MOTOROLA MPC5200BV400

Freescale Semiconductor, Inc.
MPC5200/D
Rev. 2, 5/2004
MPC5200 Hardware
Specifications
Freescale Semiconductor, Inc...
Topic
Page
1
Overview ......................................1
2
Features .......................................1
3
Electrical and Thermal
Characteristics..............................5
4
Package Description ..................60
5
System Design Information ........69
6
Ordering Information ..................74
7
Document Revision History ........75
NOTE:
The information in this document is subject to
change. For the latest data on the MPC5200, visit
www.mobilegt.com and proceed to the MPC5200
Product Summary Page.
1
Overview
The MPC5200 integrates a high performance MPC603e series G2_LE core with a
rich set of peripheral functions focused on communications and systems
integration. The G2_LE core design is based on the PowerPC® core architecture.
MPC5200 incorporates an innovative BestComm I/O subsystem, which isolates
routine maintenance of peripheral functions from the embedded G2_LE core. The
MPC5200 contains a SDRAM/DDR Memory Controller, a flexible External Bus
Interface, PCI Controller, USB, ATA, Ethernet, six Programmable Serial Controllers
(PSC), I2C, SPI, CAN, J1850, Timers, and GPIOs.
2
Features
Key features are shown below.
•
MPC603e series G2_LE core
—
—
—
—
—
—
•
SDRAM / DDR Memory Interface
—
—
—
—
—
•
Superscalar architecture
760 MIPS at 400 MHz (-40 to +85 oC)
16 k Instruction cache, 16 k Data cache
Double precision FPU
Instruction and Data MMU
Standard and Critical interrupt capability
up to 132-MHz operation
SDRAM and DDR SDRAM support
256-MByte addressing range per CS, two CS available
32-bit data bus
Built-in initialization and refresh
Flexible multi-function External Bus Interface
— Supports interfacing to ROM/Flash/SRAM memories or other memory
mapped devices
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Features
—
—
—
—
•
Peripheral Component Interconnect (PCI) Controller
—
—
—
—
—
•
8 programmable Chip Selects
Non multiplexed data access using 8/16/32 bit databus with up to 26-bit address
Short or Long Burst capable
Multiplexed data access using 8/16/32 bit databus with up to 25-bit address
Version 2.2 PCI compatibility
PCI initiator and target operation
32-bit PCI Address/Data bus
33- and 66-MHz operation
PCI arbitration function
ATA Controller
— Version 4 ATA compatible external interface—IDE Disk Drive connectivity
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•
BestComm DMA subsystem
— Intelligent virtual DMA Controller
— Dedicated DMA channels to control peripheral reception and transmission
— Local memory (SRAM 16 kBytes)
•
6 Programmable Serial Controllers (PSC), configurable for the following:
—
—
—
—
•
UART or RS232 interface
CODEC interface for Soft Modem, Master/Slave CODEC Mode, I2S and AC97
Full duplex SPI mode
IrDA mode from 2400 bps to 4 Mbps
Fast Ethernet Controller (FEC)
— Supports 100Mbps IEEE 802.3 MII, 10 Mbps IEEE 802.3 MII, 10 Mbps 7-wire interface
•
Universal Serial Bus Controller (USB)
— USB Revision 1.1 Host
— Open Host Controller Interface (OHCI)
— Integrated USB Hub, with two ports.
•
Two Inter-Integrated Circuit Interfaces (I2C)
•
Serial Peripheral Interface (SPI)
•
Dual CAN 2.0 A/B Controller (MSCAN)
— Motorola Scalable Controller Area Network (MSCAN) architecture
— Implementation of version 2.0A/B CAN protocol
— Standard and extended data frames
•
J1850 Byte Data Link Controller (BDLC)
— J1850 Class B data communication network interface compatible and ISO compatible for low
speed (<125 kbps) serial data communications in automotive applications.
— Supports 4X mode, 41.6 kbps
— In-frame response (IFR) types 0, 1, 2, and 3 supported
2
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Features
•
Systems level features
— Interrupt Controller supports four external interrupt request lines and 47 internal interrupt
sources
— GPIO/Timer functions
– Up to 56 total GPIO pins (depending on functional multiplexing selections) that support a
variety of interrupt/WakeUp capabilities.
– Eight GPIO pins with timer capability supporting input capture, output compare, and pulse
width modulation (PWM) functions
Freescale Semiconductor, Inc...
—
—
—
—
—
•
Real-time Clock with one-second resolution
Systems Protection (watch dog timer, bus monitor)
Individual control of functional block clock sources
Power management: Nap, Doze, Sleep, Deep Sleep modes
Support of WakeUp from low power modes by different sources (GPIO, RTC, CAN)
Test/Debug features
— JTAG (IEEE 1149.1 test access port)
— Common On-chip Processor (COP) debug port
•
On-board PLL and clock generation
Figure 1 shows a simplified MPC5200 block diagram.
