SPC5567MVZ132

Document Number: MPC5567 Rev. 2, December 2012 Freescale Data Sheet: Technical Data MPC5567 Microcontroller Data Sheet This document provides electrical specifications, pin assignments, and package diagrams for the MPC5567 microcontroller device. For functional characteristics, refer to the MPC5567 Microcontroller Reference Manual. 1 Contents 1 Overview . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 1 2 Ordering Information . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3 Electrical Characteristics . . . . . . . . . . . . . . . . . . . . . . . . . 3 3.1 Maximum Ratings . . . . . . . . . . . . . . . . . . . . . . . . . . 3 3.2 Thermal Characteristics. . . . . . . . . . . . . . . . . . . . . . 5 3.3 Package . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 8 3.4 EMI (Electromagnetic Interference) Characteristics 8 3.5 ESD (Electromagnetic Static Discharge) Characteristics9 3.6 Voltage Regulator Controller (VRC) and Power-On Reset (POR) Electrical Specifications9 3.7 Power-Up/Down Sequencing . . . . . . . . . . . . . . . . 10 3.8 DC Electrical Specifications. . . . . . . . . . . . . . . . . . 14 3.9 Oscillator and FMPLL Electrical Characteristics . . 20 3.10 eQADC Electrical Characteristics . . . . . . . . . . . . . 22 3.11 H7Fa Flash Memory Electrical Characteristics . . . 23 3.12 AC Specifications . . . . . . . . . . . . . . . . . . . . . . . . . 24 3.13 AC Timing . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 26 3.14 Fast Ethernet AC Timing Specifications . . . . . . . . 46 4 Mechanicals. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4.1 MPC5567 324 PBGA Pinouts . . . . . . . . . . . . . . . . 4.2 MPC5567 416 PBGA Pinout . . . . . . . . . . . . . . . . . 4.3 MPC5567 324-Pin Package Dimensions . . . . . . . 4.4 MPC5567 416-Pin Package Dimensions . . . . . . . 5 Revision History for the MPC5567 Data Sheet . . . . . . . 58 5.1 Information Changed Between Revisions 1.0 and 2.0 58 5.2 Information Changed Between Rev. 0.0 and 1.0. . 58 Overview The MPC5567 microcontroller (MCU) is a member of the MPC5500 family of microcontrollers built on the Power Architectureembedded technology. This family of parts has many new features coupled with high performance CMOS technology to provide substantial reduction of cost per feature and significant performance improvement over the MPC500 family. The host processor core of this device complies with the Power Architecture embedded category that is 100% user-mode compatible (including floating point library) with the original PowerPC instruction set.The embedded architecture enhancements improve the performance in embedded applications. The core also has additional instructions, including digital signal processing (DSP) instructions, beyond the original PowerPC instruction set. © Freescale Inc., 2007,2012. All rights reserved. 50 50 50 54 56 Overview The MPC5500 family of parts contains many new features coupled with high performance CMOS technology to provide significant performance improvement over the MPC565x. The host processor core of the MPC5567 also includes an instruction set enhancement allowing variable length encoding (VLE). This allows optional encoding of mixed 16- and 32-bit instructions. With this enhancement, it is possible to significantly reduce the code size footprint. The MPC5567 has two levels of memory hierarchy. The fastest accesses are to the 8-kilobytes (KB) unified cache. The next level in the hierarchy contains the 80-KB on-chip internal SRAM and twomegabytes (MB) internal flash memory. The internal SRAM and flash memory hold instructions and data. The external bus interface is designed to support most of the standard memories used with the MPC5xx family. The complex input/output timer functions of the MPC5567 are performed by an enhanced time processor unit (eTPU) engine. The eTPU engine controls 32 hardware channels. The eTPU has been enhanced over the TPU by providing: 24-bit timers, double-action hardware channels, variable number of parameters per channel, angle clock hardware, and additional control and arithmetic instructions. The eTPU is programmed using a high-level programming language. The less complex timer functions of the MPC5567 are performed by the enhanced modular input/output system (eMIOS). The eMIOS’ 24 hardware channels are capable of single-action, double-action, pulse-width modulation (PWM), and modulus-counter operations. Motor control capabilities include edge-aligned and center-aligned PWM. Off-chip communication is performed by a suite of serial protocols including controller area networks (FlexCANs), enhanced deserial/serial peripheral interfaces (DSPIs), and enhanced serial communications interfaces (eSCIs). The DSPIs support pin reduction through hardware serialization and deserialization of timer channels and general-purpose input/output (GPIOs) signals. The MCU has an on-chip enhanced queued dual analog-to-digital converter (eQADC).and package sve40-channels. The system integration unit (SIU) performs several chip-wide configuration functions. Pad configuration and general-purpose input and output (GPIO) are controlled from the SIU. External interrupts and reset control are also determined by the SIU. The internal multiplexer submodule provides multiplexing of eQADC trigger sources, daisy chaining the DSPIs, and external interrupt signal multiplexing. The Fast Ethernet (FEC) module is a RISC-based controller that supports both 10 and 100 Mbps Ethernet/IEEE® 802.3 networks and is compatible with three different standard MAC (media access controller) PHY (physical) interfaces to connect to an external Ethernet bus. The FEC supports the 10 or 100 Mbps MII (media independent interface), and the 10 Mbps-only with a seven-wire interface, which uses a subset of the MII signals. The upper 16-bits of the 32-bit external bus interface (EBI) are used to connect to an external Ethernet device. The FEC contains built-in transmit and receive message FIFOs and DMA support. The FlexRay controller provides functional node networking, with static and dynamic host access, to develop highly dependable automotive control systems that require the full implementation of the FlexRay protocol, as published in FlexRay Protocol Specification 2.0. The FlexRay module uses fault-tolerant, time-triggered events and clock synchronization mechanisms to maintain the global time of the functional MPC5567 Microcontroller Data Sheet, Rev. 2 2 Freescale Semiconductor Ordering Information nodes. Bus guardian operations are available for each channel in a multi- or redundant-channel configuration. 