET DISABLES OSCIL-
More informationHEF4021B. 1. General description. 2. Features and benefits. 3. Ordering information. 8-bit static shift register
Rev. 10 21 March 2016 Product data sheet 1. General description 2. Features and benefits 3. Ordering information The is an (parallel-to-serial converter) with a synchronous serial data input (DS), a clock
More informationTRIPLE PLL FIELD PROG. SPREAD SPECTRUM CLOCK SYNTHESIZER. Features
DATASHEET ICS280 Description The ICS280 field programmable spread spectrum clock synthesizer generates up to four high-quality, high-frequency clock outputs including multiple reference clocks from a low-frequency
More informationDATA SHEET. TDA1543 Dual 16-bit DAC (economy version) (I 2 S input format) INTEGRATED CIRCUITS
INTEGRATED CIRCUITS DATA SHEET File under Integrated Circuits, IC01 February 1991 FEATURES Low distortion 16-bit dynamic range 4 oversampling possible Single 5 V power supply No external components required
More informationAVR287: USB Host HID and Mass Storage Demonstration. 8-bit Microcontrollers. Application Note. Features. 1 Introduction
AVR287: USB Host HID and Mass Storage Demonstration Features Based on AVR USB OTG Reduced Host Runs on AT90USB647/1287 Support bootable/non-bootable standard USB mouse Support USB Hub feature (Mass Storage
More informationApplication Note. Atmel CryptoAuthentication Product Uses. Atmel ATSHA204. Abstract. Overview
Application Note Atmel CryptoAuthentication Product Uses Atmel Abstract Companies are continuously searching for ways to protect property using various security implementations; however, the cost of security
More informationTwo-wire Automotive Serial EEPROM AT24C01A AT24C02 AT24C04 AT24C08 (1) AT24C16 (2)
Features Medium-voltage and Standard-voltage Operation 5.0 (V CC = 4.5V to 5.5V) 2.7 (V CC = 2.7V to 5.5V) Internally Organized 128 x 8 (1K), 256 x 8 (2K), 512 x 8 (4K), 1024 x 8 (8K) or 2048 x 8 (16K)
More informationQuad 2-input NAND Schmitt trigger
Rev. 9 15 December 2015 Product data sheet 1. General description 2. Features and benefits 3. Applications The is a quad two-input NAND gate. Each input has a Schmitt trigger circuit. The gate switches
More informationNE555 SA555 - SE555. General-purpose single bipolar timers. Features. Description
NE555 SA555 - SE555 General-purpose single bipolar timers Features Low turn-off time Maximum operating frequency greater than 500 khz Timing from microseconds to hours Operates in both astable and monostable
More information8-bit RISC Microcontroller. Application Note. AVR182: Zero Cross Detector
AVR182: Zero Cross Detector Features Interrupt Driven Modular C Source Code Size Efficient Code Accurate and Fast Detection A Minimum of External Components Introduction One of the many issues with developing
More informationLOW POWER SPREAD SPECTRUM OSCILLATOR
LOW POWER SPREAD SPECTRUM OSCILLATOR SERIES LPSSO WITH SPREAD-OFF FUNCTION 1.0 110.0 MHz FEATURES + 100% pin-to-pin drop-in replacement to quartz and MEMS based XO + Low Power Spread Spectrum Oscillator
More informationAPPLICATION NOTE. Atmel AT02985: User s Guide for USB-CAN Demo on SAM4E-EK. Atmel AVR 32-bit Microcontroller. Features. Description.
APPLICATION NOTE Atmel AT02985: User s Guide for USB-CAN Demo on SAM4E-EK Atmel AVR 32-bit Microcontroller Features USB-CAN gateway USB CDC class (virtual serial port) provides low level data stream Customized
More informationcss Custom Silicon Solutions, Inc.
css Custom Silicon Solutions, Inc. GENERAL PART DESCRIPTION The is a micropower version of the popular timer IC. It features an operating current under µa and a minimum supply voltage of., making it ideal
More informationDG2302. High-Speed, Low r ON, SPST Analog Switch. Vishay Siliconix. (1-Bit Bus Switch with Level-Shifter) RoHS* COMPLIANT DESCRIPTION FEATURES
High-Speed, Low r ON, SPST Analog Switch (1-Bit Bus Switch with Level-Shifter) DG2302 DESCRIPTION The DG2302 is a high-speed, 1-bit, low power, TTLcompatible bus switch. Using sub-micron CMOS technology,
More informationTS555. Low-power single CMOS timer. Description. Features. The TS555 is a single CMOS timer with very low consumption:
Low-power single CMOS timer Description Datasheet - production data The TS555 is a single CMOS timer with very low consumption: Features SO8 (plastic micropackage) Pin connections (top view) (I cc(typ)
More information8-bit Microcontroller. Application Note. AVR134: Real-Time Clock (RTC) using the Asynchronous Timer. Features. Theory of Operation.
