MPC8240 Integrated Processor Hardware Specifications

Freescale Semiconductor, Inc.
Advance Information
MPC8240EC
Rev. 4, 11/2003
Freescale Semiconductor, Inc...
MPC8240
Integrated Processor
Hardware Specifications
The MPC8240 combines a MPC603e core microprocessor with a PCI bridge. The MPC8240
PCI support allows system designers to rapidly create systems using peripherals already
designed for PCI and the other standard interfaces. The MPC8240 also integrates a
high-performance memory controller that supports various types of DRAM and ROM. The
MPC8240 is the first of a family of products that provide system-level support for industry
standard interfaces with PowerPC™ microprocessor cores.
This hardware specification describes pertinent electrical and physical characteristics of the
MPC8240. For functional characteristics of the processor, refer to the MPC8240 Integrated
Processor User’s Manual (MPC8240UM).
This hardware specification contains the following topics:
Topic
Section 1.1, “Overview”
Section 1.2, “Features”
Section 1.3, “General Parameters”
Section 1.4, “Electrical and Thermal Characteristics”
Section 1.5, “Package Description”
Section 1.6, “PLL Configurations”
Section 1.7, “System Design Information”
Section 1.8, “Document Revision History”
Section 1.9, “Ordering Information”
Page
1
3
5
5
27
34
35
45
49
To locate any published errata or updates for this document, refer to the website at
http://www.motorola.com/semiconductors.
1.1
Overview
The MPC8240 integrated processor is comprised of a peripheral logic block and a 32-bit
superscalar MPC603e core, as shown in Figure 1.
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Overview
Processor Core Block
MPC8240
Additional Features:
• Prog I/O with Watchpoint
• JTAG/COP Interface
• Power Management
Processor
PLL
(64-Bit) Two-Instruction Fetch
Branch
Processing
Instruction Unit
Unit
(BPU)
(64-Bit) Two-Instruction Dispatch
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System
Register
Unit
(SRU)
Integer
Unit
(IU)
FloatingPoint
Unit
(FPU)
Load/Store
Unit
(LSU)
64-Bit
Data
MMU
Instruction
MMU
16-Kbyte
Instruction
Cache
16-Kbyte
Data
Cache
Peripheral Logic Bus
Peripheral Logic Block
Message
Unit
(with I2O)
DMA
Controller
Address
(32-Bit)
Data (64-Bit)
Data Path
ECC Controller
Central
Control
Unit
Memory
Controller
Configuration
Registers
I2 C
I2C
Controller
5 IRQs/
16 Serial
Interrupts
PIC
Interrupt
Controller/
Timers
Address
Translator
Peripheral Logic
PLL
PCI
Arbiter
32-Bit
Five
PCI Interface Request/Grant
Pairs
Address/Control
DRAM/SDRAM/
ROM/Flash/Port X
SDRAM Sync In
DLL
PCI Bus
Interface Unit
Data Bus
(32- or 64-Bit)
with 8-Bit Parity
or ECC
Fanout
Buffers
SDRAM Sync Out
SDRAM Clocks
PCI Clock In
PCI Bus Clocks
OSC In
Figure 1. MPC8240 Block Diagram
The peripheral logic integrates a PCI bridge, memory controller, DMA controller, PIC interrupt controller,
I2O controller, and an I2C controller. The MPC603e core is a full-featured, high-performance processor with
floating-point support, memory management, a 16-Kbyte instruction cache, a 16-Kbyte data cache, and
2
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Features
power management features. The integration reduces the overall packaging requirements and the number of
discrete devices required for an embedded system.
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The MPC8240 contains an internal peripheral logic bus that interfaces the MPC603e core to the peripheral
logic. The core can operate at a variety of frequencies, allowing the designer to trade off performance for
power consumption. The MPC603e core is clocked from a separate PLL, which is referenced to the
peripheral logic PLL. This allows the microprocessor and the peripheral logic block to operate at different
frequencies while maintaining a synchronous bus interface. The interface uses a 64- or 32-bit data bus
(depending on memory data bus width) and a 32-bit address bus along with control signals that enable the
interface between the processor and peripheral logic to be optimized for performance. PCI accesses to the
MPC8240 memory space are passed to the processor bus for snooping purposes when snoop mode is
enabled.
The MPC8240 features serve a variety of embedded applications. In this way, the MPC603e core and
peripheral logic remain general-purpose. The MPC8240 can be used as either a PCI host or an agent
controller.
1.2
Features
This section summarizes features of the MPC8240. Major features of the MPC8240 are as follows:
•
Peripheral logic
— Memory interface
– Programmable timing supporting either FPM DRAM, EDO DRAM, or SDRAM
– High-bandwidth bus (32- or 64-bit data bus) to DRAM
– Supports one to eight banks of 4-, 16-, 64-, or 128-Mbit memory devices
– Supports 1-Mbyte to 1-Gbyte DRAM memory
– 16 Mbytes of ROM space
– 8-, 32-, or 64-bit ROM
– Write buffering for PCI and processor accesses
– Supports normal parity, read-modify-write (RMW), or ECC
– Data-path buffering between memory interface and processor
– Low-voltage TTL logic (LVTTL) interfaces
– Port X: 8-, 32-, or 64-bit general-purpose I/O port using ROM controller interface with
programmable address strobe timing
— 32-bit PCI interface operating up to 66 MHz
– PCI 2.1-compliant
– PCI 5.0-V tolerance
– Support for PCI locked accesses to memory
– Support for accesses to PCI memory, I/O, and configuration spaces
– Selectable big- or little-endian operation
– Store gathering of processor-to-PCI write and PCI-to-memory write accesses
– Memory prefetching of PCI read accesses
– Selectable hardware-enforced coherency
– PCI bus arbitration unit (five request/grant pairs)
– PCI agent mode capability
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Features
•
•
•
•
4
– Address translation unit
– Some internal configuration registers accessible from PCI
— Two-channel integrated DMA controller (writes to ROM/Port X not supported)
– Supports direct mode or chaining mode (automatic linking of DMA transfers)
– Supports scatter gathering—Read or write discontinuous memory
– Interrupt on completed segment, chain, and error
– Local-to-local memory
– PCI-to-PCI memory
– PCI-to-local memory
– PCI memory-to-local memory
— Message unit
– Two doorbell registers
– Two inbound and two outbound messaging registers
– I2O message controller
— I2C controller with full master/slave support (except broadcast all)
— Programmable interrupt controller (PIC)
– Five hardware interrupts (IRQs) or 16 serial interrupts
– Four programmable timers
— Integrated PCI bus, CPU, and SDRAM clock generation
— Programmable PCI bus, 60x, and memory interface output drivers
Dynamic power management—Supports 60x nap, doze, and sleep modes
Programmable input and output signals with watchpoint capability
Built-in PCI bus performance monitor facility
— Debug features
– Memory attribute and PCI attribute signals
– Debug address signals
– MIV signal—Marks valid address and data bus cycles on the memory bus
– Error injection/capture on data path
– IEEE 1149.1 (JTAG)/test interface
Processor core interface
— High-performance, superscalar processor core
— Integer unit (IU), floating-point unit (FPU) (software enabled or disabled), load/store unit
(LSU), system register unit (SRU), and a branch processing unit (BPU)
— 16-Kbyte instruction cache
— 16-Kbyte data cache
— Lockable L1 cache, entire cache or on a per-way basis
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General Parameters
1.3
General Parameters
The following list provides a summary of the general parameters of the MPC8240:
Technology
Die size
Transistor count
Logic design
Packages
Core power supply
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I/O power supply
1.4
0.29-µm CMOS, five-layer metal
73 mm2
3.1 million
Fully-static
Surface mount 352 tape ball grid array (TBGA)
2.5 V ± 5% V DC (nominal; see Table 2 for recommended operating
conditions)
3.0- to 3.6-V DC
Electrical and Thermal Characteristics
This section provides the AC and DC electrical specifications and thermal characteristics for the MPC8240.
1.4.1
DC Electrical Characteristics
The following sections describe the MPC8240 absolute maximum ratings, recommended operating
conditions, DC electrical specifications, output driver characteristics, and power data characteristics.
1.4.1.1
Absolute Maximum Ratings
The tables in this section describe the MPC8240 DC electrical characteristics. Table 1 provides the absolute
maximum ratings.
Table 1. Absolute Maximum Ratings
Characteristic 1
Symbol
Range
Unit
VDD
–0.3 to 2.75
V
Supply voltage—memory bus drivers
GVDD
–0.3 to 3.6
V
Supply voltage—PCI and standard I/O buffers
OVDD
–0.3 to 3.6
V
Supply voltage—PLLs and DLL
AVDD/AVDD2/LAVDD
–0.3 to 2.75
V
Supply voltage—PCI reference
LVDDD
–0.3 to 5.4
V
Vin
–0.3 to 3.6
V
Tj
0 to 105
°C
Tstg
–55 to 150
°C
Supply voltage—CPU core and peripheral logic
Input voltage
2
Operational die-junction temperature range
Storage temperature range
Notes:
1. Functional and tested operating conditions are given in Table 2. Absolute maximum ratings are stress ratings only,
and functional operation at the maximums is not guaranteed. Stresses beyond those listed may affect device
reliability or cause permanent damage to the device.
2. PCI inputs with LVDD = 5 V ± 5% V DC may be correspondingly stressed at voltages exceeding LVDD + 0.5 V DC.
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Electrical and Thermal Characteristics
1.4.1.2
Recommended Operating Conditions
Table 2 provides the recommended operating conditions for the MPC8240.
Table 2. Recommended Operating Conditions 1
Symbol
Recommended
Value
Unit
Notes
VDD
2.5 ± 5%
V
4, 6
Supply voltage for PCI and standard bus standards
OVDD
3.3 ± 0.3
V
6
Supply voltages for memory bus drivers
GVDD
3.3 ± 5%
V
8
PLL supply voltage—CPU core logic
AVDD
2.5 ± 5%
V
4, 6
PLL supply voltage—peripheral logic
AVDD2
2.5 ± 5%
V
4, 7
DLL supply voltage
LAVDD
2.5 ± 5%
V
4, 7
LVDD
5.0 ± 5%
V
9, 10
3.3 ± 0.3
V
9, 10
0 to 3.6 or 5.75
V
2, 3
0 to 3.6
V
5
0 to 105
°C
Characteristic
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Supply voltage
PCI reference
Input voltage
LVDD input-tolerant signals
Vin
All other inputs
Die-junction temperature
Tj
Notes:
1. These are the recommended and tested operating conditions. Proper device operation outside of these conditions
is not guaranteed.
2. These signals are designed to withstand LVDD + 0.5 V DC when LVDD is connected to a 3.3- or 5.0-V DC power
supply.
3. LVDD input tolerant signals: PCI interface, PIC control, and OSC_IN signals.
4. See Section 1.9, “Ordering Information,” for details on a modified voltage (VDD) version device.
Cautions:
5. Input voltage (Vin) must not be greater than the supply voltage (VDD/AVDD/AVDD2/LAVDD) by more than 2.5 V at all
times, including during power-on reset.
6. OVDD must not exceed VDD/AVDD/AVDD2/LAVDD by more than 1.8 V at any time, including during power-on reset.
This limit may be exceeded for a maximum of 20 ms during power-on reset and power-down sequences.
7. VDD/AVDD/AVDD2/LAVDD must not exceed OVDD by more than 0.6 V at any time, including during power-on reset.
This limit may be exceeded for a maximum of 20 ms during power-on reset and power-down sequences.
8. GVDD must not exceed VDD/AVDD/AVDD2/LAVDD by more than 1.8 V at any time, including during power-on reset.
This limit may be exceeded for a maximum of 20 ms during power-on reset and power-down sequences.
9. LVDD must not exceed VDD/AVDD/AVDD2/LAVDD by more than 5.4 V at any time, including during power-on reset.
This limit may be exceeded for a maximum of 20 ms during power-on reset and power-down sequences.
10.LVDD must not exceed OVDD by more than 3.6 V at any time, including during power-on reset. This limit may be
exceeded for a maximum of 20 ms during power-on reset and power-down sequences.
6
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Electrical and Thermal Characteristics
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DC Power Supply Voltage
Figure 2 shows the supply voltage sequencing and separation cautions.
LVDD @ 5 V
5V
10 9
3.3 V
10
OVDD/GVDD/(LVDD @ 3.3 V - - - -)
9
2.5 V
See Note 1
6,8
7
VDD/AVDD/AVDD2/LAVDD
VDD Stable
100 µs
PLL
Relock
Time 2
0
Voltage
Regulator
Delay
HRST_CPU and
HRST_CTRL
Asserted 255
External Memory
Clock Cycles 2
Power Supply Ramp Up
Time
Reset
Configuration Pins
9 External Memory
Clock Cycles Setup Time 3
HRST_CPU and
HRST_CTRL
Maximum Rise Time Must be Less Than
One External Memory Clock Cycle 4
VM = 1.4 V
Notes:
1. Numbers associated with waveform separations correspond to caution numbers listed in Table 2.
2. Refer to Table 7 for additional information on PLL relock and reset signal assertion timing requirements.
3. Refer to Table 8 for additional information on reset configuration pin setup timing requirements.
4. For the device to be in the non-reset state, HRST_CPU/HRST_CTRL must transition from a logic 0 to a
Figure 2. Supply Voltage Sequencing and Separation Cautions
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Electrical and Thermal Characteristics
Figure 3 shows the undershoot and overshoot voltage of the memory interface of the MPC8240.