2 Ordering Information M PC 5567 M ZP 80 R Qualification status Core code Device number Temperature range Package identifier Operating frequency (MHz) Tape and reel status Temperature Range M = –40° C to 125° C Package Identifier ZP = 416PBGA SnPb VR = 416PBGA Pb-free ZQ = 324PBGA SnPb VZ = 324PBGA Pb-free Operating Frequency 80 = 80 MHz 112 = 112 MHz 132 = 132 MHz Note: Not all options are available on all devices. Refer to Table 1. Tape and Reel Status R = Tape and reel (blank) = Trays Qualification Status P = Pre qualification M = Fully spec. qualified, general market flow S = Fully spec. qualified, automotive flow Figure 1. MPC5500 Family Part Number Example Unless noted in this data sheet, all specifications apply from TL to TH. Table 1. Orderable Part Numbers Freescale Part Number1 MPC5567MVR132 MPC5567MVR112 MPC5567 416 package Lead-free (PbFree) MPC5567MVR80 MPC5567MVZ132 MPC5567MVZ80 MPC5567 324 package Lead-free (PbFree) MPC5567MVZ112 MPC5567MZP132 MPC5567MZP112 MPC5567 416 package Leaded (SnPb) MPC5567MZP80 MPC5567MZQ132 MPC5567MZQ112 MPC5567MZQ80 1 Speed (MHz) Package Description MPC5567 324 package Leaded (SnPb) Nominal Max. 3 (fMAX) 132 135 112 114 80 82 132 135 80 82 112 114 132 135 112 114 80 82 132 135 112 114 80 82 Operating Temperature 2 Min. (TL) Max. (TH) –40° C 125° C –40° C 125° C –40° C 125° C –40° C 125° C All devices are PPC5567, rather than MPC5567 or SPC5567, until product qualifications are complete. Not all configurations are available in the PPC parts. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 3 Electrical Characteristics 2 3 The lowest ambient operating temperature is referenced by TL; the highest ambient operating temperature is referenced by TH. Speed is the nominal maximum frequency. Max. speed is the maximum speed allowed including frequency modulation (FM). 82 MHz parts allow for 80 MHz system clock + 2% FM; 114 MHz parts allow for 112 MHz system clock + 2% FM; and 135 MHz parts allow for 132 MHz system clock + 2% FM. 3 Electrical Characteristics This section contains detailed information on power considerations, DC/AC electrical characteristics, and AC timing specifications for the MCU. 3.1 Maximum Ratings Table 2. Absolute Maximum Ratings 1 Spec Characteristic Symbol Min. Max. Unit 1 1.5 V core supply voltage 2 VDD –0.3 1.7 V 2 Flash program/erase voltage VPP –0.3 6.5 V 4 Flash read voltage VFLASH –0.3 4.6 V 5 SRAM standby voltage VSTBY –0.3 1.7 V 6 Clock synthesizer voltage VDDSYN –0.3 4.6 V 7 3.3 V I/O buffer voltage VDD33 –0.3 4.6 V 8 Voltage regulator control input voltage VRC33 –0.3 4.6 V 9 Analog supply voltage (reference to VSSA) VDDA –0.3 5.5 V VDDE –0.3 4.6 V VDDEH –0.3 6.5 V –1.0 5 –1.0 5 6.5 6 4.6 7 V 10 11 I/O supply voltage (fast I/O pads) 3 I/O supply voltage (slow and medium I/O pads) 3 4 DC input voltage VDDEH powered I/O pads VDDE powered I/O pads VIN 13 Analog reference high voltage (reference to VRL) VRH –0.3 5.5 V 14 VSS to VSSA differential voltage VSS – VSSA –0.1 0.1 V 15 VDD to VDDA differential voltage VDD – VDDA –VDDA VDD V 16 VREF differential voltage VRH – VRL –0.3 5.5 V 17 VRH to VDDA differential voltage VRH – VDDA –5.5 5.5 V 18 VRL to VSSA differential voltage VRL – VSSA –0.3 0.3 V 19 VDDEH to VDDA differential voltage VDDEH – VDDA –VDDA VDDEH V 20 VDDF to VDD differential voltage VDDF – VDD –0.3 0.3 V 21 VRC33 to VDDSYN differential voltage spec has been moved to Table 9 DC Electrical Specifications, Spec 43a. 22 VSSSYN to VSS differential voltage VSSSYN – VSS –0.1 0.1 V 23 VRCVSS to VSS differential voltage VRCVSS – VSS –0.1 0.1 V 24 Maximum DC digital input current 8 (per pin, applies to all digital pins) 4 IMAXD –2 2 mA 25 Maximum DC analog input current 9 (per pin, applies to all analog pins) IMAXA –3 3 mA 12 MPC5567 Microcontroller Data Sheet, Rev. 2 4 Freescale Semiconductor Electrical Characteristics Table 2. Absolute Maximum Ratings 1 (continued) Spec Characteristic Symbol Min. Max. Unit TJ TL 150.0 o 26 Maximum operating temperature range 10 Die junction temperature 27 Storage temperature range TSTG –55.0 150.0 oC 28 Maximum solder temperature 11 Lead free (Pb-free) Leaded (SnPb) TSDR — — 260.0 245.0 o Moisture sensitivity level 12 MSL — 3 29 C C 1 Functional operating conditions are given in the DC electrical specifications. Absolute maximum ratings are stress ratings only, and functional operation at the maxima is not guaranteed. Stress beyond any of the listed maxima can affect device reliability or cause permanent damage to the device. 2 1.5 V ± 10% for proper operation. This parameter is specified at a maximum junction temperature of 150 oC. 3 All functional non-supply I/O pins are clamped to V SS and VDDE, or VDDEH. 4 AC signal overshoot and undershoot of up to ± 2.0 V of the input voltages is permitted for an accumulative duration of 60 hours over the complete lifetime of the device (injection current not limited for this duration). 5 Internal structures hold the voltage greater than –1.0 V if the injection current limit of 2 mA is met. Keep the negative DC voltage greater than –0.6 V on SINB during the internal power-on reset (POR) state. 6 Internal structures hold the input voltage less than the maximum voltage on all pads powered by V DDEH supplies, if the maximum injection current specification is met (2 mA for all pins) and VDDEH is within the operating voltage specifications. 7 Internal structures hold the input voltage less than the maximum voltage on all pads powered by V DDE supplies, if the maximum injection current specification is met (2 mA for all pins) and VDDE is within the operating voltage specifications. 8 Total injection current for all pins (including both digital and analog) must not exceed 25 mA. 9 Total injection current for all analog input pins must not exceed 15 mA. 10 Lifetime operation at these specification limits is not guaranteed. 11 Moisture sensitivity profile per IPC/JEDEC J-STD-020D. 12 Moisture sensitivity per JEDEC test method A112. 3.2 Thermal Characteristics The shaded rows in the following table indicate information specific to a four-layer board. Table 3. MPC5567 Thermal Characteristics Spec 1 MPC5567 Thermal Characteristic Junction to ambient 1, 2, natural convection (one-layer board) 1, 3, Packages 324 PBGA 416 PBGA Unit RJA 29 25 °C/W RJA 19 17 °C/W 2 Junction to ambient 3 Junction to ambient (@200 ft./min., one-layer board) RJMA 23 19 °C/W 4 Junction to ambient (@200 ft./min., four-layer board 2s2p) RJMA 16 14 °C/W RJB 10 9 °C/W RJC 7 7 °C/W JT 2 2 °C/W 5 6 7 Junction to board Junction to case 4 natural convection (four-layer board 2s2p) Symbol (four-layer board 2s2p) 5 6 Junction to package top , natural convection 1 Junction temperature is a function of on-chip power dissipation, package thermal resistance, mounting site (board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board thermal resistance. 2 Per SEMI G38-87 and JEDEC JESD51-2 with the single-layer board horizontal. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 5 Electrical Characteristics 3 Per JEDEC JESD51-6 with the board horizontal. Thermal resistance between the die and the printed circuit board per JEDEC JESD51-8. Board temperature is measured on the top surface of the board near the package. 5 Indicates the average thermal resistance between the die and the case top surface as measured by the cold plate method (MIL SPEC-883 Method 1012.1) with the cold plate temperature used for the case temperature. 6 Thermal characterization parameter indicating the temperature difference between package top and the junction temperature per JEDEC JESD51-2. 