YW80C196NU40

Datasheet 8XC196KC Commercial/Express CHMOS Microcontroller The 80C196KC 16-bit microcontroller is a high performance member of the MCS® 96 microcontroller family. The 80C196KC is an enhanced 80C196KB device with 488 bytes RAM, 16 and 20 MHz operation and an optional 16 Kbytes of ROM/OTPR OM. This CHMOS III process provides a high performance processor along with low power consumption. Rochester Electronics Manufactured Components Rochester branded components are manufactured using either die/wafers purchased from the original suppliers or Rochester wafers recreated from the original IP. All re-creations are done with the approval of the Original Component Manufacturer (OCM). Parts are tested using original factory test programs or Rochester developed test solutions to guarantee product meets or exceeds the OCM data sheet. Quality Overview • ISO-9001 • AS9120 certification • Qualified Manufacturers List (QML) MIL-PRF-35835 • Class Q Military • Class V Space Level • Qualified Suppliers List of Distributors (QSLD) • Rochester is a critical supplier to DLA and meets all industry and DLA standards. Rochester Electronics, LLC is committed to supplying products that satisfy customer expectations for quality and are equal to those originally supplied by industry manufacturers. The original manufacturer’s datasheet accompanying this document reflects the performance and specifications of the Rochester manufactured version of this device. Rochester Electronics guarantees the performance of its semiconductor products to the original OCM specifications. ‘Typical’ values are for reference purposes only. Certain minimum or maximum ratings may be based on product characterization, design, simulation, or sample testing. FOR REFERENCE ONLY © 2018 Rochester Electronics, LLC. All Rights Reserved 10082018 To learn more, please visit www.rocelec.com 8XC196KC/8XC196KC20 COMMERCIAL/EXPRESS CHMOS MICROCONTROLLER 87C196KC-16 Kbytes of On-Chip OTPROM 83C196KC-16 Kbytes ROM 80C196KC-ROMless 16 and 20 MHz Available Dynamically Configurable 8-Bit or 16-Bit Buswidth 488 Byte Register RAM Register-to-Register Architecture 28 Interrupt Sources/16 Vectors Peripheral Transaction Server 1.4 s 16 x 16 Multiply (20 MHz) 2.4 s 32/16 Divide (20 MHz) Powerdown and Idle Modes Five 8-Bit I/O Ports 16-Bit Watchdog Timer Extended Temperature Available Full Duplex Serial Port High Speed I/O Subsystem 16-Bit Timer 16-Bit Up/Down Counter with Capture 3 Pulse-Width-Modulated Outputs Four 16-Bit Software Timers 8- or 10-Bit A/D Converter with Sample/Hold HOLD/HLDA Bus Protocol OTPROM One-Time Programmable Version The 80C196KC 16-bit microcontroller is a high performance member of the MCS 96 microcontroller family. The 80C196KC is an enhanced 80C196KB device with 488 bytes RAM, 16 and 20 MHz operation and an optional 16 Kbytes of ROM/OTPR OM. Intel's CHMOS III process provides a high performance processor along with low power consumption. The 87C196KC is an 80C196KC with 16 Kbytes on-chip OTPROM. The 83C196KC is an 80C196KC with 16 Kbytes factory programmed ROM. In this document, the 80C196KC will refer to all products unless otherwise stated. Four high-speed capture inputs are provided to record times when events occur. Six high-speed outputs are available for pulse or waveform generation. The high-speed output can also generate four software timers or start an A/D conversion. Events can be based on the timer or up/down counter. With the commercial (standard) temperature option, operational characteristics are guaranteed over the temperature range of 0 C to 70 C. With the extended (Express) temperature range option, operational characteristics are guaranteed over the temperature range of 40 C to 85 C. Unless otherwise noted, the specifications are the same for both options. See the Packaging information for extended temperature designators. Other brands and names are the property of their respective owners. Information in this document is provided in connection with Intel products. Intel assumes no liability whatsoever, including infringement of any patent or copyright, for sale and use of Intel products except as provided in Intel's Terms and Conditions of Sale for such products. Intel retains the right to make changes to these specifications at any time, without notice. Microcomputer Products may have minor variations to this specification known as errata. COPYRIGHT July 2004 Order Number:270942-006 8XC196KC/8XC196KC20 270942 ±1 Figure 1. 