IBM MiEM78P468L 3 IOC60/P6CR Port 6 I/O Control Register, 6 IOC90/RAMADDR 128 Bytes RAM Address

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EM78P468N/EM78P468L

8-Bit Microcontroller

6.2.3IOC60/P6CR (Port 6 I/O Control Register)

(Address: 06h, Bit 0 of R5 = “0”)

Bit 7

 

Bit 6

 

Bit 5

 

Bit 4

 

Bit 3

 

Bit 2

 

Bit 1

 

Bit 0

IOC67

 

IOC66

 

IOC65

 

IOC64

 

IOC63

 

IOC62

 

IOC61

 

IOC60

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Bit 7 (IOC67) ~ Bit 0(IOC60): Port 6 I/O direction control register

IOC6x =”0”: set the relative Port 6.x I/O pins as output

IOC6x =”1”: set the relative Port 6.x I/O pin into high impedance (input pin)

6.2.4IOC70/P7CR (Port 7 I/O Control Register)

(Address: 07h, Bit 0 of R5 = “0”)

Bit 7

Bit 6

Bit 5

Bit 4

Bit 3

Bit 2

Bit 1

Bit 0

 

 

 

 

 

 

 

 

IOC77

IOC76

IOC75

IOC74

IOC73

IOC72

IOC71

IOC70

 

 

 

 

 

 

 

 

Bit 7 (IOC77) ~ Bit 0 (IOC70): Port 7 I/O direction control register

IOC7x = “0”: set the relative Port 7.x I/O pins as output

IOC7x = “1”: set the relative Port 7.x I/O pin into high impedance (input pin)

6.2.5IOC80/P8CR (Port 8 I/O Control Register)

(Address: 08h, Bit 0 of R5 = “0”)

Bit 7

 

Bit 6

 

Bit 5

 

Bit 4

 

Bit 3

 

Bit 2

 

Bit 1

 

Bit 0

IOC87

 

IOC86

 

IOC85

 

IOC84

 

IOC83

 

IOC82

 

IOC81

 

IOC80

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Bit 7 (IOC 87) ~ Bit 0 (IOC 80): Port 8 I/O direction control register

IOC8x = “0”: set the relative Port 8.x I/O pins as output

IOC8x = “1”: set the relative Port 8.x I/O pin into high impedance (input pin)

6.2.6IOC90/RAM_ADDR (128 Bytes RAM Address)

(Address: 09h, Bit 0 of R5 = “0”)

Bit

7

Bit 6

 

Bit 5

Bit 4

Bit 3

Bit 2

 

Bit 1

Bit 0

 

 

 

 

 

 

 

 

 

 

 

 

 

0

 

RAM_A6

RAM_A5

RAM_A4

RAM_A3

RAM_A2

RAM_A1

RAM_A0

 

 

 

 

 

 

 

 

 

 

 

Bit 7: Not used, fixed at “0”

Bits 6~0: 128 bytes RAM address

6.2.7IOCA0/RAM_DB (128 Bytes RAM Data Buffer)

(Address: 0Ah, Bit 0 of R5 = “0”)

 

Bit 7

 

Bit 6

 

Bit 5

 

Bit 4

 

Bit 3

 

Bit 2

 

Bit 1

 

Bit 0

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

RAM_D7

 

RAM_D6

 

RAM_D5

 

RAM_D4

 

RAM_D3

 

RAM_D2

 

RAM_D1

 

RAM_D0

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Bits 7~0: 128 bytes RAM data transfer register

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

16

 

 

 

 

 

 

Product Specification (V1.5) 02.15.2007

(This specification is subject to change without further notice)