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3
4
Reset / Clock
Generation
JTAG / COP
Interface
CommBus
G2_LE Core
603
SDRAM / DDR
Memory Controller
SDRAM / DDR
ATA Host Controller
PCI Bus Controller
Local Plus Controller
GPIO/Timers
Interrupt Controller
System Functions
Real-Time Clock
Systems Interface Unit (SIU)
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Local
Bus
Features
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MSCAN
2x
J1850
USB
2x
SPI
I2C
2x
BestComm DMA
Ethernet
SRAM 16K
PSC
6x
Figure 1 Simplified Block Diagram—MPC5200
MPC5200 Hardware Specifications
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Electrical and Thermal Characteristics
3
Electrical and Thermal Characteristics
3.1
DC Electrical Characteristics
3.1.1 Absolute Maximum Ratings
The tables in this section describe the MPC5200 DC Electrical characteristics. Table 1 gives the absolute
maximum ratings.
Freescale Semiconductor, Inc...
Table 1 Absolute Maximum Ratings 1
Characteristic
Symbol
Min
Max
Unit
SpecID
Supply voltage - G2_LE core and peripheral logic
VDD_CORE
–0.3
1.8
V
D1.1
VDD_IO,
VDD_MEM_IO
–0.3
3.6
V
D1.2
Supply voltage - System APLL
SYS_PLL_AVDD
–0.3
2.1
V
D1.3
Supply voltage - G2_LE APLL
CORE_PLL_AVDD
–0.3
2.1
V
D1.4
Input voltage (VDD_IO)
Vin
–0.3
VDD_IO + 0.3
V
D1.5
Input voltage (VDD_MEM_IO)
Vin
–0.3
VDD_MEM_IO
+ 0.3
V
D1.6
Input voltage overshoot
Vinos
–
1.0
V
D1.7
Input voltage undershoot
Vinus
–
1.0
V
D1.8
Storage temperature range
Tstg
–55
150
oC
D1.9
Supply voltage - I/O buffers
1
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.
3.1.2 Recommended Operating Conditions
Table 2 gives the recommended operating conditions.
Table 2 Recommended Operating Conditions
Characteristic
Symbol
Min 1
Max1
Unit
SpecID
Supply voltage - G2_LE core and peripheral logic
VDD_CORE
1.42
1.58
V
D2.1
Supply voltage - standard I/O buffers
VDD_IO
3.0
3.6
V
D2.2
Supply voltage - memory I/O buffers
(SDR)
VDD_MEM_IOSDR
3.0
3.6
V
D2.3
Supply voltage - memory I/O buffers
(DDR)
VDD_MEM_IODDR
2.42
2.63
V
D2.4
Supply voltage - System APLL
SYS_PLL_AVDD
1.42
1.58
V
D2.5
Supply voltage - G2_LE APLL
CORE_PLL_AVDD
1.42
1.58
V
D2.6
Vin
0
VDD_IO
V
D2.7
Input voltage - memory I/O buffers (SDR)
VinSDR
0
VDD_MEM_IOSDR
V
D2.8
Input voltage - memory I/O buffers (DDR)
VinDDR
0
VDD_MEM_IODDR
V
D2.9
Input voltage - standard I/O buffers
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Electrical and Thermal Characteristics
Table 2 Recommended Operating Conditions (continued)
Symbol
Min 1
Max1
TA
-40
+85
o
C
D2.10
Extended ambient operating temperature
range 3
TAext
-40
+105
o
C
D2.11
Die junction operating temperature range
Tj
-40
+115
o
C
D2.12
Extended die junction operating temperature range
Tjext
-40
+125
o
C
D2.13
Characteristic
Ambient operating temperature range 2
Freescale Semiconductor, Inc...
1
2
3
Unit
SpecID
These are recommended and tested operating conditions. Proper device operation outside these conditions is not guaranteed.
Maximum G2_LE core operating frequency is 400 MHz
Maximum G2_LE core operating frequency is 264 MHz
3.1.3 DC Electrical Specifications
Table 3 gives the DC Electrical characteristics for the MPC5200 at recommended operating conditions
(see Table 2).
Table 3 DC Electrical Specifications
Characteristic
Condition
Symbol
Min
Max
Unit
SpecID
Input high voltage
Input type = TTL
VDD_IO/VDD_MEM_IOSDR
VIH
2.0
—
V
D3.1
Input high voltage
Input type = TTL
VDD_MEM_IODDR
VIH
1.7
—
V
D3.2
Input high voltage
Input type = PCI
VDD_IO
VIH
2.0
—
V
D3.3
Input high voltage
Input type = SCHMITT
VDD_IO
VIH
2.0
—
V
D3.4
Input high voltage
SYS_XTAL_IN
CVIH
2.0
—
V
D3.5
Input high voltage
RTC_XTAL_IN
CVIH
2.0
—
V
D3.6
Input low voltage
Input type = TTL
VDD_IO/VDD_MEM_IOSDR
VIL
—
0.8
V
D3.7
Input low voltage
Input type = TTL
VDD_MEM_IODDR
VIL
—
0.7
V
D3.8
Input low voltage
Input type = PCI
VDD_IO
VIL
—
0.8
V
D3.9
Input low voltage
Input type = SCHMITT
VDD_IO
VIL
—
0.8
V
D3.10
Input low voltage
SYS_XTAL_IN
CVIL
—
0.8
V
D3.11
Input low voltage
RTC_XTAL_IN
CVIL
—
0.8
V
D3.12
Vin = 0 or
VDD_IO/VDD_IO_MEMSDR
IIN
—
+10
µA
D3.13
Input leakage current
(depending on input type 1)
6
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Electrical and Thermal Characteristics
Table 3 DC Electrical Specifications (continued)
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Characteristic
Condition
Symbol
Min
Max
Unit
SpecID
Input leakage current
SYS_XTAL_IN
Vin = 0 or VDD_IO
IIN
—
+10
µA
D3.14
Input leakage current
RTC_XTAL_IN
Vin = 0 or VDD_IO
IIN
—
+10
µA
D3.15