8XC196KC Block Diagram IOC3 (0CH HWIN1 READ/WRITE) 270942 ±45 NOTE: RSV-Reserved bits must be 0 Figure 2. 8XC196KC New SFR Bit (CLKOUT Disable) 2 8XC196KC/8XC196KC20 Table 2. 8XC196KC Memory Map PROCESS INFORMATION Description NOTE: Figure 3. The 8XC196KC Family Nomenclature Table 1. Thermal Characteristics Package Type ja jc NOTES Address 8XC196KC/8XC196KC20 Figure 6. 80-Pin SQFP Package 8XC196KC/8XC196KC20 PIN DESCRIPTIONS Symbol Name and Function VCC Main supply voltage (5V). VSS Digital circuit ground (0V). There are multiple VSS pins, all of which must be connected. VREF Reference voltage for the A/D converter (5V). VREF is also the supply voltage to the analog portion of the A/D converter and the logic used to read Port 0. Must be connected for A/D and Port 0 to function. ANGND Reference ground for the A/D converter. Must be held at nominally the same potential as VSS. VPP Timing pin for the return from powerdown circuit. This pin also supplies the programming voltage on the EPROM device. XTAL1 Input of the oscillator inverter and of the internal clock generator. XTAL2 Output of the oscillator inverter. CLKOUT Output of the internal clock generator. The frequency of CLKOUT is frequency. RESET Reset input and open drain output. BUSWIDTH Input for buswidth selection. If CCR bit 1 is a one, this pin selects the bus width for the bus cycle in progress. If BUSWIDTH is a 1, a 16-bit bus cycle occurs. If BUSWIDTH is a 0 an 8-bit cycle occurs. If CCR bit 1 is a 0, the bus is always an 8-bit bus. NMI A positive transition causes a vector through 203EH. INST Output high during an external memory read indicates the read is an instruction fetch. INST is valid throughout the bus cycle. INST is activated only during external memory accesses and output low for a data fetch. EA Input for memory select (External Access). EA equal high causes memory accesses to locations 2000H through 5FFFH to be directed to on-chip ROM/E PROM. EA equal to low causes accesses to those locations to be directed to off-chip memory. Also used to enter programming mode. ALE/ADV Address Latch Enable or Address Valid output, as selected by CCR. Both pin options provide a signal to demultiplex the address from the address/data bus. When the pin is ADV, it goes inactive high at the end of the bus cycle. ALE/ADV is activated only during external memory accesses. RD Read signal output to external memory. RD is activated only during external memory reads. WR/WRL Write and Write Low output to external memory, as selected by the CCR. WR will go low for every external write, while WRL will go low only for external writes where an even byte is being written. WR/WRL is activated only during external memory writes. BHE/WRH Bus High Enable or Write High output to external memory, as selected by the CCR. BHE will go low for external writes to the high byte of the data bus. WRH will go low for external writes where an odd byte is being written. BHE/WRH is activated only during external memory writes. READY Ready input to lengthen external memory cycles, for interfacing to slow or dynamic memory, or for bus sharing. When the external memory is not being used, READY has no effect. HSI Inputs to High Speed Input Unit. Four HSI pins are available: HSI.0, HSI.1, HSI.2 and HSI.3. Two of them (HSI.2 and HSI.3) are shared with the HSO Unit. HSO Outputs from High Speed Output Unit. Six HSO pins are available: HSO.0, HSO.1, HSO.2, HSI.3, HSO.4 and HSO.5. Two of them (HSO.4 and HSO.5) are shared with the HSI Unit. Port 0 8-bit high impedance input-only port. These pins can be used as digital inputs and/or as analog inputs to the on-chip A/D converter. Port 1 8-bit quasi-bidirectional I/O port. Port 2 8-bit multi-functional