4 3.2.1 General Notes for Specifications at Maximum Junction Temperature An estimation of the device junction temperature, TJ, can be obtained from the equation: TJ = TA + (RJA  PD) where: TA = ambient temperature for the package (oC) RJA = junction to ambient thermal resistance (oC/W) PD = power dissipation in the package (W) The thermal resistance values used are based on the JEDEC JESD51 series of standards to provide consistent values for estimations and comparisons. The difference between the values determined for the single-layer (1s) board compared to a four-layer board that has two signal layers, a power and a ground plane (2s2p), demonstrate that the effective thermal resistance is not a constant. The thermal resistance depends on the: • Construction of the application board (number of planes) • Effective size of the board which cools the component • Quality of the thermal and electrical connections to the planes • Power dissipated by adjacent components Connect all the ground and power balls to the respective planes with one via per ball. Using fewer vias to connect the package to the planes reduces the thermal performance. Thinner planes also reduce the thermal performance. When the clearance between the vias leave the planes virtually disconnected, the thermal performance is also greatly reduced. As a general rule, the value obtained on a single-layer board is within the normal range for the tightly packed printed circuit board. The value obtained on a board with the internal planes is usually within the normal range if the application board has: • One oz. (35 micron nominal thickness) internal planes • Components are well separated • Overall power dissipation on the board is less than 0.02 W/cm2 The thermal performance of any component depends on the power dissipation of the surrounding components. In addition, the ambient temperature varies widely within the application. For many natural convection and especially closed box applications, the board temperature at the perimeter (edge) of the package is approximately the same as the local air temperature near the device. Specifying the local ambient conditions explicitly as the board temperature provides a more precise description of the local ambient conditions that determine the temperature of the device. MPC5567 Microcontroller Data Sheet, Rev. 2 6 Freescale Semiconductor Electrical Characteristics At a known board temperature, the junction temperature is estimated using the following equation: TJ = TB + (RJB  PD) where: TJ = junction temperature (oC) TB = board temperature at the package perimeter (oC/W) RJB = junction-to-board thermal resistance (oC/W) per JESD51-8 PD = power dissipation in the package (W) When the heat loss from the package case to the air does not factor into the calculation, an acceptable value for the junction temperature is predictable. Ensure the application board is similar to the thermal test condition, with the component soldered to a board with internal planes. The thermal resistance is expressed as the sum of a junction-to-case thermal resistance plus a case-to-ambient thermal resistance: RJA = RJC + RCA where: RJA = junction-to-ambient thermal resistance (oC/W) RJC = junction-to-case thermal resistance (oC/W) RCA = case-to-ambient thermal resistance (oC/W) RJC is device related and is not affected by other factors. The thermal environment can be controlled to change the case-to-ambient thermal resistance, RCA. For example, change the air flow around the device, add a heat sink, change the mounting arrangement on the printed circuit board, or change the thermal dissipation on the printed circuit board surrounding the device. This description is most useful for packages with heat sinks where 90% of the heat flow is through the case to heat sink to ambient. For most packages, a better model is required. A more accurate two-resistor thermal model can be constructed from the junction-to-board thermal resistance and the junction-to-case thermal resistance. The junction-to-case thermal resistance describes when using a heat sink or where a substantial amount of heat is dissipated from the top of the package. The junction-to-board thermal resistance describes the thermal performance when most of the heat is conducted to the printed circuit board. This model can be used to generate simple estimations and for computational fluid dynamics (CFD) thermal models. To determine the junction temperature of the device in the application on a prototype board, use the thermal characterization parameter (JT) to determine the junction temperature by measuring the temperature at the top center of the package case using the following equation: TJ = TT + (JT  PD) where: TT = thermocouple temperature on top of the package (oC) JT = thermal characterization parameter (oC/W) PD = power dissipation in the package (W) MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 7 Electrical Characteristics The thermal characterization parameter is measured in compliance with the JESD51-2 specification using a 40-gauge type T thermocouple epoxied to the top center of the package case. Position the thermocouple so that the thermocouple junction rests on the package. Place a small amount of epoxy on the thermocouple junction and approximately 1 mm of wire extending from the junction. Place the thermocouple wire flat against the package case to avoid measurement errors caused by the cooling effects of the thermocouple wire. References: Semiconductor Equipment and Materials International 3081 Zanker Rd. San Jose, CA., 95134 (408) 943-6900 MIL-SPEC and EIA/JESD (JEDEC) specifications are available from Global Engineering Documents at 800-854-7179 or 303-397-7956. JEDEC specifications are available on the web at http://www.jedec.org. 1. C.E. Triplett and B. Joiner, “An Experimental Characterization of a 272 PBGA Within an Automotive Engine Controller Module,” Proceedings of SemiTherm, San Diego, 1998, pp. 47–54. 2. G. Kromann, S. Shidore, and S. Addison, “Thermal Modeling of a PBGA for Air-Cooled Applications,” Electronic Packaging and Production, pp. 53–58, March 1998. 3. B. Joiner and V. Adams, “Measurement and Simulation of Junction to Board Thermal Resistance and Its Application in Thermal Modeling,” Proceedings of SemiTherm, San Diego, 1999, pp. 212–220. 3.3 Package The MPC5567 is available in packaged form. Read the package options in Section 2, “Ordering Information.” Refer to Section 4, “Mechanicals,” for pinouts and package drawings. 3.4 EMI (Electromagnetic Interference) Characteristics Table 4. EMI Testing Specifications 1 Spec Characteristic Minimum Typical Maximum Unit 0.15 — 1000 MHz 1 Scan range 2 Operating frequency — — fMAX MHz 3 VDD operating voltages — 1.5 — V 4 VDDSYN, VRC33, VDD33, VFLASH, VDDE operating voltages — 3.3 — V 5 VPP, VDDEH, VDDA operating voltages — 5.0 — V 2 6 Maximum amplitude — — 14 32 3 dBuV 7 Operating temperature — — 25 oC 1 EMI testing and I/O port waveforms per SAE J1752/3 issued 1995-03. Qualification testing was performed on the MPC5554 and applied to the MPC5500 family as generic EMI performance data. 2 Measured with the single-chip EMI program. 