AVR134: Real-Time Clock (RTC) using the Asynchronous Timer Features Real-Time Clock with Very Low Power Consumption (4µA @ 3.3V) Very Low Cost Solution Adjustable Prescaler to Adjust Precision Counts Time,
More informationSMARTCARD XPRO. Preface. SMART ARM-based Microcontrollers USER GUIDE
SMART ARM-based Microcontrollers SMARTCARD XPRO USER GUIDE Preface Atmel SMARTCARD Xplained Pro is an extension board to the Atmel Xplained Pro evaluation platform. Atmel SMARTCARD Xplained Pro is designed
More informationHow To Design An Ism Band Antenna For 915Mhz/2.4Ghz Ism Bands On A Pbbb (Bcm) Board
APPLICATION NOTE Features AT09567: ISM Band PCB Antenna Reference Design Atmel Wireless Compact PCB antennas for 915MHz and 2.4GHz ISM bands Easy to integrate Altium design files and gerber files Return
More informationR EXT THERMISTOR. Maxim Integrated Products 1
19-2219; Rev 0; 2/02 Thermistor-to-Digital Converter General Description The converts an external thermistor s temperature-dependent resistance directly into digital form. The thermistor and an external
More informationFM75 Low-Voltage Two-Wire Digital Temperature Sensor with Thermal Alarm
Low-Voltage Two-Wire Digital Temperature Sensor with Thermal Alarm Features User Configurable to 9, 10, 11 or 12-bit Resolution Precision Calibrated to ±1 C, 0 C to 100 C Typical Temperature Range: -40
More informationVN05N. High side smart power solid state relay PENTAWATT. Features. Description
High side smart power solid state relay Features Type V DSS R DS(on) I OUT V CC VN05N 60 V 0.18 Ω 13 A 26 V Output current (continuous): 13A @ Tc=25 C 5V logic level compatible input Thermal shutdown Under
More information14-stage ripple-carry binary counter/divider and oscillator
Rev. 8 25 March 2016 Product data sheet 1. General description 2. Features and benefits 3. Ordering information The is a with three oscillator terminals (RS, REXT and CEXT), ten buffered outputs (Q3 to
More information8-Bit Flash Microcontroller for Smart Cards. AT89SCXXXXA Summary. Features. Description. Complete datasheet available under NDA
Features Compatible with MCS-51 products On-chip Flash Program Memory Endurance: 1,000 Write/Erase Cycles On-chip EEPROM Data Memory Endurance: 100,000 Write/Erase Cycles 512 x 8-bit RAM ISO 7816 I/O Port
More informationICS379. Quad PLL with VCXO Quick Turn Clock. Description. Features. Block Diagram
Quad PLL with VCXO Quick Turn Clock Description The ICS379 QTClock TM generates up to 9 high quality, high frequency clock outputs including a reference from a low frequency pullable crystal. It is designed
More information74HC377; 74HCT377. 1. General description. 2. Features and benefits. 3. Ordering information
Rev. 4 24 February 2016 Product data sheet 1. General description 2. Features and benefits 3. Ordering information The is an octal positive-edge triggered D-type flip-flop. The device features clock (CP)
More informationHigh-Speed, Low r ON, SPST Analog Switch (1-Bit Bus Switch)
High-Speed, Low r ON, SPST Analog Switch (1-Bit Bus Switch) DG2301 ishay Siliconix DESCRIPTION The DG2301 is a high-speed, 1-bit, low power, TTLcompatible bus switch. Using sub-micron CMOS technology,
More informationLow-Jitter I 2 C/SPI Programmable Dual CMOS Oscillator
eet General Description The DSC2111 and series of programmable, highperformance dual CMOS oscillators utilizes a proven silicon MEMS technology to provide excellent jitter and stability while incorporating
More information5 V, 1 A H-Bridge Motor Driver
, A H-Bridge Motor Driver DESCRIPTION The SIP200 is an integrated, buffered H-bridge with TTL and CMOS compatible inputs with the capability of delivering up to A continuous current at DD supply. The SIP200
More informationINTEGRATED CIRCUITS. 74LVC08A Quad 2-input AND gate. Product specification IC24 Data Handbook. 1997 Jun 30
INTEGRATED CIRCUITS IC24 Data Handbook 1997 Jun 30 FEATURES Wide supply voltage range of 1.2 V to 3.6 V In accordance with JEDEC standard no. 8-1A Inputs accept voltages up to 5.5 V CMOS low power consumption
More information