port. All of its pins are shared with other functions in the 80C196KC. Pins 2.6 and 2.7 are quasi-bidirectional. the oscillator 7 8XC196KC/8XC196KC20 PIN DESCRIPTIONS (Continued) Symbol 8 Name and Function Ports 3 and 4 8-bit bidirectional I/O ports with open drain outputs. These pins are shared with the multiplexed address/data bus which has strong internal pullups. HOLD Bus Hold input requesting control of the bus. HLDA Bus Hold acknowledge output indicating release of the bus. BREQ Bus Request output activated when the bus controller has a pending external memory cycle. PMODE Determines the EPROM programming mode. PACT A low signal in Auto Programming mode indicates that programming is in process. A high signal indicates programming is complete. CPVER Cummulative Program Output Verification. Pin is high if all locations have programmed correctly since entering a programming mode. PALE A falling edge in Slave Programming Mode and Auto Configuration Byte Programming Mode indicates that ports 3 and 4 contain valid programming address/command information (input to slave). PROG A falling edge in Slave Programming Mode indicates that ports 3 and 4 contain valid programming data (input to slave). PVER A high signal in Slave Programmig Mode and Auto Configuration Byte Programming Mode indicates the byte programmed correctly. AINC Auto Increment. Active low input signal indicates that the auto increment mode is enabled. Auto Increment will allow reading or writing of sequential EPROM locations without address transactions across the PBUS for each read or write. 8XC196KC/8XC196KC20 ELECTRICAL CHARACTERISTICS ABSOLUTE MAXIMUM RATINGS NOTICE: This is a production data sheet. It is valid for the devices indicated in the revision history. The specifications are subject to change without notice. Ambient Temperature Under Bias.....................................-55° to +125°C Storage Temperature.........................-65° to +150°C Voltage On Any Pin to VSS.................-0.5V to +7.0V(1) Voltage from EA or VPP to VSS or ANGND..............................+13.00V Power Dissipation...........................................1.5W (2) NOTE: 1. This includes VPP and EA on ROM or CPU only devices. 2. Power dissipation is based on package heat transfer limitations, not device power consumption. OPERATING CONDITIONS Symbol Description Min TA Ambient Temperature Under Bias Commercial Temp. TA Ambient Temperature Under Bias Extended Temp. VCC Digital Supply Voltage Max Units 0 70 C 40 85 C 4.50 5.50 V VREF Analog Supply Voltage ANGND Analog Ground Voltage 4.00 FOSC Oscillator Frequency (8XC196KC) 8 16 MHz FOSC Oscillator Frequency (8XC196KC20) 8 20 MHz VSS 5.50 0.4 VSS 0.4 V V(1) NOTE: 1. ANGND and VSS should be nominally at the same potential. DC CHARACTERISTICS (Over Specified Operating Conditions) Symbol Description Min Typ VIL Input Low Voltage VIH Input High Voltage (Note 1) VIH1 Input High Voltage on XTAL 1 VIH2 Input High Voltage on RESET VHYS Hysteresis on RESET 300 VOL Output Low Voltage VOL1 Output Low Voltage in RESET on P2.5 (Note 2) VOH Output High Voltage (Standard Outputs) 0.5 0.2 VCC Max Units 0.8 V VCC 0.5 V 0.7 VCC VCC 0.5 V 2.2 VCC 0.5 V VCC VCC VCC 1.0 0.3 0.7 1.5 TestConditions mV VCC 5.0V 0.3 0.45 1.5 V V V IOL IOL IOL 200 A 2.8 mA 7 mA 0.8 V IOL 0.4 mA V V V IOH IOH IOH 200 A 3.2 mA 7 mA 9 8XC196KC/8XC196KC20 DC CHARACTERISTICS (Over Specified Operating Conditions) (Continued) Symbol Description Min VOH1 Output High Voltage (Quasi-bidirectional Outputs) VCC VCC VCC IOH1 Logical 1 Output Current in Reset. on P2.0. Do not exceed this or device may enter test modes. IIL2 Logical 0 Input Current in Reset on P2.0. Maximum current that must be sunk by external device to ensure test mode entry. IIH1 Logical 1 Input Current. Maximum current that external device must source to initiate NMI. ILI ILI1 ITL Typ Max 0.3 0.7 1.5 Units TestConditions V V V IOH IOH IOH mA VIH VCC mA VIN 0.45V 200 A VIN VCC Input Leakage Current (Std. Inputs) 10 A 0 VIN VCC Input Leakage Current (Port 0) 3 A 0 VIN VREF 1 to 0 Transition Current (QBD Pins) 