Input current, pullup resistor
PULLUP
VDD_IO
Vin = 0
IINpu
40
109
µA
D3.16
Input current, pullup resistor - memory I/O buffers
PULLUP_MEM
VDD_IO_MEMSDR
Vin = 0
IINpu
41
111
µA
D3.17
PULLDOWN
VDD_IO
Vin = VDD_IO
IINpd
36
106
µA
D3.18
Output high voltage
IOH is driver dependent 2
VDD_IO, VDD_IO_MEMSDR
VOH
2.4
—
V
D3.19
Output high voltage
IOH is driver dependent2
VDD_IO_MEMDDR
VOHDDR
1.7
—
V
D3.20
Output low voltage
IOL is driver dependent2
VDD_IO, VDD_IO_MEMSDR
VOL
—
0.4
V
D3.21
Output low voltage
IOL is driver dependent2
VDD_IO_MEMDDR
VOLDDR
—
0.4
V
D3.22
ICS
-1.0
1.0
mA
D3.23
Cin
—
15
pF
D3.24
Input current, pulldown
resistor
DC Injection Current Per
Pin 3
Capacitance
1
2
3
Vin = 0V, f = 1 MHz
Leakage current is measured with output drivers disabled and pull-up/pull-downs inactive.
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 51.
All injection current is transferred to VDD_IO/VDD_IO_MEM. An external load is required to dissipate this current to maintain the power supply within the specified voltage range.
Total injection current for all digital input-only and all digital input/output pins must not exceed 10 mA. Exceeding this limit
can cause disruption of normal operation.
Table 4 Drive Capability of MPC5200 Output Pins
Supply Voltage
IOH
IOL
DRV4
VDD_IO = 3.3V
4
4
mA
D3.25
DRV8
VDD_IO = 3.3V
8
8
mA
D3.26
DRV8_OD
VDD_IO = 3.3V
-
8
mA
D3.27
DRV16_MEM
VDD_IO_MEM = 3.3V
16
16
mA
D3.28
DRV16_MEM
VDD_IO_MEM = 2.5V
16
16
mA
D3.29
VDD_IO = 3.3V
16
16
mA
D3.30
Driver Type
PCI
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Unit SpecID
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Electrical and Thermal Characteristics
3.1.4 Electrostatic Discharge
— C A U T IO N —
This device contains circuitry that protects against damage due to high-static voltage
or electrical fields. However, it is advised that normal precautions be taken to avoid
application of any voltages higher than maximum-rated voltages. Operational reliability
is enhanced if unused inputs are tied to an appropriate logic voltage level ( i.e., either
GND or V CC ). Table 7 gives package thermal characteristics for this device.
Table 5 ESD and Latch-Up Protection Characteristics
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Sym
Min
Max
Unit
SpecID
VHBM Human Body Model (HBM)—JEDEC JESD22-A114-B
2000
—
V
D4.1
VMM
Machine Model (MM)—JEDEC JESD22-A115
200
—
V
D4.2
VCDM Charge Device Model (CDM)—JEDEC JESD22-C101
500
—
V
D4.3
Latch-up Current at TA=85oC
positive
negative
+100
-100
—
mA
Latch-up Current at TA=27oC
positive
negative
+200
-200
—
mA
ILAT
ILAT
Rating
D4.4
D4.5
3.1.5 Power Dissipation
Power dissipation of the MPC5200 is caused by 3 different components: the dissipation of the internal or
core digital logic (supplied by VDD_CORE), the dissipation of the analog circuitry (supplied by
SYS_PLL_AVDD and CORE_PLL_AVDD) and the dissipation of the IO logic (supplied by VDD_IO_MEM
and VDD_IO). Table 6 details typical measured core and analog power dissipation figures for a range of
operating modes. However, the dissipation due to the switching of the IO pins can not be given in general,
but must be calculated by the user for each application case using the following formula
P IO = P IOint + ∑ N × C × VDD_IO × f
2
M
where N is the number of output pins switching in a group M, C is the capacitance per pin, VDD_IO is the
IO voltage swing, f is the switching frequency and PIOint is the power consumed by the unloaded IO stage.
The total power consumption of the MPC5200 processor
P total = P core + P analog + P IO
must not exceed the value, which would cause the maximum junction temperature to be exceeded.
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Electrical and Thermal Characteristics
Table 6 Power Dissipation
Core Power Supply (VDD_CORE)
SYS_XTAL/XLB/PCI/IPG/CORE (MHz)
SpecID
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Mode
33/66/33/33/264
33/132/66/132/396
Unit
Notes
Typ
Typ
Operational
727.5
1080
mW
1 2
,
D5.1
Doze
—
600
mW
1, 3
D5.2
Nap
—
225
mW
1 4
,
D5.3
Sleep
—
225
mW
1 5
,
D5.4
Deep-Sleep
52.5
52.5
mW
1 6
D5.5
,
PLL Power Supplies (SYS_PLL_AVDD, CORE_PLL_AVDD)
Mode
Typ
Unit
Notes
Typical
2
mW
7
D5.6
Unloaded I/O Power Supplies (VDD_IO, VDD_MEM_IO 8)
Mode
Typ
Unit
Notes
Typical
33
mW
9
1
2
3
4
5
6
7
8
9
D5.7
Typical core power is measured at VDD_CORE = 1.5 V, Tj = 25 C
Operational power is measured while running an entirely cache-resident program with floating-point multiplication
instructions in parallel with a continuous PCI transaction via BestComm.