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Contents EM78P468N/L Elan Microelectronics Corporation Contents Infrared Remote Control Application/PWM Waveform Generate Appendix Doc. Version Revision Description DateContents Product Specification V1.5 General Description FeaturesBit Microcontroller Pin Assignment Pin QFP Pin LqfpBlock Diagram System Block DiagramPin Description Symbol Pin No Type FunctionPin Description for Package of QFP64 and LQFP64 Pin Description for Package of QFP44 and LQFP44 SEG11~SEG14Operational Registers 2 R1/TCC Timer Clock CounterFunction Description 1 R0/IAR Indirect Addressing RegisterOn-ChipProgrammemory Bit 2 Z Zero flag 4 R3/SR Status RegisterBits 6 ~ 5 PS1 ~ 0 Page select bits Bit 0 C Carry flag7 R6/Port 6 Port 6 I/O Data Register 5 R4/RSR RAM Select Register6 R5/Port 5 Port 5 I/O Data and Page of Register Select 8 R7/Port 7 Port 7 I/O Data Register10 R9/LCDCR LCD Control Register Bit 4 Lcden LCD enable bit9 R8/Port 8 Port 8 I/O Data Register Lcdtype = 0 a type waveform Lcdtype = 1 B type waveform11 RA/LCDADDR LCD Address RC/CNTER Counter Enable RegisterRB/LCDDB LCD Data Buffer Main clock 14 RD/SBPCR System, Booster and PLL Control RegisterAddress 0Dh Example Fs=32.768KBit Microcontroller CPU Operation Mode 15 RE/IRCR IR and Port 5 Setting Control RegisterAddress 0Eh Address 10h~3Fh R10~R3F General Purpose Register 16 RF/ISR Interrupt Status RegisterAddress 0Fh Accumulator Special Purpose RegistersAddress 05h, Bit 0 of R5 = 5 IOC80/P8CR Port 8 I/O Control Register 3 IOC60/P6CR Port 6 I/O Control Register4 IOC70/P7CR Port 7 I/O Control Register 6 IOC90/RAMADDR 128 Bytes RAM AddressIOCC0/CNT2PR Counter 2 Preset Register IOCB0/CNT1PR Counter 1 Preset RegisterIOCD0/HPWTPR High-Pulse Width Timer Preset Register IOCF0/IMR Interrupt Mask Register IOCE0/LPWTPR Low-Pulse Width Timer Preset RegisterBits 6, 5, 4 Not used Bits 3~0 PSRE, TCCP2 ~ TCCP0 TCC prescaler bits 14 IOC71/TCCCR TCC Control RegisterBit 7 Intedge TCC RateBits 7 ~ 4 Not used 15 IOC81/WDTCR WDT Control Register16 IOC91/CNT12CR Counters 1, 2 Control Register WDT RateHigh-pulse Width Timer Scale IOCA1/HLPWTCR High/Low Pulse Width Timer Control RegisterLow-pulse Width Timer Scale Counter 1 ScaleIOCD1/P8PH Port 8 Pull High Control Register IOCB1/P6PH Port 6 Pull-high Control RegisterIOCC1/P6OD Port 6 Open Drain Control Register IOCE1/P6PL Port 6 Pull Low Control RegisterTCC and WDT Prescaler MUXBit Microcontroller WDT Setting Flowchart TCC Setting FlowchartReset and Wake-up I/O PortsAddress Name Reset Type Bit Bit Microcontroller Summary of Registers Initialized ValuesINT Psre TCCP2 TCCP1 TCCP0 Name Reset Type Bit Wake-up Signal Sleep Mode Idle Mode Green Mode Normal Mode Oscillator Phase Lock Loop PLL ModeOscillator Modes Main clock Example Fs=32.768KHz Crystal Oscillator/Ceramic Resonators CrystalOscillator Source Oscillator Type Frequency C1 pF C2 pF RC Oscillator Frequencies Power-on ConsiderationsRC Oscillator Mode with Internal Capacitor Pin Rext Average Fosc 5V, 25 C Average Fosc 3V, 25 CExternal Power-on Reset Circuit Residue-Voltage ProtectionInterrupt 13 Interrupt Back-up1 R9/LCDCR LCD Control Register LCD DriverBits 6 ~ 5 DS1 ~ DS0 LCD duty select Bits 7 ~ 5 Not used, fixed to 2 RA/LCDADDR LCD Address3 RB/LCDDB LCD Data Buffer Bits 4 ~ 0 LCDA4 ~ LCDA0 LCD RAM address4 RD/SBPCR System, Booster and PLL Control Registers Bit 2 ~ 1 BF1 ~ 0 LCD booster frequency select bitsExternal circuit for 1/3 Bias Boosting circuits connection for LCD voltageExternal circuit for 1/2 Bias 16 LCD Waveform for 1/2 Bias, 1/2 Duty 18 LCD Waveform for 1/3 Bias, 1/3 Duty Infrared Remote Control Application/PWM Waveform Generate ⋅ 1 + decimal C ounter Preset Value Iocc 0 ⋅ prescaler21 LGP=0, Irout Pin Output Waveform 23 LGP=0, Irout Pin Output Waveform Bit Microcontroller IR/PWM Function Enable Flowchart IR applicationWord Code OptionsBits 12 ~ 10 Not used Bits12~10 WordBits 2~0 PR2~PR0 Protect Bit Instruction SetPR1PR0Protect Binary Instruction Hex Mnemonic Operation Status ConventionBinary Instruction Hex Mnemonic Operation Status Affected JZATiming Diagram AC Test Input/Output WaveformItems Symbol Condition Rating Min Max Unit Absolute Maximum RatingsSymbol Parameter Condition Min Typ Max Unit Electrical CharacteristicDC Electrical Characteristics Ta= -40 C ~85 C, VDD= 5.0V, GND=Ta= -40C ~85 C, VDD= 3.0V, GND= Symbol Parameter Conditions Min Typ Max Unit AC Electrical CharacteristicsTa=- 40C ~ 85 C, VDD=5V±5%, GND=0V Device Characteristic Vih/Vil /RESET pins with schmitt inverterVih/Vil Port 7, Port 8 All Input pins with schmitt inverter P5.7 Voh/Ioh VDD=5V, IROCS=1 P5.7 Voh/Ioh VDD=3V, IROCS=1 80 P5.7 Voh/Ioh VDD=5V, IROCS=0 Max Typ +25 Setup time from Power on Reset = 51 K 13 Typical Eric OSC Frequency vs. Temperature Xin Pin VDD=5V Typical ICC2 vs. Temerature Typical ICC1 vs. Temerature Typical ISB vs. Temerature 22 Operating Voltage under Temperature Range of 0C to 70C Application Circuit Name Package Type Pin Count Package Size Package TypeEM78P468NxS/xJ Package Information QFPLqfp 900 100 BSC 00 REFMin Normal Max 30TYP 15TYP EM78P468N/L Program Pin List Wiring diagram is for Elan DwtrProgram Pin Name IC Pin Name QFP-64 QFP-44 ICE 468XA Oscillator Circuit JP Main oscillator Crystal mode, Sub oscillator Crystal modeMain oscillator PLL mode, Sub oscillator Crystal mode Main oscillator RC mode, Sub oscillator CrystalBit Microcontroller ICE 468XA Output Pin Assignment JP VLCD3 GND OscoAddress Trap Detect Quality Assurance and ReliabilityTest Category Test Conditions Contents III