VIH
VIL
4V
GVDD + 5%
GVDD
GND
GND – 0.3 V
GND – 1.0 V
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Not to Exceed 10%
of tSDRAM_CLK
Figure 3. Overshoot/Undershoot Voltage
Figure 4 and Figure 5 show the undershoot and overshoot voltage of the PCI interface of the MPC8240 for
the 3.3-volt and 5-volt signals, respectively.
11 ns
(min)
+7.1 V
7.1 v. p-to-p
(minimum)
Overvoltage
Waveform
0V
4 ns
(max)
62.5 ns
+3.6 V
7.1 v. p-to-p
(minimum)
Undervoltage
Waveform
-3.5 V
Figure 4. Maximum AC Waveforms for 3.3-V Signaling
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Electrical and Thermal Characteristics
11 ns
(min)
+11 V
11 v. p-to-p
(minimum)
Overvoltage
Waveform
0V
4 ns
(max)
62.5 ns
+5.25 V
10.75 v. p-to-p
(minimum)
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Undervoltage
Waveform
-5.5 V
Figure 5. Maximum AC Waveforms for 5-V Signaling
1.4.1.3
DC Electrical Specifications
Table 3 provides the DC electrical characteristics for the MPC8240.
Table 3. DC Electrical Specifications
At recommended operating conditions (see Table 2)
Condition 3
Characteristic
Symbol
Min
Max
Unit
Input high voltage 5
PCI only
VIH
0.65 × OVDD
LVDD
V
Input low voltage
PCI only
VIL
—
0.3 × OVDD
V
Input high voltage
All other pins (GVDD = 3.3 V)
VIH
2.0
3.3
V
Input low voltage
All inputs except
PCI_SYNC_IN
VIL
GND
0.8
V
PCI_SYNC_IN input high voltage
CVIH
2.4
—
V
PCI_SYNC_IN input low voltage
CVIL
—
0.4
V
IL
—
±70
µA
IL
—
±10
µA
Input leakage current 4 for pins using
DRV_PCI driver
0.5 V ≤ Vin ≤ 2.7 V
@ LVDD = 4.75 V
Input leakage current 4 for all others LVDD = 3.6 V
GVDD ≤ 3.465 V
Output high voltage
IOH = driver-dependent 2
(GVDD = 3.3 V)
VOH
2.4
—
V
Output low voltage
IOL = driver-dependent 2
(GVDD = 3.3 V)
VOL
—
0.4
V
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Electrical and Thermal Characteristics
Table 3. DC Electrical Specifications (continued)
At recommended operating conditions (see Table 2)
Condition 3
Characteristic
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Capacitance
Vin = 0 V, f = 1 MHz
Symbol
Min
Max
Unit
Cin
—
7.0
pF
Notes:
1. See Table 17 for pins with internal pull-up resistors.
2. See Table 4 for the typical drive capability of a specific signal pin based on the type of output driver associated with
that pin as listed in Table 17.
3. These specifications are for the default driver strengths indicated in Table 4.
4. Leakage current is measured on input pins and on output pins in the high impedance state. The leakage current is
measured for nominal OVDD/LVDD, and VDD or both OVDD/LVDD and VDD must vary in the same direction.
5. The minimum input high voltage is not compliant with the PCI Local Bus Specification (Rev 2.1), which specifies
0.5 × OVDD for minimum input high voltage.
1.4.1.4
Output Driver Characteristics
Table 4 provides information on the characteristics of the output drivers referenced in Table 17. The values
are from the MPC8240 IBIS model (v1.1 IBIS, v1.2 file) and are untested. For additional detailed
information, see the complete IBIS model listing at: http://www.mot.com/SPS/PowerPC/teksupport/tools/
IBIS/kahlua_1.ibs.txt
Table 4. Drive Capability of MPC8240 Output Pins
Driver Type
Programmable
Output
Impedance (Ω)
Supply
Voltage
IOH
IOL
Unit
Notes
DRV_STD
20
OVDD = 3.3 V
36.7
30.0
mA
2, 4
40 (default)
OVDD = 3.3 V
18.7
15.0
mA
2, 4
25
OVDD = 3.3 V
11.0
20.6
mA
1, 3
50 (default)
OVDD = 3.3 V
5.6
10.3
mA
1, 3
8 (default)
GVDD = 3.3 V
89.0
76.3
mA
2, 4
13.3
GVDD = 3.3 V
55.9
46.4
mA
2, 4
20
GVDD = 3.3 V
36.7
30.0
mA
2, 4
40
GVDD = 3.3 V
18.7
15.0
mA
2, 4
20 (default)
GVDD = 3.3 V
36.7
30.0
mA
2, 4
40
GVDD = 3.3 V
18.7
15.0
mA
2, 4
DRV_PCI
DRV_MEM_ADDR
DRV_PCI_CLK
DRV_MEM_DATA
Notes:
1. For DRV_PCI, IOH read from the IBIS listing in the pull-up mode, I(Min) column, at the 0.33-V label by interpolating
between the 0.3- and 0.4-V table entries’ current values that correspond to the PCI VOH = 2.97 = 0.9 × OVDD (OVDD
= 3.3 V) where table entry voltage = OVDD – PCI VOH.
2. For all others with GVDD or OVDD = 3.3 V, IOH read from the IBIS listing in the pull-up mode, I(Min) column, at the
0.9-V table entry thatcorresponds to the VOH = 2.4 V where table entry voltage = GVDD/OVDD – VOH.
3. For DRV_PCI, IOL read from the IBIS listing in the pull-down mode, I(Min) column, at 0.33 V = PCI VOL = 0.1 × OVDD
(OVDD = 3.3 V) by interpolating between the 0.3- and 0.4-V table entries.
10
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Electrical and Thermal Characteristics
1.4.1.5
Power Characteristics
Table 5 provides power consumption data for the MPC8240.
Table 5. Preliminary Power Consumption
PCI Bus Clock/Memory Bus Clock
CPU Clock Frequency (MHz)
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Mode
Unit
Notes
33/66/166
33/66/200
33/100/200
66/100/200
Typical
2.5
2.8
3.0
3.0
W
1, 5
Maximum—FP
2.9
3.3
3.5
3.5
W
1, 2
Maximum—INT
2.6
2.9
3.2
3.3
W
1, 3
Doze
1.8
1.9
2.1
2.1
W
1, 4, 6
Nap
667
667
858
858
mW
1, 4, 6
Sleep
477
477
477
762
mW
1, 4, 6
I/O Power Supplies
Mode
Min
Max
Unit
Notes
Typical—OVDD
200
600
mW
7, 8
Typical—GVDD
300
900
mW
7, 9
Notes:
1. The values include VDD, AVDD, AVDD2, and LAVDD but do not include I/O supply power; see Section 1.7.2, “Power
Supply Sizing,” for information on OVDD and GVDD supply power. One DIMM is used for memory loading.
2. Maximum—FP power is measured at VDD = 2.5 V with dynamic power management enabled while running an
entirely cache-resident, looping, floating-point multiplication instruction.
3. Maximum—INT power is measured at VDD = 2.5 V with dynamic power management enabled while running entirely
cache-resident, looping, integer instructions.
4. Power saving mode maximums are measured at VDD = 2.5 V while the device is in doze, nap, or sleep mode.
5. Typical power is measured at VDD = AVDD = 2.5 V, OVDD = 3.3 V where a nominal FP value, a nominal INT value,
and a value where there is a continuous flush of cache lines with alternating ones and zeros on 64-bit boundaries
to local memory are averaged.
6. Power saving mode data measured with only two PCI_CLKs and two SDRAM_CLKs enabled.
7. The typical minimum I/O power values were results of the MPC8240 performing cache resident integer operations
at the slowest frequency combination of 33:66:166 (PCI:Mem:CPU) MHz.
8. The typical maximum OVDD value resulted from the MPC8240 operating at the fastest frequency combination of
66:100:250 (PCI:Mem:CPU) MHz and performing continuous flushes of cache lines with alternating ones and
zeros to PCI memory.
9. The typical maximum GVDD value resulted from the MPC8240 operating at the fastest frequency combination of
66:100:250 (PCI:Mem:CPU) MHz and performing continuous flushes of cache lines with alternating ones and
zeros on 64-bit boundaries to local memory.
10.Power consumption on the PLL supply pins (AVDD and AVDD2) and the DLL supply pin (LAVDD) less than15 mW.
This parameter is guaranteed by design and is not tested.
1.4.2
AC Electrical Characteristics
This section provides the AC electrical characteristics for the MPC8240. After fabrication, functional parts
are sorted by maximum processor core frequency as shown in Table 6 and tested for conformance to the AC
specifications for that frequency. The processor core frequency is determined by the bus (PCI_SYNC_IN)
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Electrical and Thermal Characteristics
clock frequency and the settings of the PLL_CFG[0:4] signals. Parts are sold by maximum processor core
frequency; see Section 1.9, “Ordering Information,” for information on ordering parts.
1.4.2.1
AC Operating Frequency Data
Table 6 provides the operating frequency information for the MPC8240.
Table 6. Operating Frequency
At recommended operating conditions (see Table 2) with GVDD = 3.3 V ± 5% and LVDD = 3.3 V ± 5%
250 MHz 2
200 MHz
Characteristic
1
Unit
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Processor frequency (CPU)
Min
Max
Min
Max
100
200
100
250
MHz
Memory bus frequency
33–100
MHz
PCI input frequency
25–66
MHz
Note:
1. Caution: The PCI_SYNC_IN frequency and PLL_CFG[0:4] settings must be chosen such that the resulting
peripheral logic/memory bus frequency and CPU (core) frequency do not exceed their respective maximum or
minimum operating frequencies. Refer to the PLL_CFG[0:4] signal description in Section 1.6, “PLL Configurations,”
for valid PLL_CFG[0:4] settings and PCI_SYNC_IN frequencies.
2.) The 250-MHz processor is only available as an R spec part. See Section 1.9.2, “Part Numbers Not Fully Addressed
by This Document,” for more information.
1.4.2.2
Clock AC Specifications
Table 7 provides the clock AC timing specifications as defined in Section 1.4.2.3, “Input AC Timing
Specifications.”
Table 7. Clock AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Characteristic and Condition 1
Min
Max
Unit
Notes
1a
Frequency of operation (PCI_SYNC_IN)
25
66
MHz
1b
PCI_SYNC_IN cycle time
40
15
ns
2, 3
PCI_SYNC_IN rise and fall times
—
2.0
ns
4
PCI_SYNC_IN duty cycle measured at 1.4 V
40
60
%
5a
PCI_SYNC_IN pulse width high measured at 1.4 V
6
9
ns
3
5b
PCI_SYNC_IN pulse width low measured at 1.4 V
6
9
ns
3
7
PCI_SYNC_IN jitter
—
150
ps
8a
PCI_CLK[0:4] skew (pin-to-pin)
—
500
ps
8b
SDRAM_CLK[0:3] skew (pin-to-pin)
—
350
ps
8
10
Internal PLL relock time
—
100
µs
3, 4, 6
15
DLL lock range with DLL_STANDARD = 1
ns
7
12
0 ≤ (NTclk – tloop – tfix0) ≤ 7
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Table 7. Clock AC Timing Specifications (continued)
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Freescale Semiconductor, Inc...
Num
Characteristic and Condition 1
Min
Max
0 ≤ (NTclk – Tclk/2 – tloop – tfix0)
≤7
Unit
Notes
ns
7
16
DLL lock range with DLL_STANDARD = 0 (default)
17
Frequency of operation (OSC_IN)
25
66
MHz
18
OSC_IN cycle time
40
15
ns
19
OSC_IN rise and fall times
—
5
ns
20
OSC_IN duty cycle measured at 1.4 V
40
60
%
21
OSC_IN frequency stability
—
100
ppm
22
OSC_IN VIH (loaded)
2.0
23
OSC_IN VIL (loaded)
5
V
0.8
V
Notes:
1. These specifications are for the default driver strengths indicated in Table 4.
2. Rise and fall times for the PCI_SYNC_IN input are measured from 0.4 to 2.4 V.
3. Specification value at maximum frequency of operation.
4. Relock time is guaranteed by design and characterization. Relock time is not tested.
5. Rise and fall times for the OSC_IN input are guaranteed by design and characterization. OSC_IN input rise and fall
times are not tested.
6. Relock timing is guaranteed by design. PLL-relock time is the maximum amount of time required for PLL lock after
a stable VDD and PCI_SYNC_IN are reached during the reset sequence. This specification also applies when the
PLL has been disabled and subsequently re-enabled during sleep mode. Also note that HRST_CPU/HRST_CTRL
must be held asserted for a minimum of 255 bus clocks after the PLL-relock time during the reset sequence.