Doze power is measured with the G2_LE core in Doze mode, the system oscillator, System PLL and Core PLL are
active, all other system modules are inactive
Nap power is measured with the G2_LE core in Nap mode, the stem oscillator, System PLL and Core PLL are active, all other system modules are inactive
Sleep power is measured with the G2_LE core in Sleep mode, the stem oscillator, System PLL and Core PLL are
active, all other system modules are inactive
Deep-Sleep power is measured with the G2_LE core in Sleep mode, the stem oscillator, System PLL, Core PLL
and all other system modules are inactive
Typical PLL power is measured at SYS_PLL_AVDD = CORE_PLL_AVDD = 1.5 V, Tj = 25 C
IO power figures given in the table represent the worst case scenario. For the mem_io rail connected to 2.5V the
IO power is expected to be lower and bounded by the worst case with VDD_MEM_IO connected to 3.3V.
Unloaded typical I/O power is measured in Deep-Sleep mode at VDD_IO = VDD_MEM_IOSDR= 3.3 V, Tj = 25 C
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Electrical and Thermal Characteristics
3.1.6 Thermal Characteristics
Table 7 Thermal Resistance Data
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Rating
Value
Unit
Notes
SpecID
Junction to Ambient
Natural Convection
Single layer board
(1s)
RθJA
30
°C/W
1 2
,
D6.1
Junction to Ambient
Natural Convection
Four layer board (2s2p)
RθJMA
22
°C/W
1 3
,
D6.2
Junction to Ambient
(@200 ft/min)
Single layer board
(1s)
RθJMA
24
°C/W
13
,
D6.3
Junction to Ambient
(@200 ft/min)
Four layer board
(2s2p)
RθJMA
19
°C/W
13
,
D6.4
Junction to Board
RθJB
14
°C/W
4
D6.5
Junction to Case
RθJC
8
°C/W
5
D6.6
Junction to Package Top Natural Convection
ΨJT
°C/W
6
D6.7
1
2
3
4
5
6
3.1.6.1
2
Junction temperature is a function of die size, on-chip power dissipation, package thermal resistance, mounting site
(board) temperature, ambient temperature, air flow, power dissipation of other components on the board, and board
thermal resistance.
Per SEMI G38-87 and JEDEC JESD51-2 with the single layer board horizontal.
Per JEDEC JESD51-6 with the board horizontal.
Thermal resistance between the die and the printed circuit board per JEDEC JESD51-8. Board temperature is measured on the top surface of the board near the package.
Thermal resistance between the die and the case top surface as measured by the cold plate method (MIL SPEC-883
Method 1012.1).
Thermal characterization parameter indicating the temperature difference between package top and the junction
temperature per JEDEC JESD51-2. When Greek letters are not available, the thermal characterization parameter is
written as Psi-JT.
Heat Dissipation
An estimation of the chip-junction temperature, TJ, can be obtained from the following equation:
TJ = TA +(R θJA × PD )
Eqn. 1
where:
TA = ambient temperature for the package (ºC)
R θJA = junction to ambient thermal resistance (ºC/W)
PD = power dissipation in package (W)
The junction to ambient thermal resistance is an industry standard value, which provides a quick and easy
estimation of thermal performance. Unfortunately, there are two values in common usage: the value
determined on a single layer board, and the value obtained on a board with two planes. For packages such
as the PBGA, these values can be different by a factor of two. Which value is correct depends on the power
dissipated by other components on the board. The value obtained on a single layer board is appropriate for
the tightly packed printed circuit board. The value obtained on the board with the internal planes is usually
appropriate if the board has low power dissipation and the components are well separated.
Historically, the thermal resistance has frequently been expressed as the sum of a junction to case thermal
resistance and a case to ambient thermal resistance:
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Electrical and Thermal Characteristics
R θJA = R θJC +R θCA
Eqn. 2
where:
R θJA = junction to ambient thermal resistance (ºC/W)
R θJC = junction to case thermal resistance (ºC/W)
R θCA = case to ambient thermal resistance (ºC/W)
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R θJC is device related and cannot be influenced by the user. The user controls the thermal environment to
change the case to ambient thermal resistance, R θCA. For instance, the user can change the air flow
around the device, add a heat sink, change the mounting arrangement on printed circuit board, or change
the thermal dissipation on the printed circuit board surrounding the device. This description is most useful
for ceramic packages with heat sinks where some 90% of the heat flow is through the case to the heat sink
to ambient. For most packages, a better model is required.
A more accurate thermal model can be constructed from the junction to board thermal resistance and the
junction to case thermal resistance1-3. The junction to case covers the situation where a heat sink will be
used or where a substantial amount of heat is dissipated from the top of the package. The junction to
board thermal resistance describes the thermal performance when most of the heat is conducted to the
printed circuit board. This model can be used for either hand estimations or for a computational fluid
dynamics (CFD) thermal model.