650 A VIN 2.0V IIL Logical 0 Input Current (QBD Pins) 70 A VIN 0.45V IIL1 Ports 3 and 4 in Reset 70 A VIN 0.45V ICC Active Mode Current in Reset (8XC196KC) 65 ICC Active Mode Current in Reset (8XC196KC20) 80 92 mA IIDLE Idle Mode Current (8XC196KC) 17 25 mA XTAL1 16 MHz VCC VPP VREF 5.5V IIDLE Idle Mode Current (8XC196KC20) 21 30 mA 5.5V IPD Powerdown Mode Current 8 15 A XTAL1 20 MHz VCC VPP VREF VCC VPP VREF IREF A/D Converter Reference Current 5 mA VCC VPP 5.5V RRST Reset Pullup Resistor VCC 5.5V, VIN CS Pin Capacitance (Any Pin to VSS) 0.8 TBD 2 6K 75 mA 65K 10 10 A 30 A 60 A 1.5V 2.4V 0.3V XTAL1 16 MHz VCC VPP VREF XTAL1 20 MHz VCC VPP VREF VREF 5.5V 5.5V 5.5V 4.0V pF NOTES: 1. All pins except RESET and XTAL1. 2. Violating these specifications in Reset may cause the part to enter test modes. 3. Commercial specifications apply to express parts except where noted. 4. QBD (Quasi-bidirectional) pins include Port 1, P2.6 and P2.7. 5. Standard Outputs include AD0 ±15, RD, WR, ALE, BHE, INST, HSO pins, PWM/P2.5, CLKOUT, RESET, Ports 3 and 4, TXD/P2.0 and RXD (in serial mode 0). The VOH specification is not valid for RESET. Ports 3 and 4 are open-drain outputs. 6. Standard Inputs include HSI pins, READY, BUSWIDTH, RXD/P2.1, EXTINT/P2.2, T2CLK/P2.3 and T2RST/P2.4. 7. Maximum current per pin must be externally limited to the following values if VOL is held above 0.45V or VOH is held below VCC 0.7V: IOL on Output pins: 10 mA IOH on quasi-bidirectional pins: self limiting IOH on Standard Output pins: 10 mA 8. Maximum current per bus pin (data and control) during normal operation is 3.2 mA. 9. During normal (non-transient) conditions the following total current limits apply: Port 1, P2.6 IOL: 29 mA IOH is self limiting HSO, P2.0, RXD, RESET IOL: 29 mA IOH: 26 mA P2.5, P2.7, WR, BHE IOL: 13 mA IOH: 11 mA AD0 ±AD15 IOL: 52 mA IOH: 52 mA RD, ALE, INST±CLKOUT IOL: 13 mA IOH: 13 mA 10 8XC196KC/8XC196KC20 270942 ±17 ICC Max 4.13 Frequency 9 mA ICC Typ 3.50 Frequency 9 mA IIDLE Max 1.25 Frequency 5 mA IIDLE Typ 0.88 Frequency 3 mA NOTE: Frequencies below 8 MHz are shown for reference only; no testing is performed. Figure 7. I CC and I IDLE vs Frequency AC CHARACTERISTICS For use over specified operating conditions. Test Conditions: Capacitive load on all pins 100 pF, Rise and fall times The system must meet these specifications Symbol Description 10 ns, FOSC 16 MHz to work with the 80C196KC: Min Max Units 2 TOSC 68 Notes TAVYV Address Valid to READY Setup TYLYH Non READY Time TCLYX READY Hold after CLKOUT Low TLLYX READY Hold after ALE Low TAVGV Address Valid to Buswidth Setup TCLGX Buswidth Hold after CLKOUT Low TAVDV Address Valid to Input Data Valid ns (Note 2) TRLDV RD Active to Input Data Valid TOSC 22 ns (Note 2) TCLDV CLKOUT Low to Input Data Valid TOSC 45 ns TRHDZ End of RD to Input Data Float TRXDX Data Hold after RD Inactive No upper limit 0 TOSC TOSC 15 30 2 TOSC 40 2 TOSC 68 0 ns (Note 1) ns (Note 1) ns ns 3 TOSC TOSC 0 ns ns 55 ns ns NOTES: 1. If max is exceeded, additional wait states will occur. 2. If wait states are used, add 2 TOSC N, where N number of wait states. 11 8XC196KC/8XC196KC20 AC CHARACTERISTICS (Continued) For user over specified operating conditions. Test Conditions: Capacitive load on all pins 100 pF, Rise and fall times 10 ns, FOSC 16 MHz The 80C196KC will meet these specifications: Symbol Description Min Max Units Notes FXTAL Frequency on XTAL1 (8XC196KC) 8 16 MHz (Note 1) FXTAL Frequency on XTAL1 (8XC196KC20) 8 20 MHz (Note 1) TOSC I/F XTAL (8XC196KC) 62.5 125 ns TOSC I/F XTAL (8XC196KC20) 50 125 ns TXHCH XTAL1 High to CLKOUT High or Low TCLCL CLKOUT Cycle Time TCHCL CLKOUT High Period TCLLH CLKOUT Falling Edge to ALE Rising TLLCH ALE Falling Edge to CLKOUT Rising TLHLH ALE Cycle Time TLHLL ALE High Period TOSC 10 TAVLL Address Setup to ALE Falling Edge TOSC 15 TLLAX Address Hold after ALE Falling Edge TOSC 35 ns TLLRL ALE Falling Edge to RD Falling Edge TOSC 30 ns TRLCL RD Low to CLKOUT Falling Edge TRLRH RD Low Period TRHLH RD Rising Edge to ALE Rising Edge TRLAZ RD Low to Address Float TLLWL ALE Falling Edge