7. DLL_STANDARD is bit 7 of the PMC2 register <72>. N is a non-zero integer (1 or 2). Tclk is the period of one
SDRAM_SYNC_OUT clock cycle in ns. tloop is the propagation delay of the DLL synchronization feedback loop (PC
board runner) from SDRAM_SYNC_OUT to SDRAM_SYNC_IN in ns; 6.25 inches of loop length (unloaded PC
board runner) corresponds to approximately 1 ns of delay. tfix0 is a fixed delay inherent in the design when the DLL
is at tap point 0 and the DLL is contributing no delay; tfix0 equals approximately 3 ns. See Figure 7 for DLL3 locking
ranges.
8. Pin-to-pin skew includes quantifying the additional amount of clock skew (or jitter) from the DLL besides any
intentional skew added to the clocking signals from the variable length DLL synchronization feedback loop, that is,
the amount of variance between the internal sys_logic_clk and the SDRAM_SYNC_IN signal after the DLL is
locked. While pin to pin skew between SDRAM_CLKs can be measured, the relationship between the internal
sys_logic_clk and the external SDRAM_SYNC_IN cannot be measured and is guaranteed by design.
Figure 6 shows the PCI_SYNC_IN input clock timing diagram, and Figure 7 shows the DLL locking range
loop delay versus frequency of operation.
1
5a
5b
2
3
CVIH
PCI_SYNC_IN
VM
VM
VM
CVIL
VM = Midpoint Voltage (1.4 V)
Figure 6. PCI_SYNC_IN Input Clock Timing Diagram
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DLL will lock
Tclk SDRAM_SYNC_OUT Period and Frequency
Freescale Semiconductor, Inc...
DLL not guaranteed to lock
25 MHz
40 ns
N=1
DLL_STANDARD = 0
33 MHz
30 ns
N=1
DLL_STANDARD = 1
50 MHz
20 ns
N=2
DLL_STANDARD = 0
N=2
DLL_STANDARD = 1
100 MHz
10 ns
0
5
10
Tloop Propagation Delay Time (ns)
15
Figure 7. DLL Locking Range Loop Delay vs. Frequency of Operation
1.4.2.3
Input AC Timing Specifications
Table 8 provides the input AC timing specifications. See Figure 8 and Figure 9 for the input-output timing
diagrams referenced to SDRAM_SYNC_IN and PCI_SYNC_IN, respectively.
Table 8. Input AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Min
Max
Unit
Notes
2.0
—
ns
2, 3
10b1 Memory control and data input signals in flow through mode valid to
SDRAM_SYNC_IN (input setup)
3.0
—
ns
1, 3
10b2 Memory control and data input signals in registered/in-line mode valid
to SDRAM_SYNC_IN (input setup)
2.5
—
ns
1, 3
10b3 Memory control and data signals accessing non-DRAM valid to
SDRAM_SYNC_IN (input setup)
3.0
—
ns
1, 3
10a
Characteristic
PCI input signals valid to PCI_SYNC_IN (input setup)
10c
PIC, miscellaneous debug input signals valid to SDRAM_SYNC_IN
(input setup)
3.0
—
ns
1, 3
10d
I2C input signals valid to SDRAM_SYNC_IN (input setup)
2.0
—
ns
1, 3
10e
Mode select inputs valid to HRST_CPU/HRST_CTRL (input setup)
9 × tCLK
—
ns
1, 3–5
14
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Table 8. Input AC Timing Specifications (continued)
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Freescale Semiconductor, Inc...
Num
Characteristic
11a
PCI_SYNC_IN (SDRAM_SYNC_IN) to inputs invalid (input hold)
11b
HRST_CPU/HRST_CTRL to mode select inputs invalid (input hold)
Min
Max
Unit
Notes
1.0
—
ns
1, 2, 3
0
—
ns
1, 3, 5
Notes:
1. All memory and related interface input signal specifications are measured from the TTL level (0.8 or 2.0 V) of the
signal in question to the VM = 1.4 V of the rising edge of the memory bus clock, SDRAM_SYNC_IN.
SDRAM_SYNC_IN is the same as PCI_SYNC_IN in 1:1 mode, but is twice the frequency in 2:1 mode
(processor/memory bus clock rising edges occur on every rising and falling edge of PCI_SYNC_IN). See Figure 8.
2. All PCI signals are measured from OVDD/2 of the rising edge of PCI_SYNC_IN to 0.4 × OVDD of the signal in
question for 3.3-V PCI signaling levels. See Figure 9.
3. Input timings are measured at the pin.
4. tCLK is the time of one SDRAM_SYNC_IN clock cycle.
5. All mode select input signals specifications are measured from the TTL level (0.8 or 2.0 V) of the signal in question
to the VM = 1.4 V of the rising edge of the HRST_CPU/HRST_CTRL signal. See Figure 10.
PCI_SYNC_IN
VM
SDRAM_SYNC_IN
Shown in 2:1 Mode
VM
VM
VM
10b-d
11a
13b
12b-d
2.0 V
2.0 V
0.8 V
0.8 V
14b
MEMORY
Inputs/Outputs
Input Timing
VM = Midpoint Voltage (1.4 V)
Output Timing
Figure 8. Input-Output Timing Diagram Referenced to SDRAM_SYNC_IN
OVDD ÷ 2
PCI_SYNC_IN
OVDD ÷ 2
OVDD ÷ 2
10a
13a
12a
11a
PCI
Inputs/Outputs
0.4 × OVDD
Input Timing
14a
0.615 × OVDD
0.285 × OVDD
Output Timing
Figure 9. Input-Output Timing Diagram Referenced to PCI_SYNC_IN
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Figure 10 shows the input timing diagram for mode select signals.
VM
HRST_CPU/HRST_CTRL
10e
11b
2.0 V
0.8 V
Mode Pins
VM = Midpoint Voltage (1.4 V)
Freescale Semiconductor, Inc...
Figure 10. Input Timing Diagram for Mode Select Signals
1.4.2.4
Output AC Timing Specification
Table 9 provides the processor bus AC timing specifications for the MPC8240. See Figure 8 and Figure 9
for the input-output timing diagrams referenced to SDRAM_SYNC_IN and PCI_SYNC_IN, respectively.
Figure 11 shows the AC test load for the MPC8240.
Table 9. Output AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Characteristic 3, 6
Num
Min
Max
Unit
Notes
PCI_SYNC_IN to output valid, 66 MHz PCI, with MCP in the default
logic 1 state and CKE pulled down to logic 0 state (see Figure 10)
—
6.0
ns
2, 4
PCI_SYNC_IN to output valid, 33 MHz PCI, with MCP and CKE in the
default logic 1 state (see Figure 10)
—
8.0
ns
2, 4
12b1 SDRAM_SYNC_IN to output valid (for memory control address and
data signals accessing DRAM in flow-through mode)
—
7.0
ns
1
12b2 SDRAM_SYNC_IN to output valid (for memory control address and
data signals accessing DRAM in registered mode)
—
6.0
ns
1
12b3 SDRAM_SYNC_IN to output valid (for memory control address and
data signals accessing non-DRAM)
—
7.0
ns
1
—
7.0
ns
1
12a
12c
SDRAM_SYNC_IN to output valid (for all others)
2
12d
SDRAM_SYNC_IN to output valid (for I C)
—
5.0
ns
1
13a
Output hold, 66 MHz PCI, with MCP in the default logic 1 state and
CKE pulled down to logic 0 state (see Figure 10)
1.0
—
ns
2, 4, 5
Output hold, 33 MHz PCI, with MCP and CKE in the default logic 1
state (see Figure 10)
2.0
—
ns
2, 4, 5
13b
Output hold (all others)
0
—
ns
1
14a
PCI_SYNC_IN to output high impedance (for PCI)
—
14.0
ns
2, 4
16
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Table 9. Output AC Timing Specifications (continued)
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Characteristic 3, 6
Num
Freescale Semiconductor, Inc...
14b
SDRAM_SYNC_IN to output high impedance (for all others)
Min
Max
Unit
Notes
—
4.0
ns
1
Notes:
1. All memory and related interface output signal specifications are specified from the VM = 1.4 V of the rising edge of
the memory bus clock, SDRAM_SYNC_IN to the TTL level (0.8 or 2.0 V) of the signal in question.
SDRAM_SYNC_IN is the same as PCI_SYNC_IN in 1:1 mode, but is twice the frequency in 2:1 mode
(processor/memory bus clock rising edges occur on every rising and falling edge of PCI_SYNC_IN). See Figure 8.
2. All PCI signals are measured from OVDD/2 of the rising edge of PCI_SYNC_IN to 0.285 × OVDD or 0.615 × OVDD
of the signal in question for 3.3-V PCI signaling levels. See Figure 9.
3. All output timings assume a purely resistive 50-Ω load (see Figure 11). Output timings are measured at the pin;
time-of-flight delays must be added for trace lengths, vias, and connectors in the system.
4. PCI bused signals are composed of the following signals: LOCK, IRDY, C/BE[0:3], PAR, TRDY, FRAME, STOP,
DEVSEL, PERR, SERR, AD[0:31], REQ[4:0], GNT[4:0], IDSEL, and INTA.
5. PCI hold times can be varied; see Section 1.4.2.4.1, “PCI Signal Output Hold Timing,” for information on
programmable PCI output hold times. The values shown for item 13a are for PCI compliance.
6. These specifications are for the default driver strengths indicated in Table 4.
Output Measurements are Made at the Device Pin
Output
Pin
Z0 = 50 Ω
RL = 50 Ω
OVDD/2 for PCI
GVDD/2 for Memory
Figure 11. AC Test Load for the MPC8240
1.4.2.4.1
PCI Signal Output Hold Timing
In order to meet minimum output hold specifications relative to PCI_SYNC_IN for both 33- and 66-MHz
PCI systems, the MPC8240 has a programmable output hold delay for PCI signals. The initial value of the
output hold delay is determined by the values on the MCP and CKE reset configuration signals. Further
output hold delay values are available through programming the PCI_HOLD_DEL value of the PMCR2
configuration register.
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Table 10 describes the bit values for the PCI_HOLD_DEL values in PMCR2.
Table 10. Power Management Configuration Register 2 at 0x72
Bit
Name
6–4 PCI_HOLD_DEL
Reset
Value
xx0
Description
PCI output hold delay values relative to PCI_SYNC_IN. The initial values of bits 6
and 5 are determined by the reset configuration pins MCP and CKE, respectively.
As these two pins have internal pull-up resistors, the default value after reset is
0b110.
Although the minimum hold times are guaranteed at shown values, changes in the
actual hold time can be made by incrementing or decrementing the value in these
bit fields of this register through software or hardware configuration. The increment
is in approximately 400-picosecond steps. Lowering the value in the 3-bit field
decreases the amount of output hold available.
Freescale Semiconductor, Inc...
000 For Silicon Rev. 1.0/1.1: 66-MHz PCI. Pull-down CKE configuration pin with a
2-kΩ or less value resistor. This setting guarantees the minimum output hold
(item 13a) and the maximum output valid (item 12a) times as specified in
Figure 9 are met for a 66-MHz PCI system. See Figure 12.
001 Reserved
010 Reserved
011 Reserved
100 For Silicon Rev. 1.2/1.3: 66-MHz PCI. Pull-down CKE configuration pin with a
2-kΩ or less value resistor. This setting guarantees the minimum output hold
(item 13a) and the maximum output valid (item 12a) times as specified in
Figure 9 are met for a 66-MHz PCI system. See Figure 12.
For Silicon Rev. 1.0/1.1: 33-MHz PCI. This setting guarantees the minimum
output hold (item 13a) and the maximum output valid (item 12a) times as
specified in Figure 9 are met for a 33-MHz PCI system. See Figure 12.
101 Reserved
110 For Silicon Rev. 1.2/1.3: 33-MHz PCI. This setting guarantees the minimum
output hold (item 13a) and the maximum output valid (item 12a) times as
specified in Figure 9 are met for a 33-MHz PCI system. See Figure 12.
(Default if reset configuration pins left unconnected.)
111
18
For Silicon Rev. 1.0/1.1: Default if reset configuration pins left unconnected.
Reserved
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Figure 12 shows the PCI_HOLD_DEL effect on output valid and hold time.
OVDD ÷ 2
PCI_SYNC_IN
12a, 8 ns for 33 MHz PCI
PCI_HOLD_DEL = 110
OVDD ÷ 2
13a, 2 ns for 33-MHz PCI
PCI_HOLD_DEL = 110
Freescale Semiconductor, Inc...
PCI Inputs/Outputs
33 MHz PCI
12a, 6 ns for 66 MHz PCI
PCI_HOLD_DEL = 100
13a, 1 ns for 66-MHz PCI
PCI_HOLD_DEL = 100
PCI Inputs/Outputs
66 MHz PCI
As PCI_HOLD_DEL
Values Decrease
PCI Inputs
and Outputs
As PCI_HOLD_DEL
Values Increase
Note: Diagram not to scale.