To determine the junction temperature of the device in the application after prototypes are available, the
Thermal Characterization Parameter (ΨJT) can be used to determine the junction temperature with a
measurement of the temperature at the top center of the package case using the following equation:
TJ = TT +(Ψ JT × PD )
Eqn. 3
where:
TT = thermocouple temperature on top of package (ºC)
Ψ JT = thermal characterization parameter (ºC/W)
PD = power dissipation in package (W)
The thermal characterization parameter is measured per JESD51-2 specification using a 40-gauge type T
thermocouple epoxied to the top center of the package case. The thermocouple should be positioned, so
that the thermocouple junction rests on the package. A small amount of epoxy is placed over the
thermocouple junction and over approximately one mm of wire extending from the junction. The
thermocouple wire is placed flat against the package case to avoid measurement errors caused by cooling
effects of the thermocouple wire.
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Electrical and Thermal Characteristics
3.2
Oscillator and PLL Electrical Characteristics
The MPC5200 System requires a system-level clock input SYS_XTAL. This clock input may be driven
directly from an external oscillator or with a crystal using the internal oscillator.
There is a separate oscillator for the independent Real-Time Clock (RTC) system.
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The MPC5200 clock generation uses two phase locked loop (PLL) blocks.
•
The system PLL (SYS_PLL) takes an external reference frequency and generates the internal
system clock. The system clock frequency is determined by the external reference frequency and
the settings of the SYS_PLL configuration.
•
The G2_LE core PLL (CORE_PLL) generates a master clock for all of the CPU circuitry. The G2_LE
core clock frequency is determined by the system clock frequency and the settings of the
CORE_PLL configuration.
3.2.1 System Oscillator Electrical Characteristics
Table 8 System Oscillator Electrical Characteristics
Characteristic
Symbol
Notes
Min
Typical
Max
Unit
SpecID
SYS_XTAL frequency
fsys_xtal
15.6
33.3
35.0
MHz
O1.1
Oscillator start-up time
tup_osc
—
—
100
µs
O1.2
3.2.2 RTC Oscillator Electrical Characteristics
Table 9 RTC Oscillator Electrical Characteristics
Characteristic
RTC_XTAL frequency
12
Symbol
frtc_xtal
Notes
Min
Typical
Max
Unit
SpecID
—
32.768
—
kHz
O2.1
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Electrical and Thermal Characteristics
3.2.3 System PLL Electrical Characteristics
Table 10 System PLL Specifications
Characteristic
Symbol
Notes
Min
Typical
Max
Unit
SpecID
SYS_XTAL frequency
fsys_xtal
1
15.6
33.3
35.0
MHz
O3.1
SYS_XTAL cycle time
Tsys_xtal
1
66.6
30.0
28.5
ns
O3.2
tjitter
2
—
—
150
ps
O3.3
System VCO frequency
fVCOsys
1
250
533
800
MHz
O3.4
System PLL relock time
tlock
3
—
—
100
µs
O3.5
Freescale Semiconductor, Inc...
SYS_XTAL clock input jitter
1
2
3
The SYS_XTAL frequency and PLL Configuration bits must be chosen such that the resulting system frequency, CPU
(core) frequency, and PLL (VCO) frequency do not exceed their respective maximum or minimum operating frequencies.
This represents total input jitter - short term and long term combined - and is guaranteed by design. Two different types
of jitter can exist on the input to core_sysclk, systemic and true random jitter. True random jitter is rejected, but the PLL.
Systemic jitter will be passed into and through the PLL to the internal clock circuitry, directly reducing the operating frequency.
Relock time is guaranteed by design and characterization. PLL-relock time is the maximum amount of time required for
the PLL lock after a stable Vdd and core_sysclk are reached during the power-on reset sequence. This specification
also applies when the PLL has been disabled and subsequently re-enabled during sleep modes.
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Electrical and Thermal Characteristics
3.2.4 G2_LE Core PLL Electrical Characteristics
The internal clocking of the G2_LE core is generated from and synchronized to the system clock by means
of a voltage-controlled core PLL.
Table 11 G2_LE PLL Specifications
Freescale Semiconductor, Inc...
Characteristic
Symbol
Notes
Min
Typical
Max
Unit
SpecID
G2_LE frequency
fcore
1
50
—
550
MHz
O4.1
G2_LE cycle time
tcore
1
2.85
—
40.0
ns
O4.2
G2_LE VCO frequency
fVCOcore
1
400
—
1200
MHz
O4.3
G2_LE input clock frequency
fSYSCLK
25
—
367
MHz
O4.4
G2_LE input clock cycle time
tSYSCLK
2.73
—
50.0
ns
O4.5
G2_LE input clock jitter
tjitter
2
—
—
150
ps
O4.6
G2_LE PLL relock time
tlock
3
—
—
100
µs
O4.7
1
2
3
14
The SYSCLK frequency and G2_LE PLL Configuration bits must be chosen such that the resulting system frequencies,
CPU (core) frequency, and G2_LE PLL (VCO) frequency do not exceed their respective maximum or minimum operating frequencies.
This represents total input jitter - short term and long term combined - and is guaranteed by design. Two different types
of jitter can exist on the input to core_sysclk, systemic and true random jitter. True random jitter is rejected, but the PLL.