3 Measured with the expanded EMI program. MPC5567 Microcontroller Data Sheet, Rev. 2 8 Freescale Semiconductor Electrical Characteristics 3.5 ESD (Electromagnetic Static Discharge) Characteristics Table 5. ESD Ratings 1, 2 Characteristic Symbol Value Unit 2000 V R1 1500  C 100 pF ESD for human body model (HBM) HBM circuit description 500 (all pins) ESD for field induced charge model (FDCM) V 750 (corner pins) Number of pulses per pin: Positive pulses (HBM) Negative pulses (HBM) — — 1 1 — — Interval of pulses — 1 second 1 2 All ESD testing conforms to CDF-AEC-Q100 Stress Test Qualification for Automotive Grade Integrated Circuits. Device failure is defined as: ‘If after exposure to ESD pulses, the device does not meet the device specification requirements, which includes the complete DC parametric and functional testing at room temperature and hot temperature. Voltage Regulator Controller (VRC) and Power-On Reset (POR) Electrical Specifications 3.6 The following table lists the VRC and POR electrical specifications: Table 6. VRC and POR Electrical Specifications Spec 1 Characteristic 3.3 V (VDDSYN) POR 3 RESET pin supply (VDDEH6) POR 1, 2 1 VRC33 voltage 6 Current can be sourced 7 Max. Units VPOR15 1.1 1.1 1.35 1.35 V Asserted (ramp up) Negated (ramp up) Asserted (ramp down) Negated (ramp down) VPOR33 0.0 2.0 2.0 0.0 0.30 2.85 2.85 0.30 V Negated (ramp up) Asserted (ramp down) VPOR5 2.0 2.0 2.85 2.85 V VTRANS_START 1.0 2.0 V When VRC allows the pass transistor to completely turn on 3, 4 VTRANS_ON 2.0 2.85 V When the voltage is greater than the voltage at which the VRC keeps the 1.5 V supply in regulation 5, 6 VVRC33REG 3.0 — V 11.0 — mA 9.0 — mA 7.5 — mA — 1.0 V Before VRC allows the pass transistor to start turning on 4 5 Min. Negated (ramp up) Asserted (ramp down) 1.5 V (VDD) POR 1 2 Symbol by VRCCTL at Tj: –40o C o 25 C 150o 8 IVRCCTL 7 C Voltage differential during power up such that: VDD33 can lag VDDSYN or VDDEH6 before VDDSYN and VDDEH6 reach the VPOR33 and VPOR5 minimums respectively. VDD33_LAG MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 9 Electrical Characteristics Table 6. VRC and POR Electrical Specifications (continued) Spec 9 10 Characteristic Absolute value of slew rate on power supply pins Required gain at Tj: IDD  IVRCCTL (@ fsys = fMAX) 6, 7, 8, 9 Symbol Min. Max. Units — — 50 V/ms 40 — — 45 — — 55 500 — o – 40 C o 25 C o 150 C BETA10 1 The internal POR signals are VPOR15, VPOR33, and VPOR5. On power up, assert RESET before the internal POR negates. RESET must remain asserted until the power supplies are within the operating conditions as specified in Table 9 DC Electrical Specifications. On power down, assert RESET before any power supplies fall outside the operating conditions and until the internal POR asserts. 2 VIL_S (Table 9, Spec15) is guaranteed to scale with VDDEH6 down to VPOR5. 3 Supply full operating current for the 1.5 V supply when the 3.3 V supply reaches this range. 4 It is possible to reach the current limit during ramp up—do not treat this event as short circuit current. 5 At peak current for device. 6 Requires compliance with Freescale’s recommended board requirements and transistor recommendations. Board signal traces/routing from the VRCCTL package signal to the base of the external pass transistor and between the emitter of the pass transistor to the VDD package signals must have a maximum of 100 nH inductance and minimal resistance (less than 1 ). VRCCTL must have a nominal 1 F phase compensation capacitor to ground. VDD must have a 20 F (nominal) bulk capacitor (greater than 4 F over all conditions, including lifetime). Place high-frequency bypass capacitors consisting of eight 0.01 F, two 0.1 F, and one 1 F capacitors around the package on the VDD supply signals. 7 I VRCCTL is measured at the following conditions: VDD = 1.35 V, VRC33 = 3.1 V, VVRCCTL = 2.2 V. 8 Refer to Table 1 for the maximum operating frequency. 9 Values are based on I DD from high-use applications as explained in the IDD Electrical Specification. 10 Represents the worst-case external transistor BETA. It is measured on a per-part basis and calculated as (I DD  IVRCCTL). 3.7 Power-Up/Down Sequencing Power sequencing between the 1.5 V power supply and VDDSYN or the RESET power supplies is required if using an external 1.5 V power supply with VRC33 tied to ground (GND). To avoid power-sequencing, VRC33 must be powered up within the specified operating range, even if the on-chip voltage regulator controller is not used. Refer to Section 3.7.2, “Power-Up Sequence (VRC33 Grounded),” and Section 3.7.3, “Power-Down Sequence (VRC33 Grounded).” Power sequencing requires that VDD33 must reach a certain voltage where the values are read as ones before the POR signal negates. Refer to Section 3.7.1, “Input Value of Pins During POR Dependent on VDD33.” Although power sequencing is not required between VRC33 and VDDSYN during power up, VRC33 must not lead VDDSYN by more than 600 mV or lag by more than 100 mV for the VRC stage turn-on to operate within specification. Higher spikes in the emitter current of the pass transistor occur if VRC33 leads or lags VDDSYN by more than these amounts. The value of that higher spike in current depends on the board power supply circuitry and the amount of board level capacitance. Furthermore, when all of the PORs negate, the system clock starts to toggle, adding another large increase of the current consumed by VRC33. If VRC33 lags VDDSYN by more than 100 mV, the increase in current consumed can drop VDD low enough to assert the 1.5 V POR again. Oscillations are possible when the 1.5 V POR asserts and stops the system clock, causing the voltage on VDD to rise until the 1.5 V POR negates again. All oscillations stop when VRC33 is powered sufficiently. MPC5567 Microcontroller Data Sheet, Rev. 2 10 Freescale Semiconductor Electrical Characteristics When powering down, VRC33 and VDDSYN have no delta requirement to each other, because the bypass capacitors internal and external to the device are already charged. When not powering up or down, no delta between VRC33 and VDDSYN is required for the VRC to operate within specification. There are no power up/down sequencing requirements to prevent issues such as latch-up, excessive current spikes, and so on. Therefore, the state of the I/O pins during power up and power down varies depending on which supplies are powered. Table 7 gives the pin state for the sequence cases for all pins with pad type pad_fc (fast type). Table 7. Pin Status for Fast Pads During the Power Sequence VDDE VDD33 VDD POR Pin Status for Fast Pad Output Driver pad_fc (fast) Low — — Asserted Low VDDE Low Low Asserted High VDDE Low VDD Asserted High VDDE VDD33 Low Asserted High impedance (Hi-Z) VDDE VDD33 VDD Asserted Hi-Z VDDE VDD33 VDD Negated Functional Table 8 gives the pin state for the sequence cases for all pins with pad type pad_mh (medium type) and pad_sh (slow type). Table 8. Pin Status for Medium and Slow Pads During the Power Sequence VDDEH VDD POR Pin Status for Medium and Slow Pad Output Driver pad_mh (medium) pad_sh (slow) Low — Asserted Low VDDEH Low Asserted High impedance (Hi-Z) VDDEH VDD Asserted Hi-Z VDDEH VDD Negated Functional The values in Table 7 and Table 8 do not include the effect of the weak-pull devices on the output pins during power up. Before exiting the internal POR state, the voltage on the pins go to a high-impedance state until POR negates. When the internal POR negates, the functional state of the signal during reset applies and the weak-pull devices (up or down) are enabled as defined in the device reference manual. If VDD is too low to correctly propagate the logic signals, the weak-pull devices can pull the signals to VDDE and VDDEH. To avoid this condition, minimize the ramp time of the VDD supply to a time period less than the time required to enable the external circuitry connected to the device outputs. During initial power ramp-up, when Vstby is 0.6v or above. a typical current of 1-3mA and maximum of 4mA may be seen until VDD is applied. This current will not reoccur until Vstby is lowered below Vstby min. specification. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 11 Electrical Characteristics Figure 2 shows an approximate interpolation of the ISTBY worst-case specification to estimate values at different voltages and temperatures. The vertical lines shown at 25 C, 60 C, and 150 C in Figure 2 are the actual IDD_STBY specifications (27d) listed in Table 9. Figure 2. fISTBY Worst-case Specifications MPC5567 Microcontroller Data Sheet, Rev. 2 12 Freescale Semiconductor Electrical Characteristics 3.7.1 Input Value of Pins During POR Dependent on VDD33 When powering up the device, VDD33 must not lag the latest VDDSYN or RESET power pin (VDDEH6) by more than the VDD33 lag specification listed in Table 6, spec 8. This avoids accidentally selecting the bypass clock mode because the internal versions of PLLCFG[0:1] and RSTCFG are not powered and therefore cannot read the default state when POR negates. VDD33 can lag VDDSYN or the RESET power pin (VDDEH6), but cannot lag both by more than the VDD33 lag specification. This VDD33 lag specification applies during power up only. VDD33 has no lead or lag requirements when powering down. 3.7.2 Power-Up Sequence (VRC33 Grounded) The 1.5 V VDD power supply must rise to 1.35 V before the 3.3 V VDDSYN power supply and the RESET power supply rises above 2.0 V. This ensures that digital logic in the PLL for the 1.5 V power supply does not begin to operate below the specified operation range lower limit of 1.35 V. Because the internal 1.5 V POR is disabled, the internal 3.3 V POR or the RESET power POR must hold the device in reset. Since they can negate as low as 2.0 V, VDD must be within specification before the 3.3 V POR and the RESET POR negate. VDDSYN and RESET Power VDD 2.0 V 1.35 V VDD must reach 1.35 V before VDDSYN and the RESET power reach 2.0 V Figure 3. Power-Up Sequence (VRC33 Grounded) 3.7.3 Power-Down Sequence (VRC33 Grounded) The only requirement for the power-down sequence with VRC33 grounded is if VDD decreases to less than its operating range, VDDSYN or the RESET power must decrease to less than 2.0 V before the VDD power increases to its operating range. This ensures that the digital 1.5 V logic, which is reset only by an ORed POR and can cause the 1.5 V supply to decrease less than its specification value, resets correctly. See Table 6, footnote 1. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 13 Electrical Characteristics 3.8 DC Electrical Specifications Table 9. DC Electrical Specifications (TA = TL to TH) Spec 1 Characteristic Core supply voltage (average DC RMS voltage) 1 Symbol Min Max. Unit VDD 1.35 1.65 V VDDE 1.62 3.6 V 2 Input/output supply voltage (fast input/output) 3 Input/output supply voltage (slow and medium input/output) VDDEH 3.0 5.25 V 4 3.3 V input/output buffer voltage VDD33 3.0 3.6 V 5 Voltage regulator control input voltage VRC33 3.0 3.6 V VDDA 4.5 5.25 V VPP 4.5 5.25 V 2 6 Analog supply voltage 8 Flash programming voltage 3 9 Flash read voltage VFLASH 3.0 3.6 V 10 SRAM standby voltage 4 VSTBY 0.8 1.2 V 11 Clock synthesizer operating voltage VDDSYN 3.0 3.6 V 12 Fast I/O input high voltage VIH_F 0.65  VDDE VDDE + 0.3 V 13 Fast I/O input low voltage VIL_F VSS – 0.3 0.35  VDDE V 14 Medium and slow I/O input high voltage VIH_S 0.65  VDDEH VDDEH + 0.3 V 15 Medium and slow I/O input low voltage VIL_S VSS – 0.3 0.35  VDDEH V 16 Fast input hysteresis VHYS_F 0.1  VDDE V 17 Medium and slow I/O input hysteresis VHYS_S 0.1  VDDEH V 18 Analog input voltage VINDC VSSA – 0.3 VDDA + 0.3 V 19 Fast output high voltage (IOH_F = –2.0 mA) VOH_F 0.8  VDDE — V 20 Slow and medium output high voltage IOH_S = –2.0 mA IOH_S = –1.0 mA VOH_S 0.80  VDDEH 0.85  VDDEH — V 21 Fast output low voltage (IOL_F = 2.0 mA) VOL_F — 0.2  VDDE V 22 Slow and medium output low voltage IOL_S = 2.0 mA IOL_S = 1.0 mA VOL_S — Load capacitance (fast I/O) 5 DSC (SIU_PCR[8:9]) = 0b00 = 0b01 = 0b10 = 0b11 CL 24 Input capacitance (digital pins) 25 26 23 V 0.20  VDDEH 0.15  VDDEH — — — — 10 20 30 50 pF pF pF pF CIN — 7 pF Input capacitance (analog pins) CIN_A — 10 pF Input capacitance: (Shared digital and analog pins AN[12]_MA[0]_SDS, AN[13]_MA[1]_SDO, AN[14]_MA[2]_SDI, and AN[15]_FCK) CIN_M — 12 pF MPC5567 Microcontroller Data Sheet, Rev. 2 14 Freescale Semiconductor Electrical Characteristics Table 9. DC Electrical Specifications (TA = TL to TH) (continued) Spec Characteristic Symbol Min Max. Unit IDD IDD IDD IDD — — — — 550 450 600 490 mA mA mA mA IDD IDD IDD IDD — — — — 460 380 520 420 mA mA mA mA IDD IDD IDD IDD — — — — 350 290 400 330 mA mA mA mA 27d RAM standby current.10 IDD_STBY @ 25o C VSTBY @ 0.8 V VSTBY @ 1.0 V VSTBY @ 1.2 V IDD_STBY IDD_STBY IDD_STBY — — — 20 30 50 A A A IDD_STBY @ 60o C VSTBY @ 0.8 V VSTBY @ 1.0 V VSTBY @ 1.2 V IDD_STBY IDD_STBY IDD_STBY — — — 70 100 200 A A A IDD_STBY @ 150o C (Tj) VSTBY @ 0.8 V VSTBY @ 1.0 V VSTBY @ 1.2 V IDD_STBY IDD_STBY IDD_STBY — — — 1200 1500 2000 A A A VDD33 11 IDD_33 — 2 + (values derived from procedure of footnote 11) mA VFLASH IVFLASH — 10 mA VDDSYN IDDSYN — 15 mA IDD_A IREF IPP — — — 20.0 1.0 25.0 mA mA mA 27a Operating current 1.5 V supplies @ 135 MHz: 6 VDD (including VDDF max current) @1.65 V typical use 7, 8 VDD (including VDDF max current) @1.35 V typical use 7, 8 VDD (including VDDF max current) @1.65 V high use 8, 9 VDD (including VDDF max current) @1.35 V high use 8, 9 27b Operating current 1.5 V supplies @ 114 MHz: 6 VDD (including VDDF max current) @1.65 V typical use 7, 8 VDD (including VDDF max current) @1.35 V typical use 7, 8 VDD (including VDDF max current) @1.65 V high use 8, 9 VDD (including VDDF max current) @1.35 V high use 8, 9 27c Operating current 1.5 V supplies @ 82 MHz: 6 VDD (including VDDF max current) @1.65 V typical use 7, 8 VDD (including VDDF max current) @1.35 V typical use 7, 8 VDD (including VDDF max current) @1.65 V high use 8, 9 VDD (including VDDF max current) @1.35 V high use 8, 9 28 29 Operating current 3.3 V supplies @ fMAX MHz Operating current 5.0 V supplies (12 MHz ADCLK): VDDA (VDDA0 + VDDA1) Analog reference supply current (VRH, VRL) VPP MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 15 Electrical Characteristics Table 9. DC Electrical Specifications (TA = TL to TH) (continued) Spec 30 31 Characteristic Operating current VDDE supplies: 12 VDDEH1 VDDE2 VDDE3 VDDEH4 VDDE5 VDDEH6 VDDE7 VDDEH8 VDDEH9 Fast I/O weak pullup current 13 1.62–1.98 V 2.25–2.75 V 3.00–3.60 V Slow and medium I/O weak pullup/down current 13 3.0–3.6 V 4.5–5.5 V 33 I/O input leakage current 14 34 DC injection current (per pin) 35 Analog input current, channel off 15 35a Analog input current, shared analog / digital pins (AN[12], AN[13], AN[14], AN[15]) 1 Min Max. Unit IDD1 IDD2 IDD3 IDD4 IDD5 IDD6 IDD7 IDD8 IDD9 — — — — — — — — — Refer to footnote 12 mA mA mA mA mA mA mA mA mA 10 20 20 110 130 170 A A A 10 20 20 100 130 170 A A A IACT_S 10 20 150 170 A A IINACT_D –2.5 2.5 A IIC –2.0 2.0 mA IINACT_A –150 150 nA IINACT_AD –2.5 2.5 A VSS – VSSA –100 100 mV VRL VSSA – 0.1 VSSA + 0.1 V VRL – VSSA –100 100 mV VRH VDDA – 0.1 VDDA + 0.1 V VRH – VRL 4.5 5.25 V IACT_F Fast I/O weak pulldown current 13 1.62–1.98 V 2.25–2.75 V 3.00–3.60 V 32 Symbol 36 VSS to VSSA differential voltage 16 37 Analog reference low voltage 38 VRL differential voltage 39 Analog reference high voltage 40 VREF differential voltage 41 VSSSYN to VSS differential voltage VSSSYN – VSS –50 50 mV 42 VRCVSS to VSS differential voltage VRCVSS – VSS –50 50 mV 43 VDDF to VDD differential voltage VDDF – VDD –100 100 mV 43a VRC33 to VDDSYN differential voltage VRC33 – VDDSYN –0.1 0.1 17 V VIDIFF –2.5 2.5 V TA = (TL to TH) TL TH C — — 50 V/ms 44 Analog input differential signal range (with common mode 2.5 V) 45 Operating temperature range, ambient (packaged) 46 Slew rate on power-supply pins VDDE2 and VDDE3 are limited to 2.25–3.6 V only if SIU_ECCR[EBTS] = 0; VDDE2 and VDDE3 have a range of 1.6–3.6 V if SIU_ECCR[EBTS] = 1. MPC5567 Microcontroller Data Sheet, Rev. 2 16 Freescale Semiconductor Electrical Characteristics 2 | VDDA0 – VDDA1 | must be < 0.1 V. VPP can drop to 3.0 V during read operations. 