Output Valid
Output Hold
Figure 12. PCI_HOLD_DEL Effect on Output Valid and Hold Time
1.4.2.5
I2C AC Timing Specifications
Table 11 provides the I2C input AC timing specifications for the MPC8240.
Table 11. I2C Input AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
1
Characteristic
Start condition hold time
Min
Max
Unit
Notes
4.0
—
CLKs
1,2
FDR[4:2]
1, 2, 4, 5
—
2
) × (5 –
Clock low period (the time before the MPC8240 8.0 + (16 × 2
will drive SCL low as a transmitting slave after 4({FDR[5],FDR[1]} == b'10) –
3({FDR[5],FDR[1]} == b'11)–
detecting SCL low as driven by an external
2({FDR[5],FDR[1]} == b'00) –
master)
1({FDR[5],FDR[1]} == b'01))
—
CLKs
3
SCL/SDA rise time (from 0.5 to 2.4 V)
1
ms
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Table 11. I2C Input AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Freescale Semiconductor, Inc...
Num
Characteristic
Min
Max
Unit
Notes
2
4
Data hold time
0
—
ns
5
SCL/SDA fall time (from 2.4 to 0.5 V)
—
1
ms
6
Clock high period (time needed to either receive
a data bit or generate a START or STOP)
5.0
—
CLKs
1, 2, 5
7
Data setup time
3.0
—
ns
3
8
Start condition setup time (for repeated start
condition only)
4.0
—
CLKs
1, 2
9
Stop condition setup time
4.0
—
CLKs
1, 2
Notes:
1. Units for these specifications are in SDRAM_CLK units.
2. The actual values depend on the setting of the digital filter frequency sampling rate (DFFSR) bits in the frequency
divider register I2CFDR. Therefore, the noted timings in this table are all relative to qualified signals. The qualified
SCL and SDA are delayed signals from what is seen in real time on the I2C bus. The qualified SCL and SDA signals
are delayed by the SDRAM_CLK clock times DFFSR times two plus one SDRAM_CLK clock. The resulting delay
value is added to the value in the table (where this note is referenced). See Figure 13.
3. Timing is relative to the sampling clock (not SCL).
4. FDR[x] refers to the frequency divider register I2CFDR bit n.
5. Input clock low and high periods in combination with the FDR value in the frequency divider register (I2CFDR)
determine the maximum I2C input frequency. See Table 12.
Table 12 provides the I2C frequency divider register (I2CFDR) information for the MPC8240.
Table 12. MPC8240 Maximum I2C Input Frequency
Maximum I2C Input Frequency 1
FDR Hex 2
Divider 3 (Dec)
20, 21
160, 192
22, 23, 24, 25
SDRAM_CLK SDRAM_CLK SDRAM_CLK
@ 33 MHz
@ 50 MHz
@ 100 MHz
1.13 MHz
1.72 MHz
3.44 MHz
224, 256, 320, 384
733
1.11 MHz
2.22 MHz
0, 1
288, 320
540
819
1.63 MHz
2, 3, 26, 27, 28, 29
384, 448, 480, 512, 640, 768
428
649
1.29 MHz
4, 5
576, 640
302
458
917
6, 7, 2A, 2B, 2C, 2D
768, 896, 960, 1024, 1280, 1536
234
354
709
8, 9
1152, 1280
160
243
487
A, B, 2E, 2F, 30, 31
1536, 1792, 1920, 2048, 2560, 3072
122
185
371
C, D
2304, 2560
83
125
251
E, F, 32, 33, 34, 35
3072, 3584, 3840, 4096, 5120, 6144
62
95
190
10, 11
4608, 5120
42
64
128
31
48
96
12, 13, 36, 37, 38, 39 6144, 7168, 7680, 8192, 10240, 12288
20
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Table 12. MPC8240 Maximum I2C Input Frequency (continued)
Maximum I2C Input Frequency 1
FDR Hex 2
Divider 3 (Dec)
Freescale Semiconductor, Inc...
14, 15
SDRAM_CLK SDRAM_CLK SDRAM_CLK
@ 33 MHz
@ 50 MHz
@ 100 MHz
9216, 10240
21
32
64
16, 17, 3A, 3B, 3C, 3D 12288, 14336, 15360, 16384, 20480, 24576
16
24
48
18, 19
18432, 20480
10
16
32
1A, 1B, 3E, 3F
24576, 28672, 30720, 32768
8
12
24
1C, 1D
36864, 40960
5
8
16
1E, 1F
49152, 61440
4
6
12
Notes:
1. Values are in KHz, unless otherwise specified.
2. FDR Hex and Divider (Dec) values are listed in corresponding order.
3. Multiple Divider (Dec) values will generate the same input frequency, but each Divider (Dec) value will generate a
unique output frequency as shown in Table 13.
Table 13 provides the I2C output AC timing specifications for the MPC8240.
Table 13. I2C Output AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Characteristic
Min
Max
Unit
Notes
(FDR[5] == 0) × (DFDR/16)/2N + (FDR[5]
== 1) × (DFDR/16)/2M
—
CLKs
1, 2, 5
DFDR/2
—
CLKs
1, 2, 5
—
—
ms
3
8.0 + (16 × 2FDR[4:2]) × (5 –
4({FDR[5],FDR[1]} == b'10) –
3({FDR[5],FDR[1]} == b'11) –
2({FDR[5],FDR[1]} == b'00) –
1({FDR[5],FDR[1]} == b'01))
—
CLKs
1, 2, 5
—
<5
ns
4
DFDR/2
—
CLKs
1, 2, 5
(DFDR/2) – (Output data hold time)
—
CLKs
1, 5
—
CLKs
1, 2, 5
1
Start condition hold time
2
Clock low period
3
SCL/SDA rise time (from 0.5 to 2.4 V)
4
Data hold time
5
SCL/SDA fall time (from 2.4 to 0.5 V)
6
Clock high time
7
Data setup time (MPC8240 as a
master only)
8
Start condition setup time (for repeated DFDR + (Output start condition hold time)
start condition only)
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Table 13. I2C Output AC Timing Specifications (continued)
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Freescale Semiconductor, Inc...
9
Characteristic
Stop condition setup time
Min
Max
Unit
Notes
4.0
—
CLKs
1, 2
Notes:
1. Units for these specifications are in SDRAM_CLK units.
2. The actual values depend on the setting of the digital filter frequency sampling rate (DFFSR) bits in the frequency
divider register I2CFDR. Therefore, the noted timings in this table are all relative to qualified signals. The qualified
SCL and SDA are delayed signals from what is seen in real time on the I2C bus. The qualified SCL and SDA signals
are delayed by the SDRAM_CLK clock times DFFSR times two plus one SDRAM_CLK clock. The resulting delay
value is added to the value in the table (where this note is referenced). See Figure 14.
3. Since SCL and SDA are open-drain type outputs, which the MPC8240 can only drive low, the time required for SCL
or SDA to reach a high level depends on external signal capacitance and pull-up resistor values.
4. Specified at a nominal 50-pF load.
5. DFDR is the decimal divider number indexed by the value of FDR[5:0]. Refer to the I2C Interface chapter’s serial bit
clock frequency divider selections table. FDR[n] refers to the frequency divider register I2CFDR bit n. N is equal to
a variable number that would make the result of the divide (data hold time value) equal to a number less than 16.
M is equal to a variable number that would make the result of the divide (data hold time value) equal to a number
less than 9.
Figure 13 through Figure 16 show I2C timings.
2
SCL
VM
VM
6
1
4
SDA
Figure 13. I2C Timing Diagram I
3
5
SCL
VH
VM
VL
8
9
SDA
Figure 14. I2C Timing Diagram II
22
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Electrical and Thermal Characteristics
DFFSR FILTER CLK 1
7
SDA
Input Data Valid
Note:
1. DFFSR filter clock is the SDRAM_CLK clock times DFFSR value.
Figure 15. I2C Timing Diagram III
Freescale Semiconductor, Inc...
SCL/SDArealtime
VM
Delay 1
SCL/SDAqualified
VM
Note:
1. The delay is the local memory clock times DFFSR times 2 plus 1 local memory clock.
Figure 16. I2C Timing Diagram IV (Qualified Signal)
1.4.2.6
PIC Serial Interrupt Mode AC Timing Specifications
Table 14 provides the PIC serial interrupt mode AC timing specifications for the MPC8240.
Table 14. PIC Serial Interrupt Mode AC Timing Specifications
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Characteristic
Min
Max
Unit
Notes
1
1
S_CLK frequency
1/14 SDRAM_SYNC_IN
1/2 SDRAM_SYNC_IN
MHz
2
S_CLK duty cycle
40
60
%
3
S_CLK output valid time
—
6
ns
4
Output hold time
0
—
ns
5
S_FRAME, S_RST output valid
time
—
1 sys_logic_clk period + 6
ns
2
6
S_INT input setup time to S_CLK
1 sys_logic_clk period + 2
—
ns
2
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Electrical and Thermal Characteristics
Table 14. PIC Serial Interrupt Mode AC Timing Specifications (continued)
Freescale Semiconductor, Inc...
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Num
Characteristic
Min
Max
Unit
Notes
7
S_INT inputs invalid (hold time) to
S_CLK
—
0
ns
2
Notes:
1. See the MPC8240 Integrated Processor User’s Manual for a description of the PIC interrupt control register (ICR)
describing S_CLK frequency programming.
2. S_RST, S_FRAME, and S_INT are shown in Figure 17. Figure 18 depicts timing relationships to sys_logic_clk and
S_CLK and does not describe functional relationships between S_RST, S_FRAME, and S_INT. See the MPC8240
Integrated Processor User’s Manual for a complete description of the functional relationships between these
signals.
3. The sys_logic_clk waveform is the clocking signal of the internal peripheral logic from the output of the peripheral
logic PLL; sys_logic_clk is the same as SDRAM_SYNC_IN when the SDRAM_SYNC_OUT to SDRAM_SYNC_IN
feedback loop is implemented and the DLL is locked. See the MPC8240 Integrated Processor User’s Manual for a
complete clocking description.
sys_logic_clk
VM
VM
VM
3
S_CLK
4
VM
VM
5
4
S_FRAME
VM
VM
S_RST
Figure 17. PIC Serial Interrupt Mode Output Timing Diagram
VM
S_CLK
7
6
S_INT
Figure 18. PIC Serial Interrupt Mode Input Timing Diagram
24
MPC8240 Integrated Processor Hardware Specifications
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Electrical and Thermal Characteristics
1.4.2.7
IEEE 1149.1 (JTAG) AC Timing Specifications
Table 15 provides the JTAG AC timing specifications for the MPC8240 while in the JTAG operating mode.
Table 15. JTAG AC Timing Specification (Independent of PCI_SYNC_IN)
At recommended operating conditions (see Table 2) with LVDD = 3.3 V ± 0.3 V
Characteristic 4
Freescale Semiconductor, Inc...
Num
Min
Max
Unit
Notes
TCK frequency of operation
0
25
MHz
1
TCK cycle time
40
—
ns
2
TCK clock pulse width measured at 1.5 V
20
—
ns
3
TCK rise and fall times
0
3
ns
4
TRST setup time to TCK falling edge
10
—
ns
5
TRST assert time
10
—
ns
6
Input data setup time
5
—
ns
2
7
Input data hold time
15
—
ns
2
8
TCK to output data valid
0
30
ns
3
9
TCK to output high impedance
0
30
ns
3
10
TMS, TDI data setup time
5
—
ns
11
TMS, TDI data hold time
15
—
ns
12
TCK to TDO data valid
0
15
ns
13
TCK to TDO high impedance
0
15
ns
1
Notes:
1. TRST is an asynchronous signal. The setup time is for test purposes only.
2. Non-test (other than TDI and TMS) signal input timing with respect to TCK.
3. Non-test (other than TDO) signal output timing with respect to TCK.
4. Timings are independent of the system clock (PCI_SYNC_IN).
Figure 19 shows the JTAG clock input timing diagram.
1
2
VM
TCK
3
2
VM
VM
3
VM = Midpoint Voltage
Figure 19. JTAG Clock Input Timing Diagram
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Freescale Semiconductor, Inc.
Electrical and Thermal Characteristics
Figure 20 shows the JTAG TRST timing diagram.
TCK
4
TRST
5
Figure 20. JTAG TRST Timing Diagram
Freescale Semiconductor, Inc...
Figure 21 shows the JTAG boundary scan timing diagram.
TCK
6
Data Inputs
7
Input Data Valid
8
Data Outputs
Output Data Valid
9
Data Outputs
Figure 21. JTAG Boundary Scan Timing Diagram
Figure 22 shows the test access port timing diagram.
.
TCK
10
TDI, TMS
11
Input Data Valid
12
TDO
Output Data Valid
13
TDO
Figure 22. Test Access Port Timing Diagram
26
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Package Description
1.4.3
Thermal Characteristics
Table 16 provides the package thermal characteristics for the MPC8240.
Table 16. Package Thermal Characteristics
Characteristic 1
Symbol
Value
Unit
Die junction-to-case thermal resistance
RθJC
1.8
°C/W
Die junction-to-board thermal resistance
RθJB
4.8
°C/W
Freescale Semiconductor, Inc...