Systemic jitter will be passed into and through the PLL to the internal clock circuitry, directly reducing the operating frequency.
Relock time is guaranteed by design and characterization. PLL-relock time is the maximum amount of time required for
the PLL lock after a stable Vdd and core_sysclk are reached during the power-on reset sequence. This specification
also applies when the PLL has been disabled and subsequently re-enabled during sleep modes.
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Electrical and Thermal Characteristics
3.3
AC Electrical Characteristics
Freescale Semiconductor, Inc...
Hyperlinks to the indicated timing specification sections are provided below.
•
AC Operating Frequency Data
•
USB
•
Clock AC Specifications
•
SPI
•
Resets
•
MSCAN
•
External Interrupts
•
I2C
•
SDRAM
•
J1850
•
PCI
•
PSC
•
Local Plus Bus
•
GPIOs and Timers
•
ATA
•
IEEE 1149.1 (JTAG) AC Specifications
•
Ethernet
AC Test Timing Conditions:
Unless otherwise noted, all test conditions are as follows:
•
TA = -40 to 85 oC
•
Tj = -40 to 115 oC
•
VDD_CORE = 1.42 to 1.58 V
VDD_IO = 3.0 to 3.6 V
•
Input conditions:
All Inputs: tr, tf <= TBD
•
Output Loading:
All Outputs: 50 pF
3.3.1 AC Operating Frequency Data
Table 12 provides the operating frequency information for the MPC5200.
Table 12 Clock Frequencies
Min
Max
Units
SpecID
1
G2_LE Processor Core
—
400
MHz
A1.1
2
SDRAM Clock
—
133
MHz
A1.2
3
XL Bus Clock
—
133
MHz
A1.3
4
IP Bus Clock
—
133
MHz
A1.4
5
PCI / Local Plus Bus Clock
—
66
MHz
A1.5
6
PLL Input Range
15.6
35
MHz
A1.6
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3.3.2 Clock AC Specifications
t CYCLE
t DUTY
t DUTY
t FALL
t RISE
CV IH
SYSCLK
VM
VM
VM
CV IL
Figure 2 Timing Diagram—SYS_XTAL_IN
Table 13 SYS_XTAL_IN Timing
Freescale Semiconductor, Inc...
Sym
t CYCLE
SYS_XTAL_IN cycle time. 1
Min
Max
Units SpecID
28.6
64.1
ns
A2.1
t RISE
SYS_XTAL_IN rise time.
—
5.0
ns
A2.2
t FALL
SYS_XTAL_IN fall time.
—
5.0
ns
A2.3
t DUTY
SYS_XTAL_IN duty cycle (measured at V M ). 2
40.0
60.0
%
A2.4
CV IH
SYS_XTAL_IN input voltage high
2.0
—
V
A2.5
CV IL
SYS_XTAL_IN input voltage low
—
0.8
V
A2.6
1
2
16
Description
CAUTION—The SYS_XTAL_IN frequency and system PLL_CFG[0-6] settings must be chosen such that the resulting
system frequencies do not exceed their respective maximum or minimum operating frequencies. See the MPC5200
User Manual [1].
SYS_XTAL_IN duty cycle is measured at V M.
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Electrical and Thermal Characteristics
3.3.3 Resets
The MPC5200 has three reset pins:
•
PORESET - Power on Reset
•
HRESET - Hard Reset
•
SRESET - Software Reset
These signals are asynchronous I/O signals and can be asserted at any time. The input side uses a
Schmitt trigger and requires the same input characteristics as other MPC5200 inputs, as specified in the
DC Electrical Specifications section. Table 14 specifies the pulse widths of the Reset inputs.
Table 14 Reset Pulse Width
Max Pulse
Width
Reference Clock
SpecID
Power On Reset tVDD_stable+tup_osc+tlock
—
SYS_XTAL_IN
A3.1
HRESET
Hardware Reset
4 clock cycles
—
SYS_XTAL_IN
A3.2
SRESET
Software Reset
4 clock cycles
—
SYS_XTAL_IN
A3.3
Freescale Semiconductor, Inc...
Name
PORESET
Description
Min Pulse Width
Notes:
1. For PORESET the value of the minimum pulse width reflects the power on sequence. If PORESET is asserted afterwards its minimum pulse width equals the minimum given for HRESET related to the same reference clock.
2. The tVDD_stable describes the time which is needed to get all power supplies stable.
3. For tlock, refer to the Oscillator/PLL section of this specification for further details.
4. For tup_osc, refer to the Oscillator/PLL section of this specification for further details.
5. Following the deassertion of PORESET, HRESET and SRESET remain low for 4096 reference clock cycles.
6. The deassertion of HRESET for at least the minimum pulse width forces the internal resets to be active for an additional
4096 clock cycles.
NOTE:
As long as VDD is not stable the HRESET output is not stable.
Table 15 Reset Rise / Fall Timing
Description
Min
Max
Unit
SpecID
PORESET fall time
—
1
ms
A3.4
PORESET rise time
—
1
ms
A3.5
HRESET fall time
—
TBD
ns
A3.6
HRESET rise time
—
TBD
ns
A3.7
SRESET fall time
—
TBD
ns
A3.8
SRESET rise time
—
TBD
ns
A3.9
For additional information, see the MPC5200 User Manual [1].