MiEM78P468L, MiEM78P468N specifications

The IBM MiEM78P468N and MiEM78P468L are advanced integrated circuit solutions that cater primarily to the needs of enterprise-level computing systems. These microprocessors are integral in handling a variety of complex tasks, thereby empowering businesses with the efficiency and speed required in today's fast-paced digital environment.

Both models utilize the cutting-edge 78P architecture, which provides impressive performance capabilities. The MiEM78P468N operates at a clock speed of up to 2.2 GHz, while the MiEM78P468L offers a lower clock speed optimized for energy efficiency. This distinction makes the N version ideal for high-performance applications, whereas the L version appeals to scenarios where power consumption is a critical consideration.

A key characteristic of both models is their multi-core architecture, supporting up to four cores. This feature allows for enhanced parallel processing, enabling the handling of multiple tasks simultaneously—a vital requirement for data-intensive applications. Moreover, the inclusion of advanced cache memory arrangements enhances data retrieval speeds significantly, ensuring that applications run smoothly without performance bottlenecks.

These processors also employ cutting-edge thermal management technologies. The dynamic voltage and frequency scaling (DVFS) capabilities ensure that performance can be adjusted in real-time based on workload requirements, helping to minimize energy consumption. This is particularly beneficial in maintaining optimal operating temperatures and prolonging the lifespan of the hardware.

Another notable feature is support for advanced security protocols. Both models incorporate hardware-based security technologies that safeguard data integrity and protect against unauthorized access. This is becoming increasingly important in today's cybersecurity landscape where businesses must prioritize protecting sensitive information.

Additionally, the IBM MiEM78P468N and MiEM78P468L processors are compatible with a wide range of operating systems, facilitating seamless integration into various IT environments. Their robust architecture supports extensive peripheral interconnect protocols, enhancing expandability and connectivity options.

In summary, the IBM MiEM78P468N and MiEM78P468L processors stand out for their performance capabilities, energy efficiency, advanced security features, and versatility. They are well-suited for organizations looking to enhance their computing power while maintaining a balance between performance and power consumption. These microprocessors are instrumental in driving innovation and efficiency in enterprise computing.
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