Note:
1. Refer to Section 1.7, “System Design Information,” for details about thermal management.
1.5
Package Description
The following sections provide the package parameters and mechanical dimensions for the MPC8240, 352
TBGA package.
1.5.1
Package Parameters
The MPC8240 uses a 35 mm × 35 mm, cavity-down, 352 pin tape ball grid array (TBGA) package. The
package parameters are as provided in the following list.
Package outline
Interconnects
Pitch
Solder balls
Solder ball diameter
Maximum module height
Co-planarity specification
Maximum force
35 mm × 35 mm
352
1.27 mm
ZU (TBGA)—62 Sn/36 Pb/2 Ag
VV (Lead free version of TBGA package)—95.5 Sn/4.0 Ag/0.5 Cu
0.75 mm
1.65 mm
0.15 mm
6.0 lbs. total, uniformly distributed over package (8 grams/ball)
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Package Description
1.5.2
Mechanical Dimensions
Figure 23 provides the mechanical dimensions, top surface, side profile, and pinout for the MPC8240, 352
TBGA package.
–F–
B
CORNER
–E–
–T–
Freescale Semiconductor, Inc...
0.150 T
A
MIN
MAX
A
34.8
35.2
B
34.8
35.2
C
1.45
1.65
D
.60
.90
G
Top View
H
1.27 BASIC
.85
.95
K
31.75 BASIC
L
.50
.70
26 24 22 20 18 16 14 12 10 8 6 4 2
25 23 21 19 17 15 13 11 9 7 5 3 1
A
C
E
G
J
L
N
R
U
W
B
D
F
H
K
M
K
P
T
V
Y
AA
AB
AC
AD
AE
AF
C
H
L
Bottom View
352X ∅ D
G
K
Notes:
1. Drawing not to scale.
2. All measurements are in millimeters (mm).
Figure 23. Mechanical Dimensions and Pinout Assignments for the MPC8240, 352 TBGA
28
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Package Description
1.5.3
Pinout Listings
Table 17 provides the pinout listing for the MPC8240, 352 TBGA package.
Table 17. MPC8240 Pinout Listing
Name
Pin Number
Pin Type
Power
Supply
Output
Driver
Type
Notes
Freescale Semiconductor, Inc...
PCI Interface Signals
C/BE[3:0]
P25 K23 F23 A25
I/O
OVDD
DRV_PCI
6, 15
DEVSEL
H26
I/O
OVDD
DRV_PCI
8, 15
FRAME
J24
I/O
OVDD
DRV_PCI
8, 15
IRDY
K25
I/O
OVDD
DRV_PCI
8, 15
LOCK
J26
Input
OVDD
—
8
AD[31:0]
V25 U25 U26 U24 U23 T25 T26
R25 R26 N26 N25 N23 M26 M25
L25 L26 F24 E26 E25 E23 D26
D25 C26 A26 B26 A24 B24 D19
B23 B22 D22 C22
I/O
OVDD
DRV_PCI
6, 15
PAR
G25
I/O
OVDD
DRV_PCI
15
GNT[3:0]
W25 W24 W23 V26
Output
OVDD
DRV_PCI
6, 15
GNT4/DA5
W26
Output
OVDD
DRV_PCI
7, 15
REQ[3:0]
Y25 AA26 AA25 AB26
Input
OVDD
—
6, 12
REQ4/DA4
Y26
I/O
OVDD
—
12
PERR
G26
I/O
OVDD
DRV_PCI
8, 15, 18
SERR
F26
I/O
OVDD
DRV_PCI
8, 15, 16
STOP
H25
I/O
OVDD
DRV_PCI
8, 15
TRDY
K26
I/O
OVDD
DRV_PCI
8, 15
INTA
AC26
Output
OVDD
DRV_PCI
8, 15, 16
IDSEL
P26
Input
OVDD
—
Memory Interface Signals
MDL[0:31]
AD17 AE17 AE15 AF15 AC14
AE13 AF13 AF12 AF11 AF10
AF9 AD8 AF8 AF7 AF6 AE5 B1
A1 A3 A4 A5 A6 A7 D7 A8 B8
A10 D10 A12 B11 B12 A14
I/O
GVDD
DRV_MEM_
DATA
5, 6, 13
MDH[0:31]
AC17 AF16 AE16 AE14 AF14
AC13 AE12 AE11 AE10 AE9
AE8 AC7 AE7 AE6 AF5 AC5 E4
A2 B3 D4 B4 B5 D6 C6 B7 C9 A9
B10 A11 A13 B13 A15
I/O
GVDD
DRV_MEM_
DATA
6, 13
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Package Description
Table 17. MPC8240 Pinout Listing (continued)
Freescale Semiconductor, Inc...
Output
Driver
Type
Pin Number
Pin Type
Power
Supply
CAS/DQM[0:7]
AB1 AB2 K3 K2 AC1 AC2 K1 J1
Output
GVDD
DRV_MEM_
ADDR
6
RAS/CS[0:7]
Y4 AA3 AA4 AC4 M2 L2 M1 L1
Output
GVDD
DRV_MEM_
ADDR
6
FOE
H1
I/O
GVDD
DRV_MEM_
ADDR
3, 4
RCS0
N4
I/O
GVDD
DRV_MEM_
ADDR
3, 4
RCS1
N2
Output
GVDD
DRV_MEM_
ADDR
SDMA[11:0]
N1 R1 R2 T1 T2 U4 U2 U1 V1 V3
W1 W2
Output
GVDD
DRV_MEM_
ADDR
6, 14
SDMA12/SDBA1
P1
Output
GVDD
DRV_MEM_
ADDR
14
SDBA0
P2
Output
GVDD
DRV_MEM_
ADDR
PAR[0:7]
AF3 AE3 G4 E2 AE4 AF4 D2 C2
I/O
GVDD
DRV_MEM_
DATA
6, 13, 14
SDRAS
AD1
Output
GVDD
DRV_MEM_
ADDR
3
SDCAS
AD2
Output
GVDD
DRV_MEM_
ADDR
3
CKE
H2
Output
GVDD
DRV_MEM_
ADDR
3, 4
WE
AA1
Output
GVDD
DRV_MEM_
ADDR
AS
Y1
Output
GVDD
DRV_MEM_
ADDR
3, 4
Name
Notes
PIC Control Signals
IRQ_0/S_INT
C19
Input
OVDD
—
19
IRQ_1/S_CLK
B21
I/O
OVDD
DRV_PCI
19
IRQ_2/S_RST
AC22
I/O
OVDD
DRV_PCI
19
IRQ_3/S_FRAME
AE24
I/O
OVDD
DRV_PCI
19
IRQ_4/L_INT
A23
I/O
OVDD
DRV_PCI
19
OVDD
DRV_STD
10, 16
I2C Control Signals
SDA
30
AE20
I/O
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Package Description
Table 17. MPC8240 Pinout Listing (continued)
Name
SCL
Pin Number
AF21
Pin Type
Power
Supply
Output
Driver
Type
Notes
I/O
OVDD
DRV_STD
10, 16
6
Freescale Semiconductor, Inc...
Clock Out Signals
PCI_CLK [0:3]
AC25 AB25 AE26 AF25
Output
GVDD
DRV_PCI_C
LK
PCI_CLK4/DA3
AF26
Output
GVDD
DRV_PCI_C
LK
PCI_SYNC_OUT
AD25
Output
GVDD
DRV_PCI_C
LK
PCI_SYNC_IN
AB23
Input
GVDD
—
SDRAM_CLK [0:3]
D1 G1 G2 E1
Output
GVDD
DRV_MEM_
ADDR
SDRAM_SYNC_OUT
C1
Output
GVDD
DRV_MEM_
ADDR
SDRAM_SYNC_IN
H3
Input
GVDD
—
CKO/DA1
B15
Output
OVDD
DRV_STD
OSC_IN
AD21
Input
OVDD
—
6
19
Miscellaneous Signals
HRST_CTRL
A20
Input
OVDD
—
HRST_CPU
A19
Input
OVDD
—
MCP
A17
Output
OVDD
DRV_STD
NMI
D16
Input
OVDD
—
SMI
A18
Input
OVDD
—
10
SRESET
B16
Input
OVDD
—
10
TBEN
B14
Input
OVDD
—
10
QACK/DA0
F2
Output
OVDD
DRV_STD
3, 4
CHKSTOP_IN
D14
Input
OVDD
—
10
MAA[0:2]
AF2 AF1 AE1
Output
GVDD
DRV_MEM_
DATA
3, 4, 6
MIV
A16
Output
OVDD
DRV_STD
PMAA[0:2]
AD18 AF18 AE19
Output
OVDD
DRV_STD
3, 4, 6,15
TRIG_IN
AF20
Input
OVDD
—
10
TRIG_OUT
AC18
I/O
OVDD
DRV_STD
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31
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Package Description
Table 17. MPC8240 Pinout Listing (continued)
Name
Pin Number
Power
Supply
Output
Driver
Type
Notes
I/O
OVDD
—
4, 6
Pin Type
Freescale Semiconductor, Inc...
Test/Configuration Signals
PLL_CFG[0:4]/
DA[10:6]
A22 B19 A21 B18 B17
TEST0
AD22
Input
OVDD
—
1, 9
TEST1
B20
Input
OVDD
—
9, 10
TEST2
Y2
Input
GVDD
—
11
TCK
AF22
Input
OVDD
—
9, 12
TDI
AF23
Input
OVDD
—
9, 12
TDO
AC21
Output
OVDD
DRV_PCI
TMS
AE22
Input
OVDD
—
9, 12
TRST
AE23
Input
OVDD
—
9, 12
Ground
—
—
Power and Ground Signals
GND
AA2 AA23 AC12 AC15 AC24
AC3 AC6 AC9 AD11 AD14 AD16
AD19 AD23 AD4 AE18 AE2
AE21 AE25 B2 B25 B6 B9 C11
C13 C16 C23 C4 C8 D12 D15
D18 D21 D24 D3 F25 F4 H24
J25 J4 L24 L3 M23 M4 N24 P3
R23 R4 T24 T3 V2 V23 W3
LVDD
AC20 AC23 D20 D23 G23 P23
Y23
Reference
voltage
3.3 V, 5.0 V
LVDD
—
GVDD
AB3 AB4 AC10 AC11 AC8 AD10
Power for
AD13 AD15 AD3 AD5 AD7 C10
memory
C12 C3 C5 C7 D13 D5 D9 E3 G3 drivers 2.5 V,
H4 K4 L4 N3 P4 R3 U3 V4 Y3
3.3 V
GVDD
—
OVDD
AB24 AD20 AD24 C14 C20 C24
E24 G24 J23 K24 M24 P24 T23
Y24
PCI/Stnd
3.3 V
OVDD
—
VDD
AA24 AC16 AC19 AD12 AD6
AD9 C15 C18 C21 D11 D8 F3
H23 J3 L23 M3 R24 T4 V24 W4
Power for
core 2.5 V
VDD
—
LAVDD
D17
Power for
DLL 2.5 V
LAVDD
—
AVDD
C17
Power for
PLL (CPU
core logic)
2.5 V
AVDD
—
32
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Package Description
Table 17. MPC8240 Pinout Listing (continued)
Name
AVDD2
Pin Number
AF24
Pin Type
Power for
PLL
(peripheral
logic) 2.5 V
Power
Supply
Output
Driver
Type
AVDD2
—
Notes
Freescale Semiconductor, Inc...
Manufacturing Pins
DA2
C25
Output
OVDD
DRV_PCI
2
DA[11:13]
AD26 AF17 AF19
Output
OVDD
DRV_PCI
2, 6
DA[14:15]
F1 J2
Output
GVDD
DRV_MEM_
ADDR
2, 6
Notes:
1. Place pull-up resistors of 120 Ω or less on the TEST0 pin.
2. Treat these pins as no connects unless using debug address functionality.
3. This pin has an internal pull-up resistor that is enabled only when the MPC8240 is in the reset state. The value of
the internal pull-up resistor is not guaranteed but is sufficient to ensure that a 1 is read into configuration bits during
reset.
4. This pin is a reset configuration pin.
5. DL[0] is a reset configuration pin and has an internal pull-up resistor that is enabled only when the MPC8240 is in
the reset state.The value of the internal pull-up resistor is not guaranteed, but is sufficient to ensure that a one is
read into configuration bits during reset.
6. Multi-pin signals such as AD[0:31] or DL[0:31] have their physical package pin numbers listed in order
corresponding to the signal names. Example: AD0 is on pin C22, AD1 is on pin D22,...AD31 is on pin V25.
7. GNT4 is a reset configuration pin and has an internal pull-up resistor that is enabled only when the MPC8240 is in
the reset state.The value of the internal pull-up resistor is not guaranteed but is sufficient to ensure that a one is
read into configuration bits during reset.
8. Recommend a weak pull-up resistor (2–10 kΩ) be placed on this PCI control pin to LVDD.
9. VIH and VIL for these signals are the same as the PCI VIH and VIL entries in Table 3.
10.Recommend a weak pull-up resistor (2–10 kΩ) be placed on this pin to OVDD.