to WR Falling Edge TCLWL CLKOUT Low to WR Falling Edge TQVWH Data Stable to WR Rising Edge TCHWH CLKOUT High to WR Rising Edge TWLWH WR Low Period TOSC 20 ns TWHQX Data Hold after WR Rising Edge TOSC 25 ns TWHLH WR Rising Edge to ALE Rising Edge TOSC 10 TWHBX BHE, INST after WR Rising Edge TOSC 10 ns TWHAX AD8±15 HOLD after WR Rising TOSC 30 ns TRHBX BHE, INST after RD Rising Edge TOSC 10 ns TRHAX AD8±15 HOLD after RD Rising TOSC 25 ns 20 110 ns 2 TOSC TOSC 10 ns TOSC 15 ns 5 15 ns 20 15 ns 4 TOSC ns TOSC 10 4 TOSC 30 TOSC TOSC 25 ns (Note 4) ns (Note 2) 5 ns 25 ns 15 ns 10 ns 0 TOSC ns ns 5 TOSC 23 (Note 4) 5 TOSC 15 ns NOTES: 1. Testing performed at 8 MHz. However, the device is static by design and will typically operate below 1 Hz. 2. Assuming back-to-back bus cycles. 3. 8-Bit bus only. 4. If wait states are used, add 2 TOSC N, where N number of wait states. 12 (Note 4) (Note 4) (Note 2) (Note 3) (Note 3) 8XC196KC/8XC196KC20 System Bus Timings 270942 ±18 13 8XC196KC/8XC196KC20 READY Timings (One Wait State) 270942 ±20 Buswidth Timings 270942 ±35 14 8XC196KC/8XC196KC20 HOLD/HLDA Timings Symbol Description Min Max Units THVCH HOLD Setup 55 TCLHAL CLKOUT Low to HLDA Low 15 15 ns ns TCLBRL CLKOUT Low to BREQ Low 15 15 ns THALAZ HLDA Low to Address Float 15 ns THALBZ HLDA Low to BHE, INST, RD, WR Weakly Driven 20 ns TCLHAH CLKOUT Low to HLDA High 15 15 ns TCLBRH CLKOUT Low to BREQ High 15 15 THAHAX HLDA High to Address No Longer Float 15 THAHBV HLDA High to BHE, INST, RD, WR Valid 10 15 ns TCLLH CLKOUT Low to ALE High 5 15 ns Notes (Note 1) ns ns NOTE: 1. To guarantee recognition at next clock. DC SPECIFICATIONS IN HOLD Description Min Max Units Weak Pullups on ADV, RD, WR, WRL, BHE 50K 250K VCC 5.5V, VIN 0.45V Weak Pulldowns on ALE, INST 10K 50K VCC 5.5V, VIN 2.4 15 8XC196KC/8XC196KC20 270942 ±36 Maximum Hold Latency Bus Cycle Type Internal Execution 1.5 States 16-Bit External Execution 2.5 States 8-Bit External Execution 4.5 States EXTERNAL CLOCK DRIVE (8XC196KC) 16 Symbol Parameter Min Max Units 1/T XLXL Oscillator Frequency TXLXL Oscillator Period TXHXX High Time 20 ns TXLXX Low Time 20 ns TXLXH Rise Time 10 ns TXHXL Fall Time 10 ns 8 16.0 MHz 62.5 125 ns 8XC196KC/8XC196KC20 EXTERNAL CLOCK DRIVE (8XC196KC20) Symbol Parameter Min Max Units 1/T XLXL Oscillator Frequency 8 20.0 MHz TXLXL Oscillator Period 50 125 ns TXHXX High Time 17 ns TXLXX Low Time 17 ns TXLXH Rise Time 8 ns TXHXL Fall Time 8 ns EXTERNAL CLOCK DRIVE WAVEFORMS 270942 ±21 EXTERNAL CRYSTAL CONNECTIONS EXTERNAL CLOCK CONNECTIONS 270942 ±41 NOTE: Keep oscillator components close to chip and use short, direct traces to XTAL1, XTAL2 and VSS. When using crystals, C1 C2 20 pF. When using ceramic resonators, consult manufacturer for recommended circuitry. AC TESTING INPUT, OUTPUT WAVEFORMS 270942 ±22 AC Testing inputs are driven at 2.4V for a Logic ``1'' and 0.45V for a Logic ``0'' Timing measurements are made at 2.0V for a Logic ``1'' and 0.8V for a Logic ``0''. 270942 ±42 NOTE: Required if TTL driver used. Not needed if CMOS driver is used. FLOAT WAVEFORMS 270942 ±23 For Timing Purposes a Port Pin is no Longer Floating when a 150 mV change from Load Voltage Occurs and Begins to Float when a 150 mV change from the Loaded VOH/V OL Level occurs; IOL/I OH 15 mA. 17 8XC196KC/8XC196KC20 EXPLANATION OF AC SYMBOLS Each symbol is two pairs of letters prefixed by ``T'' for time. The characters in a pair indicate a signal and its condition, respectively. Symbols represent the time between the two signal/condition points. Conditions: Signals: L- H- High A- Address BR- BREQ ALE/ADV L- Low B- BHE R- RD V- Valid C- CLKOUT W- WR/WRH /WRL X- No Longer Valid D- DATA X- XTAL1 Z- Floating G- Buswidth Y- READY H- HOLD Q- Data Out HA- HLDA AC CHARACTERISTICS-SERIAL PORT-SHIFT REGISTER MODE SERIAL PORT TIMING-SHIFT REGISTER MODE (MODE 0) Symbol Parameter Min TXLXL Serial Port Clock Period (BRR TXLXH Serial Port Clock Falling Edge to Rising Edge (BRR 8002H) TXLXL Serial Port Clock Period (BRR TXLXH Serial Port Clock Falling Edge to Rising Edge (BRR 8001H) 2 TOSC 50 TQVXH Output Data Setup to