4 If standby operation is not required, connect VSTBY to ground. 5 Applies to CLKOUT, external bus pins, and Nexus pins. 6 Maximum average RMS DC current. 7 Average current measured on automotive benchmark. 8 Peak currents can be higher on specialized code. 9 High use current measured while running optimized SPE assembly code with all code and data 100% locked in cache (0% miss rate) with all channels of the eMIOS and eTPU running autonomously, plus the eDMA transferring data continuously from SRAM to SRAM. Higher currents are possible if an idle loop that crosses cache lines is run from cache. Write code to avoid this condition. 10 The current specification relates to average standby operation after SRAM has been loaded with data. For power up current see Section 3.7, “Power-Up/Down Sequencing”, Figure 2. 11 Power requirements for the VDD33 supply depend on the frequency of operation, load of all I/O pins, and the voltages on the I/O segments. Refer to Table 11 for values to calculate the power dissipation for a specific operation. 12 Power requirements for each I/O segment are dependent on the frequency of operation and load of the I/O pins on a particular I/O segment, and the voltage of the I/O segment. Refer to Table 10 for values to calculate power dissipation for specific operation. The total power consumption of an I/O segment is the sum of the individual power consumptions for each pin on the segment. 13 Absolute value of current, measured at V and V . IL IH 14 Weak pullup/down inactive. Measured at V DDE = 3.6 V and VDDEH = 5.25 V. Applies to pad types: pad_fc, pad_sh, and pad_mh. 15 Maximum leakage occurs at maximum operating temperature. Leakage current decreases by approximately one-half for each 8 oC to 12 oC, in the ambient temperature range of 50 oC to 125 oC. Applies to pad types: pad_a and pad_ae. 16 V SSA refers to both VSSA0 and VSSA1. | VSSA0 – VSSA1 | must be < 0.1 V. 17 Up to 0.6 V during power up and power down. 3 MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 17 Electrical Characteristics 3.8.1 I/O Pad Current Specifications The power consumption of an I/O segment depends on the usage of the pins on a particular segment. The power consumption is the sum of all output pin currents for a segment. The output pin current can be calculated from Table 10 based on the voltage, frequency, and load on the pin. Use linear scaling to calculate pin currents for voltage, frequency, and load parameters that fall outside the values given in Table 10. Table 10. I/O Pad Average DC Current (TA = TL to TH)1 Frequency (MHz) Load2 (pF) Voltage (V) Drive Select / Slew Rate Control Setting Current (mA) 25 50 5.25 11 8.0 10 50 5.25 01 3.2 2 50 5.25 00 0.7 4 2 200 5.25 00 2.4 5 50 50 5.25 11 17.3 Spec Pad Type Symbol 1 2 3 6 Slow IDRV_SH 20 50 5.25 01 6.5 3.33 50 5.25 00 1.1 8 3.33 200 5.25 00 3.9 9 66 10 3.6 00 2.8 7 Medium IDRV_MH 10 66 20 3.6 01 5.2 11 66 30 3.6 10 8.5 12 66 50 3.6 11 11.0 13 66 10 1.98 00 1.6 14 66 20 1.98 01 2.9 15 66 30 1.98 10 4.2 16 66 50 1.98 11 6.7 17 56 10 3.6 00 2.4 18 56 20 3.6 01 4.4 19 56 30 3.6 10 7.2 20 56 50 3.6 11 9.3 56 10 1.98 00 1.3 22 56 20 1.98 01 2.5 23 56 30 1.98 10 3.5 24 56 50 1.98 11 5.7 25 40 10 3.6 00 1.7 26 40 20 3.6 01 3.1 27 40 30 3.6 10 5.1 21 Fast IDRV_FC 28 40 50 3.6 11 6.6 29 40 10 1.98 00 1.0 30 40 20 1.98 01 1.8 31 40 30 1.98 10 2.5 32 40 50 1.98 11 4.0 1 These values are estimates from simulation and are not tested. Currents apply to output pins only. 2 All loads are lumped. MPC5567 Microcontroller Data Sheet, Rev. 2 18 Freescale Semiconductor Electrical Characteristics 3.8.2 I/O Pad VDD33 Current Specifications The power consumption of the VDD33 supply dependents on the usage of the pins on all I/O segments. The power consumption is the sum of all input and output pin VDD33 currents for all I/O segments. The output pin VDD33 current can be calculated from Table 11 based on the voltage, frequency, and load on all fast (pad_fc) pins. The input pin VDD33 current can be calculated from Table 11 based on the voltage, frequency, and load on all pad_sh and pad_mh pins. Use linear scaling to calculate pin currents for voltage, frequency, and load parameters that fall outside the values given in Table 11. Table 11. VDD33 Pad Average DC Current (TA = TL to TH) 1 Spec Pad Type Symbol Frequency (MHz) Load 2 (pF) VDD33 (V) VDDE (V) Drive Select Current (mA) Inputs 1 Slow I33_SH 66 0.5 3.6 5.5 NA 0.003 2 Medium I33_MH 66 0.5 3.6 5.5 NA 0.003 3 66 10 3.6 3.6 00 0.35 4 66 20 3.6 3.6 01 0.53 5 66 30 3.6 3.6 10 0.62 6 66 50 3.6 3.6 11 0.79 7 66 10 3.6 1.98 00 0.35 8 66 20 3.6 1.98 01 0.44 9 66 30 3.6 1.98 10 0.53 10 66 50 3.6 1.98 11 0.70 11 56 10 3.6 3.6 00 0.30 12 56 20 3.6 3.6 01 0.45 13 56 30 3.6 3.6 10 0.52 Outputs 14 56 50 3.6 3.6 11 0.67 56 10 3.6 1.98 00 0.30 16 56 20 3.6 1.98 01 0.37 17 56 30 3.6 1.98 10 0.45 18 56 50 3.6 1.98 11 0.60 19 40 10 3.6 3.6 00 0.21 20 40 20 3.6 3.6 01 0.31 21 40 30 3.6 3.6 10 0.37 15 Fast I33_FC 22 40 50 3.6 3.6 11 0.48 23 40 10 3.6 1.98 00 0.21 24 40 20 3.6 1.98 01 0.27 25 40 30 3.6 1.98 10 0.32 26 40 50 3.6 1.98 11 0.42 1 These values are estimated from simulation and not tested. Currents apply to output pins for the fast pads only and to input pins for the slow and medium pads only. 2 All loads are lumped. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 19 Electrical Characteristics 3.9 Oscillator and FMPLL Electrical Characteristics Table 12. FMPLL Electrical Specifications (VDDSYN = 3.0–3.6 V; VSS = VSSSYN = 0.0 V; TA = TL to TH) Spec Characteristic Symbol Minimum Maximum 1 PLL reference frequency range: 1 Crystal reference (20)2 Crystal reference (40)3 External reference (20)2 External reference (40)3 Dual controller (1:1 mode) fref_crystal fref_crystal fref_ext fref_ext fref_1:1 8 > 20 8 > 20 24 20 40 20 40 fsys  2 2 System frequency 4 fsys fICO(MIN)  2RFD fMAX 5 MHz 3 System clock period tCYC — 1  fsys ns 4 Loss of reference frequency 6 fLOR 100 1000 kHz 5 Self-clocked mode (SCM) frequency 7 fSCM 7.4 17.5 MHz EXTAL input high voltage crystal mode 8 VIHEXT VXTAL + 0.4 V — V All other modes [dual controller (1:1), bypass, external reference] VIHEXT (VDDE5  2) + 0.4 V — V EXTAL input low voltage crystal mode 9 VILEXT — VXTAL – 0.4 V V All other modes [dual controller (1:1), bypass, external reference] VILEXT — (VDDE5 2) – 0.4 V V IXTAL 2 6 mA 6 7 Unit MHz 8 XTAL current 10 9 Total on-chip stray capacitance on XTAL CS_XTAL — 1.5 pF 10 Total on-chip stray capacitance on EXTAL CS_EXTAL — 1.5 pF 