11.Recommend a weak pull-up resistor (2–10 kΩ) be placed on this pin to GVDD.
12.This pin has an internal pull-up resistor; the value of the internal pull-up resistor is not guaranteed, but is sufficient
to prevent unused inputs from floating.
13.Output valid specifications for this pin are memory interface mode dependent (registered or flow-through), see
Table 9.
14.Non-DRAM access output valid specification applies to this pin during non-DRAM accesses, see specification 12b3
in Table 9.
15.This pin is affected by programmable PCI_HOLD_DEL parameter, see Section 1.4.2.4.1, “PCI Signal Output Hold
Timing.”
16.This pin is an open drain signal.
17.This pin can be programmed to be driven (default) or can be programmed to be open drain; see the PMCR2 register
description in the MPC8240 Integrated Processor User’s Manual, for details.
18.This pin is a sustained three-state pin as defined by the PCI Local Bus Specification.
19.Maximum input voltage tolerance is LVDD-based. See Table 2 for details.
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PLL Configurations
1.6
PLL Configurations
The MPC8240 internal PLLs are configured by the PLL_CFG[0:4] signals. For a given PCI_SYNC_IN
(PCI bus) frequency, the PLL configuration signals set both the peripheral logic/memory bus PLL (VCO)
frequency of operation for the PCI-to-memory frequency multiplying and the MPC603e CPU PLL (VCO)
frequency of operation for memory-to-CPU frequency multiplying. The PLL configurations for the
MPC8240 is shown in Table 18.
Table 18. MPC8240 Microprocessor PLL Configurations
Freescale Semiconductor, Inc...
200 MHz Part 8,9
Peripheral
CPU 1 HID1
PCI Clock Input
Logic/ Mem Bus
[0:4]
(PCI_SYNC_IN)
Clock Range
Range (MHz)
(MHz)
Ref.
No.
PLL_CFG
[0:4] 2
0
00000
00110
1
00001
11000
2
00010
00101
3
00011
00101
25–26
75–80
Ratios 3,4
CPU Clock
Range
(MHz)
PCI-to-Mem
(Mem VCO)
Multiplier
Mem-to-CPU
(CPU VCO)
Multiplier
188–200
3 (6)
2.5 (5)
3 (6)
3 (6)
1 (4)
2 (8)
Bypass
2 (8)
2 (8)
2 (8)
Not usable
50–56
5
25–28
5
50 – 56
100–112
Bypass
4
00100
00101
5
00101
00110
Bypass
Bypass
2.5 (5)
7
00111
11000
Bypass
Bypass
3 (6)
8
01000
11000
1 (4)
3 (6)
A
01010
00111
2 (4)
4.5 (9)
C
01100
00110
25–40
50–80
125–200
2 (4)
2.5 (5)
E
01110
11000
25–33
50–66
150–200
2 (4)
3 (6)
10
10000
00100
25–33
75–100
150–200
3 (6)
2 (4)
50–100
100–200
1.5 (3)
2 (4)
33 6–56 5
50–56
33–56
100–113
100–168
Not usable
33 7
12
10010
00100
14
10100
11110
25–28
50–56
175–200
2 (4)
3.5 (7)
16
10110
11010
25
50
200
2 (4)
4 (8)
18
11000
11000
25–26
62–65
186–200
2.5 (5)
3 (6)
1A
11010
11010
50
50
200
1 (2)
4 (8)
11000
33
7–44
50–66
150–200
1.5 (3)
3 (6)
33
7–53
50–80
125–200
1.5 (3)
2.5 (5)
1C
1D
34
11100
11101
00110
–66
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System Design Information
Table 18. MPC8240 Microprocessor PLL Configurations (continued)
200 MHz Part 8,9
Ref.
No.
PLL_CFG
[0:4] 2
1E
11110
Peripheral
CPU 1 HID1
PCI Clock Input
Logic/ Mem Bus
[0:4]
(PCI_SYNC_IN)
Clock Range
Range (MHz)
(MHz)
Ratios 3,4
CPU Clock
Range
(MHz)
01111
PCI-to-Mem
(Mem VCO)
Multiplier
Mem-to-CPU
(CPU VCO)
Multiplier
Off
Off
Off
Off
Not usable
Freescale Semiconductor, Inc...
1F
11111
11111
Notes:
1. The processor HID1 values only represent the multiplier of the processor’s PLL (memory-to-processor multiplier);
thus, multiple MPC8240 PLL_CFG[0:4] values may have the same processor HID1 value. This implies that system
software cannot read the HID1 register and associate it with a unique PLL_CFG[0:4] value.
2. PLL_CFG[0:4] settings not listed (00110, 01001, 01011, 01101, 01111, 10001, 10011, 10101, 10111, 11001, and
11011) are reserved.
3. In PLL-bypass mode, the PCI_SYNC_IN input signal clocks the internal processor directly, the peripheral logic PLL
is disabled, and the bus mode is set for 1:1 (PCI:Mem) mode operation. This mode is intended for hardware
modeling support. The AC timing specifications given in this document do not apply in the PLL-bypass mode.
4. In clock-off mode, no clocking occurs inside the MPC8240 regardless of the PCI_SYNC_IN input.
5. Limited due to maximum memory VCO = 225 MHz.
6. Limited due to minimum CPU VCO = 200 MHz.
7. Limited due to minimum memory VCO = 100 MHz.
8. For clarity, range values are shown rounded down to the nearest whole number (decimal place accuracy removed).
9. Note that the 250-MHz part is available only in the XPC8240RZUnnnx number series.
1.7
System Design Information
This section provides electrical and thermal design recommendations for successful application of the
MPC8240.
1.7.1
PLL Power Supply Filtering
The AVDD, AVDD2, and LAVDD power signals on the MPC8240 provide power to the peripheral
logic/memory bus PLL, MPC603e processor PLL, and SDRAM clock delay-locked loop (DLL),
respectively. To ensure stability of the internal clocks, the power supplied to the AVDD, AVDD2, and LAVDD
input signals should be filtered of any noise in the 500-KHz to 10-MHz resonant frequency range of the
PLLs. Three separate circuits similar to the one shown in Figure 24 using surface mount capacitors with
minimum effective series inductance (ESL) is recommended for AVDD, AVDD2, and LAVDD power signal
pins. Consistent with the recommendations of Dr. Howard Johnson in High Speed Digital Design: A
Handbook of Black Magic (Prentice Hall, 1993), using multiple small capacitors of equal value is
recommended over using multiple values.
The circuits should be placed as close as possible to the respective input signal pins to minimize noise
coupled from nearby circuits. Routing directly as possible from the capacitors to the input signal pins with
minimal inductance of vias is important.
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10 Ω
VDD
AVDD
2.2 µF
2.2 µF
Low ESL Surface Mount Capacitors
GND
Figure 24. PLL Power Supply Filter Circuit
Freescale Semiconductor, Inc...
1.7.2
Power Supply Sizing
The power consumption numbers provided in Table 5 do not reflect power from the OVDD and GVDD power
supplies that are non-negligible for the MPC8240. In typical application measurements, the OVDD power
ranged from 200 to 600 mW and the GVDD power ranged from 300 to 900 mW. The ranges’ low-end power
numbers were results of the MPC8240 performing cache-resident integer operations at the slowest
frequency combination of 33:66:166 (PCI:Mem:CPU) MHz. The OVDD high-end range’s value resulted
from the MPC8240 performing continuous flushes of cache lines with alternating ones and zeros to PCI
memory. The GVDD high-end range’s value resulted from the MPC8240 operating at the fastest frequency
combination of 66:100:250 (PCI:Mem:CPU) MHz and performing continuous flushes of cache lines with
alternating ones and zeros on 64-bit boundaries to local memory.
1.7.3
Decoupling Recommendations
Due to its dynamic power management feature, large address and data buses, and high operating
frequencies, the MPC8240 can generate transient power surges and high frequency noise in its power
supply, especially while driving large capacitive loads. This noise must be prevented from reaching other
components in the MPC8240 system, and the MPC8240 itself requires a clean, tightly regulated source of
power. Therefore, it is recommended that the system designer place at least one decoupling capacitor at each
VDD, OVDD, GVDD, and LVDD pin of the MPC8240. It is also recommended that these decoupling capacitors
receive their power from separate VDD, OVDD, GVDD, and GND power planes in the PCB, utilizing short
traces to minimize inductance. These capacitors should have a value of 0.1 µF. Only ceramic SMT (surface
mount technology) capacitors should be used to minimize lead inductance, preferably 0508 or 0603,
oriented such that connections are made along the length of the part.
In addition, it is recommended that there be several bulk storage capacitors distributed around the PCB,
feeding the VDD, OVDD, GVDD, and LVDD planes, to enable quick recharging of the smaller chip capacitors.
These bulk capacitors should have a low ESR (equivalent series resistance) rating to ensure the quick
response time necessary. They should also be connected to the power and ground planes through two vias
to minimize inductance. Suggested bulk capacitors: 100–330 µF (AVX TPS tantalum or Sanyo OSCON).
1.7.4
Connection Recommendations
To ensure reliable operation, it is highly recommended to connect unused inputs to an appropriate signal
level. Unused active low inputs should be tied to OVDD. Unused active high inputs should be connected to
GND. All NC (no connect) signals must remain unconnected.
Power and ground connections must be made to all external VDD, OVDD, GVDD, LVDD, and GND pins of the
MPC8240.
The PCI_SYNC_OUT signal is intended to be routed halfway out to the PCI devices and then returned to
the PCI_SYNC_IN input of the MPC8240.
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The SDRAM_SYNC_OUT signal is intended to be routed halfway out to the SDRAM devices and then
returned to the SDRAM_SYNC_IN input of the MPC8240. The trace length may be used to skew or adjust
the timing window as needed. See the Motorola application note AN1794, “Backside L2 Timing Analysis
for PCB Design Engineers,” for more information on this topic.
1.7.5
Pull-Up/Pull-Down Resistor Requirements
The data bus input receivers are normally turned off when no read operation is in progress; therefore, they
do not require pull-up resistors on the bus. The data bus signals are: DH[0:31], DL[0:31], and PAR[0:7].
Freescale Semiconductor, Inc...
If the 32-bit data bus mode is selected, the input receivers of the unused data and parity bits (DL[0:31] and
PAR[4:7]) will be disabled, and their outputs will drive logic zeros when they would otherwise normally be
driven. For this mode, these pins do not require pull-up resistors and should be left unconnected by the
system to minimize possible output switching.
The TEST0 pins require pull-up resistors of 120 Ω or less connected to OVDD.
It is recommended that TEST2 have a weak pull-up resistor (2–10 kΩ) connected to GVDD.
It is recommended that the following signals be pulled up to OVDD with weak pull-up resistors (2–10 kΩ):
SDA, SCL, SMI, SRESET, TBEN, CHKSTOP_IN, and TEST1.
It is recommended that the following PCI control signals be pulled up to LVDD with weak pull-up resistors
(2–10 kΩ): DEVSEL, FRAME, IRDY, LOCK, PERR, SERR, STOP, TRDY, and INTA. The resistor values
may need to be adjusted stronger to reduce induced noise on specific board designs.
The following pins have internal pull-up resistors enabled at all times: REQ[0:3], REQ4/DA4, TCK, TDI,
TMS, and TRST. See Table 17 for more information.
The following pins have internal pull-up resistors enabled only while the MPC8240 is in the reset state:
GNT4/DA5, DL0, FOE, RCS0, SDRAS, SDCAS, CKE, AS, MCP, MAA[0:2], PMAA[0:2], and
QACK/DA0. See Table 17 for more information.
The following pins are reset configuration pins: GNT4/DA5, DL0, FOE, RCS0, CKE, AS, MCP,
QACK/DA0, MAA[0:2], PMAA[0:2], and PLL_CFG[0:4]/DA[10:6]. These pins are sampled during reset
to configure the device.
Reset configuration pins should be tied to GND via 1-kΩ pull-down resistors to ensure a logic 0 level is read
into the configuration bits during reset if the default logic 1 level is not desired.
Any other unused active-low input pins should be tied to a logic one level through weak pull-up resistors
(2–10 kΩ) to the appropriate power supply. Unused active-high input pins should be tied to GND through
weak pull-down resistors (2–10 kΩ).
1.7.6
JTAG Configuration Signals
Boundary scan testing is enabled through the JTAG interface signals. The TRST signal is optional in the
IEEE 1149.1 specification but is provided on all processors that implement the PowerPC architecture. While
it is possible to force the TAP controller to the reset state using only the TCK and TMS signals, more reliable
power-on reset performance will be obtained if the TRST signal is asserted during power-on reset. Because
the JTAG interface is also used for accessing the common on-chip processor (COP) function, simply tying
TRST to HRESET is not practical.
The COP function of these processors allows a remote computer system (typically, a PC with dedicated
hardware and debugging software) to access and control the internal operations of the processor. The COP
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interface connects primarily through the JTAG port of the processor, with some additional status monitoring
signals. The COP port requires the ability to independently assert HRESET or TRST in order to fully control
the processor. If the target system has independent reset sources, such as voltage monitors, watchdog timers,
power supply failures, or push-button switches, the COP reset signals must be merged into these signals with
logic.