Clock Rising Edge 2 TOSC 50 ns TXHQX Output Data Hold after Clock Rising Edge 2 TOSC 50 ns TXHQV Next Output Data Valid after Clock Rising Edge TDVXH Input Data Setup to Clock Rising Edge TXHDX Input Data Hold after Clock Rising Edge TXHQZ Last Clock Rising to Output Float 8002H) Max Units 6 TOSC 4 TOSC 8001H) ns 50 4 TOSC 50 4 TOSC ns 2 TOSC 2 TOSC TOSC ns 50 50 50 ns ns ns 0 ns 1 TOSC ns WAVEFORM-SERIAL PORT-SHIFT REGISTER MODE SERIAL PORT WAVEFORM-SHIFT REGISTER MODE (MODE 0) 270942 ±24 18 8XC196KC/8XC196KC20 A to D CHARACTERISTICS The A/D converter is ratiometric, so absolute accuracy is dependent on the accuracy and stability of VREF. 10-BIT MODE A/D OPERATING CONDITIONS Symbol Description Min Max Units 0 70 C TA Ambient Temperature Commercial Temp. TA Ambient Temperature Extended Temp. 40 85 C VCC Digital Supply Voltage 4.50 5.50 V VREF Analog Supply Voltage 4.00 5.50 TSAM Sample Time TCONV Conversion Time 10 20 FOSC Oscillator Frequency (8XC196KC) 8.0 16.0 MHz FOSC Oscillator Frequency (8XC196KC20) 8.0 20.0 MHz V s(1) 1.0 s(1) NOTE: ANGND and VSS should nominally be at the same potential, 0.00V. 1. The value of AD_TIME is selected to meet these specifications. 10-BIT MODE A/D CHARACTERISTICS (Over Specified Operating Conditions) Parameter Typical (1) Resolution Minimum 1024 10 Absolute Error 0.25 Zero Offset Error 0.25 0.5 Non-Linearity 1.0 2.0 3 0.1 Repeatability 0.25 LSBs LSBs 0 3 0 LSBs 2 LSBs 1 LSBs LSBs 0.009 0.009 0.009 Off Isolation LSB/ C LSB/ C LSB/ C 60 Feedthrough 60 VCC Power Supply Rejection 60 Input Series Resistance ANGND DC Input Leakage 0 3 dB 1, 2 dB 1 dB 750 Voltage on Analog Input Pin *Notes LSBs 1 Channel-to-Channel Matching Units Levels Bits 0.5 Differential Non-Linearity Error Sampling Capacitor 1024 10 0 Full Scale Error Temperature Coefficients: Offset Full Scale Differential Non-Linearity Maximum 1.2K 0.5 VREF 0.5 3.0 1 4 V 5, 6 A pF NOTES: An ``LSB'' as used here has a value of approxiimately 5 mV. (See Embedded Microcontrollers and Processors Handbook for A/D glossary of terms). 1. These values are expected for most parts at 25 C but are not tested or guaranteed. 2. DC to 100 KHz. 3. Multiplexer Break-Before-Make is guaranteed. 4. Resistance from device pin, through internal MUX, to sample capacitor. 5. These values may be exceeded if the pin current is limited to 2 mA. 6. Applying voltages beyond these specifications will degrade the accuracy of all channels being converted. 7. All conversions performed with processor in IDLE mode. 19 8XC196KC/8XC196KC20 8-BIT MODE A/D OPERATING CONDITIONS Symbol Description Min 0 Max TA Ambient Temperature Commercial Temp. 70 TA Ambient Temperature Extended Temp. VCC Digital Supply Voltage 4.50 5.50 VREF Analog Supply Voltage 4.00 5.50 TSAM Sample Time TCONV Conversion Time FOSC FOSC 40 85 Units C C V V s(1) 1.0 7 20 s(1) Oscillator Frequency (8XC196KC) 8.0 16.0 MHz Oscillator Frequency (8XC196KC20) 8.0 20.0 MHz NOTE: ANGND and VSS should nominally be at the same potential, 0.00V. 1. The value of AD_TIME is selected to meet these specifications. 8-BIT MODE A/D CHARACTERISTICS Parameter Typical Resolution (Over Specified Operating Conditions) Minimum 256 8 Absolute Error Maximum Levels Bits 1 LSBs 0 Full Scale Error 0.5 Zero Offset Error 0.5 LSBs 0 Differential Non-Linearity Error 1 Channel-to-Channel Matching Temperature Coefficients: Offset Full Scale Differential Non-Linearity Notes LSBs Non-Linearity Repeatability Units 256 8 1 LSBs 1 LSBs 1 LSBs 0.25 LSBs 0.003 0.003 0.003 LSB/ C LSB/ C LSB/ C Off Isolation dB 2, 3 Feedthrough 60 60 dB 2 VCC Power Supply Rejection 60 dB 2 Input Series Resistance 750 Voltage on Analog Input Pin VSS DC Input Leakage Sampling Capacitor 0 3 1.2K 0.5 VREF s 0.5 3.0 V 4 5, 6 A pF NOTES: An ``LSB'' as used here has a value of approximately 20 mV. (See Embedded Microcontrollers and Processors Handbook for A/D glossary of terms). 1. These values are expected for most parts at 25 C but are not tested or guaranteed. 2. DC to 100 KHz. 3. Multiplexer Break-Before-Make is guaranteed. 4. Resistance from device pin, through internal MUX, to sample capacitor. 