NOTE:
Make sure that the PORESET does not carry any glitches. The MPC5200
has no filter to prevent them from getting into the chip.
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3.3.3.1
Reset Configuration Word
During reset (HRESET and PORESET) the Reset Configuration Word is cached in the related Reset
Configuration Word Register with each rising edge of the SYS_XTAL signal. If both resets (HRESET and
PORESET) are inactive (high), the contents of this register get locked after two further SYS_XTAL cycles
(see Figure 3).
4096 clocks
2 clocks
SYS_XTAL
PORESET
Freescale Semiconductor, Inc...
HRESET
RST_CFG_WRD
sample
sample
sample
sample
sample
sample
sample
sample
sample
sample
sample
sample
LOCK
Figure 3 Reset Configuration Word Locking
NOTE:
Beware of changing the values on the pins of the reset configuration word
after the deassertion of PORESET. This may cause problems because it
may change the internal clock ratios and so extend the PLL locking
process.
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3.3.4 External Interrupts
The MPC5200 provides three different kinds of external interrupts:
•
Four IRQ interrupts
•
Eight GPIO interrupts with simple interrupt capability (not available in power-down mode)
•
Eight WakeUp interrupts (special GPIO pins)
The propagation of these three kinds of interrupts to the core is shown in the following graphic:
IRQ0
8 GPIOs
cint
8
Encoder
GPIO Std
core_cint
core_int
Freescale Semiconductor, Inc...
int
8 GPIOs
8
GPIO WakeUp
Grouper
Encoder
IRQ1
IRQ2
G2_LE Core
PIs
Main Interrupt
Controller
IRQ3
Notes:
1. PIs = Programmable Inputs
2. Grouper and Encoder functions imply programmability in software
Figure 4 External interrupt scheme
Due to synchronization, prioritization, and mapping of external interrupt sources, the propagation of
external interrupts to the core processor is delayed by several IP_CLK clock cycles. The following table
specifies the interrupt latencies in IP_CLK cycles. The IP_CLK frequency is programmable in the Clock
Distribution Module (see Note Table 16).
Table 16 External interrupt latencies
Interrupt Type
Interrupt Requests
MOTOROLA
Pin Name
Clock Cycles Reference Clock
Core Interrupt
SpecID
IRQ0
10
IP_CLK
critical (cint)
A4.1
IRQ0
10
IP_CLK
normal (int)
A4.2
IRQ1
10
IP_CLK
normal (int)
A4.3
IRQ2
10
IP_CLK
normal (int)
A4.5
IRQ3
10
IP_CLK
normal (int)
A4.6
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Table 16 External interrupt latencies (continued)
Freescale Semiconductor, Inc...
Interrupt Type
Pin Name
Clock Cycles Reference Clock
Core Interrupt
SpecID
Standard GPIO Interrupts GPIO_PSC3_4
12
IP_CLK
normal (int)
A4.7
GPIO_PSC3_5
12
IP_CLK
normal (int)
A4.8
GPIO_PSC3_8
12
IP_CLK
normal (int)
A4.9
GPIO_USB_9
12
IP_CLK
normal (int)
A4.10
GPIO_ETHI_4
12
IP_CLK
normal (int)
A4.11
GPIO_ETHI_5
12
IP_CLK
normal (int)
A4.12
GPIO_ETHI_6
12
IP_CLK
normal (int)
A4.13
GPIO_ETHI_7
12
IP_CLK
normal (int)
A4.14
GPIO WakeUp Interrupts GPIO_PSC1_4
12
IP_CLK
normal (int)
A4.15
GPIO_PSC2_4
12
IP_CLK
normal (int)
A4.16
GPIO_PSC3_9
12
IP_CLK
normal (int)
A4.17
GPIO_ETHI_8
12
IP_CLK
normal (int)
A4.18
GPIO_IRDA_0
12
IP_CLK
normal (int)
A4.19
DGP_IN0
12
IP_CLK
normal (int)
A4.20
DGP_IN1
12
IP_CLK
normal (int)
A4.21
Notes:
1) The frequency of IP_CLK depends on register settings in Clock Distribution Module. See the MPC5200 User Manual [1].
2) The interrupt latency descriptions in the table above are related to non competitive, non masked but enabled external
interrupt sources. Take care of interrupt prioritization which may increase the latencies.
Since all external interrupt signals are synchronized into the internal processor bus clock domain, each of
these signals has to exceed a minimum pulse width of more than one IP_CLK cycle.
Table 17 Minimum pulse width for external interrupts to be recognized
Name
Min Pulse Width Max Pulse Width Reference Clock SpecID
All external interrupts (IRQs, GPIOs)
> 1 clock cycle
—
IP_CLK
A4.22
Notes:
1) The frequency of the IP_CLK depends on the register settings in Clock Distribution Module. See the MPC5200 User
Manual [1] for further information.
2) If the same interrupt occurs a second time while its interrupt service routine has not cleared the former one, the second
interrupt will not be recognized at all.
Besides synchronization, prioritization, and mapping the latency of an external interrupt to the start of its
associated interrupt service routine also depends on the following conditions: To get a minimum interrupt
service response time, it is recommended to enable the instruction cache and set up the maximum core
clock, XL bus, and IP bus frequencies (depending on board design and programming). In addition, it is
advisable to execute an interrupt handler, which has been implemented in assembly code.