The arrangement shown in Figure 25 allows the COP to independently assert HRESET or TRST, while
ensuring that the target can drive HRESET as well. If the JTAG interface and COP header will not be used,
TRST should be tied to HRESET so that it is asserted when the system reset signal (HRESET) is asserted
ensuring that the JTAG scan chain is initialized during power-on.
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The COP header shown in Figure 25 adds many benefits—breakpoints, watchpoints, register and memory
examination/modification, and other standard debugger features are possible through this interface—and
can be as inexpensive as an unpopulated footprint for a header to be added when needed.
The COP interface has a standard header for connection to the target system, based on the 0.025"
square-post, 0.100" centered header assembly (often called a Berg header).
There is no standardized way to number the COP header shown in Figure 25; consequently, many different
pin numbers have been observed from emulator vendors. Some are numbered top-to-bottom then
left-to-right, while others use left-to-right then top-to-bottom, while still others number the pins counter
clockwise from pin 1 (as with an IC). Regardless of the numbering, the signal placement recommended in
Figure 25 is common to all known emulators.
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MPC8240
SRESET 5
From Target
Board Sources
(if any)
SRESET 5
HRESET
13
11
HRST_CPU
10 kΩ
HRESET
HRST_CTRL
OVDD
SRESET 5
OVDD
10 kΩ
OVDD
10 kΩ
4
1
2
3
4
6
5
6
2
7
8
9
11
10
12
KEY
13 No
pin
15
16
COP Connector
Physical Pin Out
5
TRST
VDD_SENSE
15
Key
14 4
TRST
1 kΩ
10 kΩ
OVDD
OVDD
10 kΩ
3
COP Header
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OVDD
10 kΩ
10 kΩ
CHKSTOP_IN 6
8
OVDD
OVDD
CHKSTOP_IN 6
TMS
9
1
TMS
TDO
TDO
TDI
3
TDI
TCK
7
TCK
2
NC
10
NC
12
NC
QACK 1
16
Notes:
1. QACK is an output on the MPC8240 and is not required at the COP header for emulation.
2. RUN/STOP normally found on pin 5 of the COP header is not implemented on the MPC8240.
Connect pin 5 of the COP header to OVDD with a 1-kΩ pull-up resistor.
3. CKSTP_OUT normally found on pin 15 of the COP header is not implemented on the MPC8240.
Connect pin 15 of the COP header to OVDD with a 10-kΩ pull-up resistor.
4. Pin 14 is not physically present on the COP header.
5. SRESET functions as output SDMA12 in extended ROM mode.
6. CHKSTOP_IN functions as output SDMA14 in extended ROM mode.
Figure 25. COP Connector Diagram
1.7.7
PCI Reference Voltage—LVDD
The MPC8240 PCI reference voltage (LVDD) pins should be connected to 3.3 ±0.3 V power supply if
interfacing the MPC8240 into a 3.3-V PCI bus system. Similarly, the LVDD pins should be connected to
5.0 ±5% V power supply if interfacing the MPC8240 into a 5-V PCI bus system. For either reference
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voltage, the MPC8240 always performs 3.3-V signaling as described in the PCI Local Bus Specification,
(Rev 2.1). The MPC8240 only tolerates 5-V signals when interfaced into a 5-V PCI bus system.
1.7.8
Thermal Management Information
This section provides thermal management information for the tape ball grid array (TBGA) package for
air-cooled applications. Proper thermal control design is primarily dependent on the system-level
design—the heat sink, airflow, and thermal interface material. To reduce the die-junction temperature, heat
sinks may be attached to the package by several methods: adhesive, spring clip to holes in the printed-circuit
board, or package and mounting clip and screw assembly. See Figure 26.
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Heat Sink
TBGA Package
Heat Sink
Clip
Adhesive or
Thermal Interface
Material
Die
Printed-Circuit Board
Option
Figure 26. Package Exploded Cross-Sectional View with Several Heat Sink Options
Figure 27 depicts the die junction-to-ambient thermal resistance for four typical cases:
•
•
•
•
40
A heat sink is not attached to the TBGA package, and there exists high board-level thermal loading
of adjacent components.
A heat sink is not attached to the TBGA package, and there exists low board-level thermal loading
of adjacent components.
A heat sink (for example, ChipCoolers #HTS255-P) is attached to the TBGA package, and there
exists high board-level thermal loading of adjacent components.
A heat sink (for example, ChipCoolers #HTS255-P) is attached to the TBGA package, and there
exists low board-level thermal loading of adjacent components.
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Die Junction-to-Ambient Thermal Resistance (°C/W)
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18
No heat sink and high thermal board-level loading of
adjacent components
No heat sink and low thermal board-level loading of
adjacent components
16
Attached heat sink and high thermal board-level loading of
adjacent components
Attached heat sink and low thermal board-level loading of
adjacent components
14
12
10
8
6
4
2
0
0.5
1
1.5
Airflow Velocity (m/s)
2
2.5
Figure 27. Die Junction-to-Ambient Resistance
The board designer can choose between several types of heat sinks to place on the MPC8240. Several
commercially-available heat sinks for the MPC8240 are provided by the following vendors:
Aavid Thermalloy
80 Commercial St.
Concord, NH 03301
Internet: www.aavidthermalloy.com
603-224-9988
Alpha Novatech
473 Sapena Ct. #15
Santa Clara, CA 95054
Internet: www.alphanovatech.com
408-749-7601
The Bergquist Company
18930 West 78th St.
Chanhassen, MN 55317
Internet: www.bergquistcompany.com
800-347-4572
International Electronic Research Corporation (IERC)
413 North Moss St.
Burbank, CA 91502
Internet: www.ctscorp.com
818-842-7277
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Tyco Electronics
Chip Coolers™
P.O. Box 3668
Harrisburg, PA 17105-3668
Internet: www.chipcoolers.com
800-522-6752
Wakefield Engineering
33 Bridge St.
Pelham, NH 03076
Internet: www.wakefield.com
603-635-5102
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Ultimately, the final selection of an appropriate heat sink depends on many factors, such as thermal
performance at a given air velocity, spatial volume, mass, attachment method, assembly, and cost.
1.7.8.1
Internal Package Conduction Resistance
The intrinsic conduction thermal resistance paths for the TBGA, cavity-down, packaging technology shown
in Figure 26 are as follows:
•
•
The die junction-to-case thermal resistance
The die junction-to-ball thermal resistance
Figure 28 depicts the primary heat transfer path for a package with an attached heat sink mounted to a
printed-circuit board.
External Resistance
Radiation
Convection
Heat Sink
Thermal Interface Material
Die/Package
Die Junction
Package/Leads
Internal Resistance
Printed-Circuit Board
External Resistance
Radiation
Convection
(Note the internal versus external package resistance.)
Figure 28. TBGA Package with Heat Sink Mounted to a Printed-Circuit Board
For this cavity-down, wire-bond TBGA package, heat generated on the active side of the chip is conducted
through the silicon, die attach, and package spreader, through the heat sink attach material (or thermal
interface material), and finally to the heat sink, where it is removed by forced-air convection.
1.7.8.2
Adhesives and Thermal Interface Materials
A thermal interface material is recommended at the package lid-to-heat sink interface to minimize thermal
contact resistance. For those applications where the heat sink is attached by a spring clip mechanism,
Figure 29 shows the thermal performance of three thin-sheet thermal-interface materials (silicone,
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graphite/oil, floroether oil), a bare joint, and a joint with thermal grease as a function of contact pressure.
As shown, the performance of these thermal interface materials improves with increased contact pressure.
The use of thermal grease significantly reduces the interface thermal resistance, that is, the bare joint results
in a thermal resistance approximately seven times greater than that of the thermal grease joint.
Heat sinks are attached to the package by means of a spring clip to holes in the printed-circuit board (see
Figure 26). Therefore, the synthetic grease offers the best thermal performance, considering the low
interface pressure. Of course, the selection of any thermal interface material depends on many factors:
thermal performance requirements, manufacturability, service temperature, dielectric properties, cost, and
so on.
Silicone Sheet (0.006 in.)
Bare Joint
Floroether Oil Sheet (0.007 in.)
Graphite/Oil Sheet (0.005 in.)
Synthetic Grease
Specific Thermal Resistance (K-in.2/W)
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2
1.5
1
0.5
0
0
10
20
30
40
50
Contact Pressure (psi)
60
70
80
Figure 29. Thermal Performance of Select Thermal Interface Material
The board designer can choose between several types of thermal interfaces. Heat sink adhesive materials
should be selected based on high conductivity and yet adequate mechanical strength to meet equipment
shock/vibration requirements. The following venders provide several commercially-available thermal
interfaces and adhesive materials:
Chomerics, Inc.
77 Dragon Ct.
Woburn, MA 01888-4014
Internet: www.chomerics.com
781-935-4850
Dow-Corning Corporation
Dow-Corning Electronic Materials
2200 W. Salzburg Rd.
Midland, MI 48686-0997
Internet: www.dow.com
800-248-2481
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Shin-Etsu MicroSi, Inc.
10028 S. 51st St.
Phoenix, AZ 85044
Internet: www.microsi.com
888-642-7674
Thermagon Inc.
4707 Detroit Ave.
Cleveland, OH 44102
Internet: www.thermagon.com
888-246-9050
The following section provides a heat sink selection example using one of the commercially-available heat
sinks.
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1.7.8.3
Heat Sink Selection Example
For preliminary heat sink sizing, the die-junction temperature, TJ, can be expressed as follows:
TJ = TA + TR + (RθJC + RθINT + RθSA) × PD
where
TJ is the die-junction temperature
TA is the inlet cabinet ambient temperature
TR is the air temperature rise within the computer cabinet
RθJC is the junction-to-case thermal resistance
RθINT is the adhesive or interface material thermal resistance
RθSA is the heat sink base-to-ambient thermal resistance
PD is the power dissipated by the device
During operation, the die-junction temperatures (TJ) should be maintained at less than the value specified
in Table 2. The temperature of the air cooling the component greatly depends on the ambient inlet air
temperature and the air temperature rise within the electronic cabinet. An electronic cabinet inlet-air
temperature (TA) may range from 30° to 40°C. The air temperature rise within a cabinet (TR) may be in the
range of 5° to 10°C. The thermal resistance of the thermal interface material (RθINT) is typically about
1°C/W. Assuming a TA of 30°C, a TR of 5°C, a TBGA package RθJC = 1.8, and a power consumption (PD)
of 5.0 watts, the following expression for TJ is obtained for die-junction temperature:
TJ = 30°C + 5°C + (1.8°C/W + 1.0°C/W + RθSA) × 5.0 W
For preliminary heat sink sizing, the heat sink base-to-ambient thermal resistance is needed from the heat
sink manufacturer.
Though the die junction-to-ambient and the heat sink-to-ambient thermal resistances are a common figure
of merit used for comparing the thermal performance of various microelectronic packaging technologies,
one should exercise caution when using only this metric in determining thermal management because no
single parameter can adequately describe three-dimensional heat flow. The final die-junction operating
temperature is not only a function of the component-level thermal resistance, but the system-level design
and its operating conditions. In addition to the component's power consumption, a number of factors affect
the final operating die-junction temperature: airflow, board population (local heat flux of adjacent
components), heat sink efficiency, heat sink attach, heat sink placement, next-level interconnect technology,
system air temperature rise, altitude, and so on.
Due to the complexity and the many variations of system-level boundary conditions for today’s
microelectronic equipment, the combined effects of the heat transfer mechanisms (radiation, convection,
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and conduction) may vary widely. For these reasons, it is recommended that conjugate heat-transfer models
for the board, as well as system-level designs, be used.
1.8
Document Revision History
Table 19 provides a revision history for this hardware specification.
Table 19. Document Revision History
Revision
Number
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0
Substantive Change(s)
Preliminary release with some TBDs in the spec tables.
0.1
Updated notes for Table 2.
Replaced TBDs in Table 3 with values for output high and low voltages.
Deleted 25/25/75 column from Table 5; inconsistent with PLL encoding 01000.
Updated minimum processor frequencies in Table 6 from 80 to 100 MHz.
Updated values in Table 8. Spec 10b split for flow through and registered modes.
Updated values in Table 9.
Updated PCI_HOLD_DEL value guidelines in Table 10 and Figure 10.
Relabeled DA[0:15] pins in opposite order and added Note 11 for TEST2 in Table 17.
Changed PLL configurations 01001 and 10001 in Table 18 to reserved configurations.
Updated PLL configuration 00010’s operation ranges in Table 18.
Revised TRST connection recommendations in Figure 22 for COP interface.
0.2
Added Note 4 to Table 2, updated Note and Caution numbers in Table 2 and Figure 2.
Modified Table 6:
—Added 250 MHz column.
—Changed Maximum PCI Input Frequency for 200 MHz part from 33 to 66 MHz.
—Made one column common entries for Memory Bus and PCI Input Frequencies.