5. These values may be exceeded if pin current is limited to 2 mA. 6. Applying voltages beyond these specifications will degrade the accuracy of all channels being converted. 7. All conversions performed with processor in IDLE mode. 20 8XC196KC/8XC196KC20 EPROM SPECIFICATIONS OPERATING CONDITIONS DURING PROGRAMMING Symbol Description Min Max Units TA Ambient Temperature During Programming 20 30 C VCC Supply Voltage During Programming 4.5 5.5 V(1) VREF Reference Supply Voltage During Programming 4.5 5.5 V(1) VPP Programming Voltage 12.25 12.75 V(2) VEA EA Pin Voltage 12.25 12.75 V(2) FOSC Oscillator Frequency During Auto and Slave Mode Programming 6.0 8.0 MHz FOSC Oscillator Frequency During Run-Time Programming (8XC196KC) 6.0 16.0 MHz FOSC Oscillator Frequency During Run-Time Programming (8XC196KC20) 6.0 20.0 MHz NOTES: 1. VCC and VREF should nominally be at the same voltage during programming. 2. VPP and VEA must never exceed the maximum specification, or the device may be damaged. 3. VSS and ANGND should nominally be at the same potential (0V). 4. Load capacitance during Auto and Slave Mode programming 150 pF. AC EPROM PROGRAMMING CHARACTERISTICS Symbol Description Min Max 1100 Units TSHLL Reset High to First PALE Low TOSC TLLLH PALE Pulse Width 50 TOSC TAVLL Address Setup Time 0 TOSC TLLAX Address Hold Time 100 TPLDV PROG Low to Word Dump Valid TPHDX Word Dump Data Hold TDVPL Data Setup Time 0 TOSC TPLDX Data Hold Time 400 TOSC TPLPH(1) PROG Pulse Width 50 TOSC TPHLL PROG High to Next PALE Low 220 TOSC TLHPL PALE High to PROG Low 220 TOSC TPHPL PROG High to Next PROG Low 220 TOSC TPHIL PROG High to AINC Low TILIH AINC Pulse Width TILVH PVER Hold after AINC Low 50 TOSC TILPL AINC Low to PROG Low 170 TOSC TPHVL PROG High to PVER Valid TOSC 50 TOSC 50 TOSC 0 TOSC 240 TOSC 220 TOSC NOTE: 1. This specification is for the Word Dump Mode. For programming pulses, use the Modified Quick Pulse Algorithm. See user's manual for further information. 21 8XC196KC/8XC196KC20 DC EPROM PROGRAMMING CHARACTERISTICS Symbol IPP Description Min VPP Supply Current (When Programming) Max Units 100 mA NOTE: Do not apply VPP until VCC is stable and within specifications and the oscillator/clock has stabilized or the device may be damaged. EPROM PROGRAMMING WAVEFORMS SLAVE PROGRAMMING MODE DATA PROGRAM MODE WITH SINGLE PROGRAM PULSE 270942 ±27 NOTE: P3.0 must be high (``1'') SLAVE PROGRAMMING MODE IN WORD DUMP WITH AUTO INCREMENT 270942 ±28 NOTE: P3.0 must be low (``0'') 22 8XC196KC/8XC196KC20 SLAVE PROGRAMMING MODE TIMING IN DATA PROGRAM WITH REPEATED PROG PULSE AND AUTO INCREMENT 270942 ±29 8XC196KB TO 8XC196KC DESIGN CONSIDERATIONS 1. Memory Map. The 8XC196KC has 512 bytes of RAM/SFRs and an optional 16K of ROM/OTPR OM. The extra 256 bytes of RAM will reside in locations 100H ±1FFH and the extra 8K of ROM/OTPR OM will reside in locations 4000H ±5FFFH. These locations are external memory on the 8XC196KB. 2. The CDE pin on the KB has become a VSS pin on the KC to support 16/20 MHz operation. 3. EPROM programming. The 8XC196KC has a different programming algorithm to support 16K of on-board memory. When performing Run-Time Programming, use the section of code in the 8XC196KC User's Guide. 4. ONCE Mode Entry. The ONCE mode is entered on the 8XC196KC by driving the TXD pin low on the rising edge of RESET. The TXD pin is held high by a pullup that is specified by IOH1. This Pullup must not be overridden or the 8XC196KC will enter the ONCE mode. 5. During the bus HOLD state, the 8XC196KC weakly holds RD, WR, ALE, BHE and INST in their inactive states. The 8XC196KB only holds ALE in its inactive state. 6. A RESET pulse from the 8XC196KC is 16 states rather than 4 states as on the 8XC196KB (i.e., a watchdog timer overflow). This provides a longer RESET pulse for other devices in the system. 8XC196KC ERRATA 1. Missed EXTINT on P0.7. The 80C196KC20 could possibly miss EXTINT on P0.7. See techbit MC0893. an 2. HSI_MODEdivide-by-eight. See Faxback 2192. 3. IPD hump. See Faxback 2311. 