11 Crystal manufacturer’s recommended capacitive load CL Refer to crystal specification Refer to crystal specification pF Discrete load capacitance to connect to EXTAL CL_EXTAL — (2  CL) – CS_EXTAL – CPCB_EXTAL 11 pF Discrete load capacitance to connect to XTAL CL_XTAL — (2  CL) – CS_XTAL – CPCB_XTAL 11 pF tlpll — 750 s tskew –2 2 ns 12 13 14 PLL lock time 12 15 Dual controller (1:1) clock skew (between CLKOUT and EXTAL) 13, 14 16 Duty cycle of reference tDC 40 60 % 17 Frequency unLOCK range fUL –4.0 4.0 % fSYS 18 Frequency LOCK range fLCK –2.0 2.0 % fSYS MPC5567 Microcontroller Data Sheet, Rev. 2 20 Freescale Semiconductor Electrical Characteristics Table 12. FMPLL Electrical Specifications (continued) (VDDSYN = 3.0–3.6 V; VSS = VSSSYN = 0.0 V; TA = TL to TH) Spec Characteristic Symbol Minimum Maximum 19 CLKOUT period jitter, measured at fSYS max: 15, 16 Peak-to-peak jitter (clock edge to clock edge) Long term jitter (averaged over a 2 ms interval) CJITTER 20 Frequency modulation range limit 17 (do not exceed fsys maximum) 21 ICO frequency fico = [fref_crystal  (MFD + 4)] (PREDIV + 1) 18 fico = [fref_ext  (MFD + 4)] (PREDIV + 1) 22 Predivider output frequency (to PLL) Unit — — 5.0 0.01 CMOD 0.8 2.4 %fSYS fico 48 fMAX MHz fPREDIV 4 20 19 MHz % fCLKOUT 1 Nominal crystal and external reference values are worst-case not more than 1%. The device operates correctly if the frequency remains within ± 5% of the specification limit. This tolerance range allows for a slight frequency drift of the crystals over time. The designer must thoroughly understand the drift margin of the source clock. 2 The 8–20 MHz crystal or external reference values have PLLCFG[2] pulled low. 3 The 20–40 MHz crystal and external reference values have PLLCFG[2] pulled high, and the minimum frequency must be greater than 20 MHz. Use the 8–20 MHz setting (PLLCFG[2] pulled low) if a 20 MHz crystal or external reference is required. To exit RESET when using 40 MHz, set PLLCFG[2] to 1. 4 All internal registers retain data at 0 Hz. 5 Up to the maximum frequency rating of the device (refer to Table 1). 6 Loss of reference frequency is defined as the reference frequency detected internally, which transitions the PLL into self-clocked mode. 7 The PLL operates at self-clocked mode (SCM) frequency when the reference frequency falls below f LOR. SCM frequency is measured on the CLKOUT ball with the divider set to divide-by-two of the system clock. NOTE: In SCM, the MFD and PREDIV have no effect and the RFD is bypassed. 8 Use the EXTAL input high voltage parameter when using the FlexCAN oscillator in crystal mode (no quartz crystals or resonators). (Vextal – Vxtal) must be  400 mV for the oscillator’s comparator to produce the output clock. 9 Use the EXTAL input low voltage parameter when using the FlexCAN oscillator in crystal mode (no quartz crystals or resonators). (Vxtal – Vextal) must be  400 mV for the oscillator’s comparator to produce the output clock. 10 I xtal is the oscillator bias current out of the XTAL pin with both EXTAL and XTAL pins grounded. 11 C PCB_EXTAL and CPCB_XTAL are the measured PCB stray capacitances on EXTAL and XTAL, respectively. 12 This specification applies to the period required for the PLL to relock after changing the MFD frequency control bits in the synthesizer control register (SYNCR). From power up with crystal oscillator reference, the lock time also includes the crystal startup time. 13 PLL is operating in 1:1 PLL mode. 14 V DDE = 3.0–3.6 V. 15 Jitter is the average deviation from the programmed frequency measured over the specified interval at maximum fsys. Measurements are made with the device powered by filtered supplies and clocked by a stable external clock signal. Noise injected into the PLL circuitry via VDDSYN and VSSSYN and variation in crystal oscillator frequency increase the jitter percentage for a given interval. CLKOUT divider is set to divide-by-two. 16 Values are with frequency modulation disabled. If frequency modulation is enabled, jitter is the sum of (jitter + Cmod). 17 Modulation depth selected must not result in f sys value greater than the fsys maximum specified value. 18 f RFD). sys = fico  (2 19 Maximum value for dual controller (1:1) mode is (fMAX 2) with the predivider set to 1 (FMPLL_SYNCR[PREDIV] = 0b001). MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 21 Electrical Characteristics 3.10 eQADC Electrical Characteristics Table 13. eQADC Conversion Specifications (TA = TL to TH) Spec Characteristic Symbol Minimum Maximum Unit FADCLK 1 12 MHz 13 + 2 (15) 14 + 2 (16) 13 + 128 (141) 14 + 128 (142) 1 ADC clock (ADCLK) frequency 1 Conversion cycles Differential Single ended CC 2 3 Stop mode recovery time 2 TSR 10 — s — 1.25 — mV 3 ADCLK cycles 4 Resolution 5 INL: 6 MHz ADC clock INL6 –4 4 Counts 3 6 INL: 12 MHz ADC clock INL12 –8 7 8 9 10 DNL: 6 MHz ADC clock DNL: 12 MHz ADC clock Offset error with calibration Full-scale gain error with calibration 7, 8, 9, 10 8 Counts DNL6 –3 4 34 Counts DNL12 –6 4 6 4 Counts OFFWC –4 5 4 5 Counts GAINWC –8 6 8 6 Counts IINJ –1 1 mA 11 Disruptive input injection current 12 Incremental error due to injection current. All channels are 10 k < Rs 20 40 external reference (20) fref_ext 8  20 external reference (40) fref_ext > 20 40 • Spec 1, footnote 2 in column 1: Changed to: ‘The 8–20 MHz crystal or external reference values have PLLCFG[2] pulled low’ and applies to spec 1, column 2, crystal reference and external reference. • Specs 12 and 13: Grouped (2 x Cl). • Spec 21, column 2: Changed fref_crystal to fref in ICO frequency equation, and added the same equation but substituted fref_ext for fref for the external reference clock, giving: fico = [ fref_crystal  (MFD + 4) ] (PREDIV + 1) fico = [ fref_ext  (MFD + 4) ] (PREDIV + 1) • Spec 21, column 4, Max: Deleted old footnote 18 that reads: The ICO frequency can be higher than the maximum allowable system frequency. For this case, set the CMPLL synthesizer control register reduced frequency divider (FMPLL_SYNCR[RFD]) to divide-by-two (RFD = 0b001). Therefore, for a 40 MHz maximum device (system frequency), program the FMPLL to generate 80 MHz at the ICO output and then divide-by-two the RFD to provide the 40 MHz system clock.’ • Spec 21: Changed column 5 from ‘fSYS’ MHz’ to: ‘fMAX’. • Spec 22: Changed column 4, Max Value from fMAX to 20, and added footnote 17 to read, ‘Maximum value for dual controller (1:1) mode is (fMAX 2) and the predivider set to 1 (FMPLL_SYNCR[PREDIV] = 0b001).’ Table 13 eQADC Conversion Specifications: Added (TA = TL – TH) to the table title. Table 14 Flash Program and Erase Specifications: • Added (TA = TL – TH) to the table title. • Specs 7, 8, 9, and 10 Changed values for the H7Fa Flash pre-program and erase times and used the previous values for Typical values. -- 48 KB: from 340 to 345 -- 64 KB: from 400 to 415 • Spec 8, 128KB block pre-program and erase time, Max column value from 15,000 to 7,500. • Moved footnote 1 from the table title to directly after the ‘Typical’ in the column 5 header. • Footnote 2: Changed from: ‘Initial factory condition: 100program/erase cycles, 25 oC, typical supply voltage, 80 MHz minimum system frequency.‘ To: ‘Initial factory condition: 100program/erase cycles, 25 oC, using a typical supply voltage measured at a minimum system frequency of 80 MHz.’ Table 15 Flash EEPROM Module Life: • Replaced (Full Temperature Range) with (TA = TL – TH) in the table title. • Spec 1b, Min. column value changed from 10,000 to 1,000. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 63 Revision History for the MPC5567 Data Sheet Table 35. Table and Figure Changes Between Rev. 0.0 and 1.0 (continued) Location Description of Changes Table 16 FLASH BIU Settings vs. Frequency of Operations: • ‘Added footnote 1 to the end of the table title, The footnote reads: ‘Illegal combinations exist. Use entries from the same row in this table.’ • Moved footnote 2:’ For maximum flash performance, set to 0b11’ to the ‘DPFEN’ column header. • Deleted the x-refs in the ‘DPFEN’ column for the rows. • Created a x-ref for footnote 2 and inserted in the ‘IPFEN’ column header. • Deleted the x-refs in the ‘IPFEN’ column for the rows. • Moved footnote 3:’ For maximum flash performance, set to 0b110’ to the ‘PFLIM’ column header. • Deleted the x-refs in the ‘PFLIM’ column for the rows. • Moved footnote 4:’ For maximum flash performance, set to 0b1’ to the ‘BFEN’ column header. • Deleted the x-refs in the ‘BFEN’ column for the rows. • Changed footnotes 1, 5, and 6 to become footnotes 5, 6, and 7 -- footnote 5 82 MHz parts allow for 80 MHz system clock + 2% frequency modulation (FM). -- footnote 6 102 MHz parts allow for 100 MHz system clock + 2% FM. -- footnote 7 135 MHz parts allow for 132 MHz system clock + 2% FM. • Footnote 9: added to the end of the 1st column for the 147 MHz row that reads: Preliminary setting. Final setting pending characterization. Table 17 Pad AC Specifications and Table 18 Derated Pad AC Specifications: The changes are identical in the tables. Footnote 1, deleted ‘FSYS = 132 MHz.’ Footnote 2, changed from ‘tested’ to ‘(not tested).’ Footnote 3, changed from ‘Out delay. . .’ to ‘The output delay. . .’, Changed from ‘ Add a maximum of one system clock to the output delay to get the output delay with respect to the system clock‘ to ‘To calculate the output delay with respect to the system clock, add a maximum of one system clock to the output delay.’ • Footnote 4: changed ‘Delay’ to ‘The output delay.’ • Footnote 5: deleted ‘before qualification.’ • Changed from ‘This parameter is supplied for reference and is not guaranteed by design and not tested’ to ‘This parameter is supplied for reference and is guaranteed by design and tested.’ • • • • Table 19 Reset and Configuration Pin Timing: Footnote 1, deleted ‘FSYS = 132 MHz,’ and ‘VDD = 1.35–1.65.’ Table 20 JTAG Pin AC Electrical Characteristics: • Footnote 1, deleted: ‘, and CL = 30 pF with DSC = 0b10, SRC = 0b11’ • Footnote 1, changed ‘functional’ to ‘Nexus.’ Table 21 Nexus Debug Port Timing. Changed Spec 12, TCK Low to TDO Data Valid: Changed ‘VDDE = 3.0 to 3.6 volts’ maximum value in column 4 from 9 to 10. Now reads ‘VDDE = 3.0–3.6 V’ with a max value of 10. MPC5567 Microcontroller Data Sheet, Rev. 2 64 Freescale Semiconductor Revision History for the MPC5567 Data Sheet Table 35. Table and Figure Changes Between Rev. 0.0 and 1.0 (continued) Location Description of Changes Table 22 Bus Operation Timing: • External Bus Frequency in the table heading: Added footnote that reads: Speed is the nominal maximum frequency. Max speed is the maximum speed allowed including frequency modulation (FM). 82 MHz parts allow for 80 MHz system clock + 2% FM; 114 MHz parts allow for 112 MHz system clock + 2% FM, and 135 MHz parts allow for 132 MHz system clock + 2% FM. • Spec 1: Changed the values in Min. columns: 40 MHz from 25 to 24.4; 56 MHz from 17.9 to 17.5, and the 66 MHz from 15.2 to 14.9. • Specs 5 and 6: CLKOUT positive edge to output signals invalid of high: Corrected format to show the bus timing values for various frequencies with EBTS bit = 0 and EBTS bit = 1. • Specs 5, and 6: Deleted the BG, BR, and TSIZ[0:1] signals for arbitration. Added the following calibration signals: CAL_ADDR[10:30], CAL_CS[0, 2:3], CAL_DATA[0:15], CAL_OE, CAL_RD_WR, CAL_TS, CAL_WE/BE[0:1]. • Specs 7 and 8: Deleted the BG, BR, and TSIZ[0:1] signals for arbitration. Added the following calibration signals: CAL_ADDR[10:30], CAL_DATA[0:15], CAL_RD_WR, and CAL_TS. • Added a footnote each for the DATA[0:31], TEA, and WE/BE[0:3] signals in the table: Due to pin limitations, the DATA[16:31], TEA, and WE/BE[2:3] signals are not available on the 324 package. Table 23 External Interrupt Timing: • Footnote 1: Deleted ‘FSYS = 132 MHz.’,‘VDD = 1.35–1.65 V’, ‘VDD33 and VDDSYN = 3.0–3.6 V.’ and ‘ and CL = 200 pF with SRC = 0b11.’ • Deleted second figure after table ‘External Interrupt Setup Timing.’ Table 24 eTPU Timing • Footnote 1: Deleted ‘FSYS = 132 MHz.’, ‘VDD = 1.35–1.65 V’, ‘VDD33 and VDDSYN = 3.0–3.6’ and ‘ and CL = 200 pF with SRC = 0b11.’ • Deleted second figure, ‘eTPU Input/Output Timing’ after this table. • Added Footnote 2: ‘This specification does not include the rise and fall times. When calculating the minimum eTPU pulse width, include the rise and fall times defined in the slew rate control fields (SRC) of the pad configuration registers (PCR).’ Table 25 eMIOS Timing: • Deleted (MTS) from the heading, table, and footnotes. • Footnote 1: Deleted ‘FSYS = 132 MHz’, ‘VDD = 1.35–1.65 V’, ‘VDD33 and VDDSYN = 3.0–3.6 V’ and ‘ and CL = 200 pF with SRC = 0b11.’ • Added Footnote 2: ‘This specification does not include the rise and fall times. When calculating the minimum eMIOS pulse width, include the rise and fall times defined in the slew rate control fields (SRC) of the pad configuration registers (PCR).’ Figure 17 Added eMIOS Timing figure. Table 26 DSPI Timing: • Table Title: Added footnote that reads: Speed is the nominal maximum frequency. Max speed is the maximum speed allowed including frequency modulation (FM). 82 MHz parts allow for 80 MHz system clock + 2% FM; 114 MHz parts allow for 112 MHz system clock + 2% FM, and 135 MHz parts allow for 132 MHz system clock + 2% FM. • Spec1:SCK Cycle Time: changes to values: 80 MHz, min = 24.4, max 2.9; 112 MHz, min = 17.5, max = 2.1; 132 MHz, min = 14.8, max = 1.8. • Footnote 1: Added to beginning of footnote 1 ‘All DSPI timing specifications use the fastest slew rate (SRC = 0b11) on pad type M or MH. DSPI signals using pad types of S or SH have an additional delay based on the slew rate.’ Deleted ‘VDD = 1.35–1.65 V’ and ‘VDD33 and VDDSYN = 3.0–3.6 V. MPC5567 Microcontroller Data Sheet, Rev. 2 Freescale 65 Revision History for the MPC5567 Data Sheet Table 35. Table and Figure Changes Between Rev. 0.0 and 1.0 (continued) Location Description of Changes Table 27 EQADC SSI Timing Characteristics: • • • • Deleted from table title ‘(Pads at 3.3 V or 5.0 V)’ Deleted 1st line in table ‘CLOAD = 25 pF on all outputs. Pad drive strength set to maximum.’ Spec 1: FCK frequency -- removed. Combined footnotes 1 and 2, and moved the new footnote to Spec 2. Moved old footnote 3 that is now footnote 2 to Spec 2. • Footnote 1, deleted ‘VDD = 1.35–1.65 V’ and ‘VDD33 and VDDSYN = 3.0–3.6V.’ Changed ‘CL = 50 pF’ to ‘CL = 25 pF.’ • Footnote 2: added ‘cycle’ after ‘duty’ to read: FCK duty cycle is not 50% when . . . . Figure 32 MPC5567 324 Package: Deleted the version number and date; changed ball label T21 from VRCVSS to PLLCFG2. Figure 36 and Figure 36MPC5567 416 Package: Deleted the version number and date. 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