Revised Note 7 of Table 7 to indicate a feedback loop length of 6.25 inches (formerly 11.8 inches)
corresponding to approximately 1 ns of delay.
Added 250 MHz column to Table 18.
Corrected document revision number for previous version of this document in Table 19. Document
revision was indicated as 1, should have been 0.1.
Removed P = Reduced Spec information from Figure 28; does not apply to MPC8240.
Added R = Modified Voltage Spec information to Figure 28.
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Table 19. Document Revision History (continued)
Revision
Number
0.3
Removed “PowerPC Platform compliant” from first sentence on cover sheet.
Changed PCI 2.1—’compatible’ to ‘compliant’ in Section 1.2.
Updated Table 5 and its notes with preliminary power-consumption information.
Updated Table 6, removing 266 MHz frequency information.
Made corrections to Table 7.
• Items 5a and 5b were changed to correct values for 66-MHz PCI_SYNC_IN.
• OSC_IN Frequency Stability spec from 1000 to 100 ppm.
Table 9:
• Changed item 12b1 from 8.0 to 7.0 ns.
• Added item 12b3, Output Valid for ROM accesses.
Table 11, item 2, “KAHLUA” terminology replaced with MPC8240.
Added EPIC Serial Interrupt Timing Section with two new figures, causing cross-references to
subsequent figures to be updated.
Updated formatting of pin out in Table 17.
Modified notes section in Table 17:
• Split Note 3 into new Notes 3 and 12. Notes 3, 5, and 7 cover internal pull-up resistors active only
during the reset state. Note 12 covers internal pull-up resistors enabled at all times.
• Note 11 has been revised.
• Added Note 10 to SDA and SCL signals for consistency with theMPC8240 User’s Manual.
• Added Note 10 to SMI and TBEN; inputs that should have pull-ups and for consistency with reference
designs.
• Added Note 10 to SRESET and CHKSTOP_IN for consistency with Figure 23 (COP Connector)
• Added Notes 13 and 14 for output valid specifications dependent upon memory mode.
• Added Note 15 for pins affected by programmable PCI output valid and hold time.
• Added Notes 16 –18 relating to open drain pins.
Figure 18:
• Revised 200-MHz column to reflect PCI_SYNC_IN 66-MHz upper limit.
• Refs 1E and 1F not usable entries made to match others in the table.
• Revised Notes 4 and 5 changing OSC_IN to PCI_SYNC_IN.
• Removed 266-MHz column.
• Removed Ref 0x06 for dual PLL bypass mode; added it to reserved list in Note 3.
• Revised Note 4 describing PLL bypass mode.
Added missing cross-reference in Section 1.7.2 and corrected Schottky reference to the 1N5820 diodes.
Added Section 1.7.2 on power supply sizing.
Modified internal pull-up resistor list in Section 1.7.5 to be consistent with Notes of Table 17; added reset
configuration pin pull-down resistor value recommendation.
Modified Figure 23, COP connector diagram:
• Reversed direction of CKSTP_IN arrow to show it going in.
• Added a pull-up resistor on TRST.
Changed R-spec device’s VDD range from 2.5–2.625 V to 2.5–2.75 V.
0.4
Modified DLL Lock Range with DLL_EXTEND = 1 equation in Table 7 from 0 ≤ (NTclk/2 – tloop – tfix0) ≤ 7
to 0 ≤(NTclk – Tclk/2 – tloop – tfix0) ≤ 7.
Modified Figure 5 to only show Tloop up to 15 ns, not practical to implement Tloop beyond 15 ns.
Modified DL[0:31] and DH[0:31] signal names to MDL[0:31] and MDH[0:31], respectively, in Table 17 to
be consistent with the Tundra Tsi107™ PowerPC host bridge data bus naming convention.
Several active low signal names in Table 17 inadvertently had the overline formatting removed during the
final edit process of the previous revision. The signals are shown correctly with overlines in this version.
Signals affected were: DEVSEL, FRAME, LOCK, PERR, SERR, STOP, TRDY, INTA, FOE, RCS0, RCS1,
SDRAS, SDCAS, WE, AS, HRST_CTRL, HRST_CPU, MCP, SMI, SRESET, CHKSTOP_IN, and MIV.
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46
Substantive Change(s)
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Table 19. Document Revision History (continued)
Revision
Number
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0.5
Substantive Change(s)
Removed references to GVDD = 2.5 V until characterization of the memory interface at this voltage has
been completed.
Corrected Figure 2 power supply ramp-up time to be before the 100 ms PLL relock time.
Table 3:
• Deleted input leakage specification @ LVDD = 5.5 V.
• Changed minimum ‘Input High Voltage for PCI only’ from 0.5*OVDodaoD to 0.65*OVDD and added
Note 6.
• Changed condition on ‘Input Low Voltage,’ VIL, from ‘All inputs except OSC_IN’ to ‘All inputs except
PCI_SYNC_IN.’
• Replaced minimum CVIH formula, 0.5*OVDD, with 2.4-V value.
• Replaced maximum CVIL formula, 0.3*OVDD, with 0.4-V value.
Added Note 10 to Table 5.
Changed minimum memory bus frequency of operation from 25 to 33 MHz in Table 6 to coincide with
information shown in PLL_CFG Table 18.
Updated clock specifications in Table 7.
Updated input AC timing specifications in Table 8.
Updated output AC timing specifications in Table 9.
Replaced TBDs in Table 14 for specs 3, 5, and 6.
Table 17 renamed TEST3 (pin AF20) to TRIG_IN and renamed TEST4 (pin AC18) to TRIG_OUT; moved
both pins from Test/Configuration Signals group to Miscellaneous Signals group.
Added external pull-up resistor to LVDD recommendation for INTA signal in Table 17 and Section 1.7.5.
Added Note 19 to Table 17 about AVDD and LAVDD being internally connected; revised Section 1.7.1,
on filtering these pins.
Replaced HID1 column TBDs in Table 18 and deleted Note 1 resulting in renumbering notes throughout
Table 18.
Added Section 1.7.7, about PCI reference voltage.
Added note in Section 1.9, indicating ‘L=Standard Spec.’ part is only available in 200 MHz version of the
device. Changed ‘XPC’ to ‘MPC’ for consistency with other references in the document.
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Document Revision History
Table 19. Document Revision History (continued)
Revision
Number
Freescale Semiconductor, Inc...
0.6
48
Substantive Change(s)
Updated Technology in Section 1.3 from 0.32 to 0.29 µm.
Updated Notes in Table 2. Changed line 2 to reflect supply voltage wording of the other lines. Changed
notes 2 and 3 to include all LVDD input tolerant signals.
Updated Table 4 eliminating LVDD = 5.0 V entries for DRV_PCI. Changed LVDD to OVDD for remaining
DRV_PCI entries. Updated notes.
Updated Table 6 to show minimum memory bus operating frequency is 33 MHz.
Updated Table 8 with new characterization data for numbers 22 and 23.
Updated Table 8 adding ‘/In-line’ to ‘Registered’ in Spec 10b2.
Updated Table 9 to Table 10 to how changes for MCP and CKE reset configuration changes for
PCI_HOLD_DEL.
Updated Table 12 eliminating 25 MHz column since memory interface does not operate at this frequency.
Updated Table 17:
• REQ4/DA4 and PLL_CFG[0:4]/DA[10:6] changed Pin Type from Input to I/O.
• DA2, DA[11:13], DA[14:15] changed Pin Type from I/O to Output.
• Reversed vector ordering for the PCI Interface Signals: C/BE[0:3] changed to C/BE[3:0], AD[0:31]
changed to AD[31:0], GNT[0:3] changed to GNT[3:0], and REQ[0:3] changed to REQ[3:0]. The
package pin number orderings were also reversed meaning that pin functionality did NOT change. For
example, AD0 is still on signal C22, AD1 is still on signal D22, ... AD31 is still on signal V25. This
change was made to make the vectored PCI signals in the MPC8240 Hardware Specification
consistent with the PCI Local Bus Specification and the MPC8240 User Manual vector ordering.
• Deleted Note 19 indicating LAVDD and AVDD are internally connected. Added a new Note 19 about
OSC_IN and EPIC control signals input voltage levels.
Updated Section 1.7.1, eliminating references to LAVDD and AVDD being internally connected.
Updated Table 23 changing 2-kΩ pull-up resistor on VDD_SENSE to 1-kΩ.
Moved Section 1.7.7 to be at end of JTAG section.
Changed erroneous C4 reference in Figure 26 title to TBGA.
Deleted references to FLOTHERM models in Section 1.7.8.3.
1
Updated notes for Table 2, to include that the values maybe exceeded for up to 20 ms.
Updated Figure 2, removed note 2 concerning voltage sequencing.
Updated Solder Balls in Section 1.5.1, from 63/37 Sn/Pb to 62 Sn/36 Pb/2 Ag.
Updated Table 9, adding ‘address’ to 12b1-3.
Updated Table 10 to show the settings for silicon rev. 1.0/1.1 and for silicon rev. 1.2/1.3.
Updated Table 17:
• removed Note 10 from TRIG_OUT.
• Created separate rows for TEST0 and TEST1 to reflect the change made in Note 1
• Changed Note 1 to refer only to TEST0.
Removed Section 1.7.2.
Section 1.6.8—Updated list of heat sink and thermal interface vendors.
Changed format of Section 1.8.
2
Section 1.3.1.5—Updated Table 5 to reflect power numbers for the L spec (2.5 V) part. The power
numbers for the R spec (2.625 V) part are now in the part number specifications document
MPC8240RZUPNS.
Section 1.5—Table 18 now reflects the L spec parts (200 MHz). The R spec PLL table is now in the R spec
(250 MHz) part number specifications document MPC8240RZUPNS.
Section 1.6.6—Updated this section and Figure 26.
Section 1.8.2—Updated reference to part number specifications document.
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Ordering Information
Table 19. Document Revision History (continued)
Freescale Semiconductor, Inc...
Revision
Number
Substantive Change(s)
3
Throughout this document, the acronym EPIC was changed to PIC.
Throughout this document, the register name EICR was changed to ICR
Figure 2—The note numbers in the figure were renumbered to reflect the notes.
Table 7—Num 15 and 16 were updated, and Note 7 was corrected.
Figure 5 was updated to reflect the changes made in Table 7.
Section 1.7.6—Updated this section and Figure 23.
Section 1.9.1—Updated Table 20.
Section 1.9.2—Updated Table 21.
4
Section 1.4.1.2—Added Figure 4 and 5, Overshoot and Undershoot Voltage of PCI Interface
Section 1.5.1—Added solder ball package information for Lead free TBGA offering
Section 1.9—Added information regarding Lead free TBGA offering.
1.9
Ordering Information
Ordering information for the parts fully covered by this specification document is provided in Section 1.9.1,
“Part Numbers Fully Addressed by This Document.” Section 1.9.2, “Part Numbers Not Fully Addressed by
This Document,” lists the part numbers that do not fully conform to the specifications of this document.
These special part numbers require an additional document called a part number specification.
1.9.1
Part Numbers Fully Addressed by This Document
Table 20 provides the Motorola part numbering nomenclature for the MPC8240. Note that the individual
part numbers correspond to a maximum processor core frequency. For available frequencies, contact a local
Motorola sales office. Each part number also contains a revision code that refers to the die mask revision
number. The revision level can be determined by reading the Revision ID register at address offset 0x08.
Table 20. Part Numbering Nomenclature
XPC
nnnn
x
xx
nnn
x
Product Code
Part Identifier
Process
Descriptor
Package 1
Processor
Frequency 2
Revision Level
XPC
8240
L = 2.5 V ± 125 mV
0 to 105°C
ZU = TBGA
V V = Lead free
TBGA
200
E: 1.3, Revision ID 0x13
Notes:
1. See Section 1.5, “Package Description,” for more information on available package types.
2. Processor core frequencies supported by parts addressed by this specification only. Not all parts described in
this specification support all core frequencies. Additionally, parts addressed by part number specifications may
support other maximum core frequencies.
1.9.2
Part Numbers Not Fully Addressed by This Document
Parts with application modifiers or revision levels not fully addressed in this specification document are
described in separate part number specifications that supplement and supersede this document. Table 21
shows the part numbers addressed by the XPC8240RXX250x part number specifications.
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Table 21. Part Numbers Addressed by XPC8240RXX250x Part Number Specification
XPC
nnnn
x
xx
nnn
x
Product Code
Part Identifier
Process
Descriptor
Package
Processor
Frequency
Revison Level
XPC
8240
250
E: 1.3; Revision ID 0x13
R = 2.625 V ± 125 mV, ZU = TBGA
0 to 105°C
V V = Lead free
TBGA
Note: For other differences, see applicable specifications.
1.9.3
Part Marking
Freescale Semiconductor, Inc...
Parts are marked as the example shown in Figure 30.
XPC8240L
XX200E
MMMMMM
ATWLYYWWA
8240
Notes:
MMMMMM is the 6-digit mask number.
ATWLYYWWA is the traceability code.
TBGA
Figure 30. Motorola Part Marking for TBGA Device
50
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