23 8XC196KC/8XC196KC20 DATA SHEET REVISION HISTORY This data sheet is valid for devices with a ``H'', ``L'' or ``M'' at the end of the topside tracking number. The topside tracking number consists of nine characters and is the second line on the top side of the device. Data sheets are changed as new device information becomes available. Verify with your local Intel sales office that you have the latest version before finalizing a design or ordering devices. The following are differences between the 270942-006 datasheet and the 270942-005 datasheet: 1. Package prefix variables have changed. Variables are now indicated by an "x" The following are differences between the 270942-004 and 270942-005 datasheets: 1. Removed ``Word Addressable Only'' from Port 3 and 4 in Table 2. 2. Renamed PVAL to CPVER. 3. Removed TLLYV and TLLGV from the waveform diagrams. 4. Added HSI_MODE divide-by-eight and IPD hump to 8XC196KC errata. The following are important differences between the 270942-002 and 270942-004 data sheets: 1. NMI during PTS, QBD port glitch and Divide HOLD/READY erratas were fixed and have been removed from the data sheet. The HSI errata is also removed as this is now considered normal operation. 2. Combined 16 and 20 MHz data sheets. Data sheet 270924-001 (20 MHz) is now obsolete. 3. Added 80-lead SQFP package pinout. 4. Added documentation for CLKOUT disable bit. 5. JA for QFP package was changed to 55 C/W from 42 C/W. 6. JC for QFP package was changed to 16 C/W from TBD C/W. 7. TSAM (MIN) in 10-bit mode was changed to 1.0 s from 3.0 s. 8. TSAM (MIN) in 8-bit mode was changed to 1.0 s from 2.0 s. 9. IIL1 specification for port 2.0 was renamed IIL2. 10. IIL2 (MAX) is changed to TBD from 11. IIH1 (MAX) is changed to 6 mA. 200 A from 12. IIH1 test condition changes to VIN 100 A. 2.4V from VIN 5.5V. 13. VHYS is changed to 300 mV from 150 mV. 14. ICC (TYP) at 16 MHz is changed to 65 mA from 50 mA. 15. ICC (MAX) at 16 MHz is changed to 75 mA from 70 mA. 16. ICC (TYP) at 20 MHz is changed to 80 mA from 60 mA. 17. ICC (MAX) at 20 MHz is changed to 92 mA from 86 mA. 18. IIDLE (TYP) at 16 MHz is changed to 17 mA from 15 mA. 19. IIDLE (MAX) at 16 MHz is changed to 25 mA from 30 mA. 20. IIDLE (TYP) at 20 MHz is changed to 21 mA from 15 mA. 21. IIDLE (MAX) at 20 MHz is changed to 30 mA from 35 mA. 22. IPD (TYP) at 16 MHz is changed to 8 A from 15 A. 23. IPD (MAX) at 16 MHz is changed to 15 A from TBD. 24. IPD (TYP) at 20 MHz is changed to 8 A from 18 A. 25. IPD (MAX) at 20 MHz is changed to 15 A from TBD. 26. TCLDV (MAX) is changed to TOSC 27. TLLAX (MIN) is changed to TOSC 28. TCHWH (MIN) is changed to 45 ns from TOSC 35 ns from TOSC 5 ns from 29. TRHAX (MIN) is changed to TOSC 50 ns. 40 ns. 10 ns. 25 ns from TOSC 30. THALAZ (MAX) is changed to 15 ns from 10 ns. 31. THALBZ (MAX) is changed to 20 ns from 15 ns. 30 ns. 8XC196KC/8XC196KC20 32. THAHBV (MAX) is now specified at 15 ns, was formerly unspecified. 33. The TLLYV and TLLGV specifications were removed. These specifications are not required in high-speed systems designs. 34. Added EXTINT, P0.7 errata to Errata section. The following are the important differences between the -001 and -002 versions of data sheet 270942. 1. Express and Commercial devices are combined into one data sheet. The Express only data sheet 270794-001 is obsolete. 2. Removed KB/KC feature set differences, pin definition table, and SFR locations and bitmaps. 3. Added programming pin function to package drawings and pin descriptions. 4. Changed absolute maximum temperature under bias from 0 C to 70 C to 55 C to 125 C. 5. Replaced VOH2 specification with IOH1 and IIL1 specifications. 6. Added IIH1 specification for NMI pulldown resistors. 7. Added maximum hold latency table. 8. Added external oscillator and external clock circuit drawings. 9. Changed Clock Drive TXHXX and TXLXX Min spec to 20 ns. 10. Fixed Serial Port TXLXH specification. 11. Added 8- and 10-bit mode A/D operating conditions tables. 12. Specified operating range for sample and convert times. 13. Added specification for voltage on analog input pin. 14. Put operating conditions for EPROM programming into tabular format. 25