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Electrical and Thermal Characteristics
3.3.5 SDRAM
3.3.5.4
Memory Interface Timing-Standard SDRAM Read Command
Table 18 Standard SDRAM Memory Read Timing
Sym
Description
Freescale Semiconductor, Inc...
tmem_clk MEM_CLK period
Min
Max
Units SpecID
7.5
—
ns
A5.1
tvalid
Control Signals, Address and MBA Valid
after rising edge of MEM_CLK
—
tmem_clk*0.5+0.4
ns
A5.2
thold
Control Signals, Address and MBA Hold
after rising edge of MEM_CLK
tmem_clk*0.5
—
ns
A5.3
—
tmem_clk*0.25+0.4
ns
A5.4
—
ns
A5.5
DMvalid
DQM valid after rising edge of
MEM_CLK
DMhold
DQM hold after rising edge of MEM_CLK tmem_clk*0.25-0.7
datasetup MDQ setup to rising edge of MEM_CLK
—
0.3
ns
A5.6
datahold MDQ hold after rising edge of MEM_CLK
0.2
—
ns
A5.7
MEM_CLK
tvalid
thold
Active
Control Signals
NOP
READ
DMvalid
NOP
NOP
NOP
NOP
NOP
DMhold
DQM (Data Mask)
datasetup
datahold
MDQ (Data)
tvalid
thold
Row
MA (Address)
tvalid
Column
thold
MBA (Bank Selects)
NOTE: Control Signals are composed of RAS, CAS, MEM_WE, MEM_CS, MEM_CS1 and CLK_EN
Figure 5 Timing Diagram—Standard SDRAM Memory Read Timing
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3.3.5.5
Memory Interface Timing-Standard SDRAM Write Command
In Standard SDRAM, all signals are activated on the Mem_clk from the Memory Controller and captured on
the Mem_clk clock at the memory device.
Table 19 Standard SDRAM Write Timing
Sym
Description
Min
Max
MEM_CLK period
7.5
—
ns
A5.8
tvalid
Control Signals, Address and MBA
Valid after rising edge of MEM_CLK
—
tmem_clk*0.5+0.4
ns
A5.9
thold
Control Signals, Address and MBA
Hold after rising edge of MEM_CLK
tmem_clk*0.5
—
ns
A5.10
—
tmem_clk*0.25+0.4
ns
A5.11
—
ns
A5.12
Freescale Semiconductor, Inc...
tmem_clk
Units SpecID
DMvalid
DQM valid after rising edge of
MEM_CLK
DMhold
DQM hold after rising edge of Mem_clk tmem_clk*0.25-0.7
datavalid
MDQ valid after rising edge of
MEM_CLK
—
tmem_clk*0.75+0.4
ns
A5.13
datahold
MDQ hold after rising edge of
MEM_CLK
tmem_clk*0.75-0.7
—
ns
A5.14
MEM_CLK
tvalid
thold
Active
Control Signals
NOP
WRITE
NOP
NOP
NOP
NOP
NOP
DMhold
DMvalid
DQM (Data Mask)
datavalid
datahold
MDQ (Data)
tvalid
thold
Row
MA (Address)
tvalid
Column
thold
MBA (Bank Selects)
NOTE: Control Signals are composed of RAS, CAS, MEM_WE, MEM_CS, MEM_CS1 and CLK_EN
Figure 6 Timing Diagram—Standard SDRAM Memory Write Timing
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Electrical and Thermal Characteristics
3.3.5.6
Memory Interface Timing-DDR SDRAM Read Command
The SDRAM Memory Controller uses an internally skewed clock for reading DDR memory. The
programmable bits in the Reset Configuration Register used to account for unknown board delays are in
the CDM module. The internal read clock can be delayed up to 3 ns under worst operating conditions in 32
increments of 95 ps, (1.4 ns in 45 ps increments under best case operating conditions) by programming
the CDM Reset Configuration Register tap delay bits. Note: These bits in the CDM Reset Configuration
register are not ‘reset configured’ but have a hard coded reset value and are writable during operation.
Table 20 DDR SDRAM Memory Read Timing
Sym
Description
Min
Max
MEM_CLK period
7.5
—
ns
A5.15
tvalid
Control Signals, Address and MBA
valid after rising edge of MEM_CLK
—
tmem_clk*0.5+0.4
ns
A5.16
thold
Control Signals, Address and MBA
hold after rising edge of MEM_CLK
tmem_clk*0.5
—
ns
A5.17
—
0.4
ns
A5.18
2.34
—
ns
A5.19
Freescale Semiconductor, Inc...
tmem_clk
datasetup Setup time skewed by CDM Reset
Config Reg [3:7] = 0b00010
datahold
Hold time skewed by CDM Reset Config Reg [3:7] = 0b00010
Units SpecID
MEM_CLK
MEM_CLK
tvalid
thold
Active
Control Signals
NOP
READ
NOP
NOP
NOP
NOP
NOP
MDQS (Data Strobe)
datasetup
datahold
MDQ (Data)
tvalid
thold
Row
MA (Address)
tvalid
Column
thold
MBA (Bank Selects)
NOTE: Control Signals signals are composed of RAS, CAS, MEM_WE, MEM_CS, MEM_CS1 and CLK_EN
Figure 7 Timing Diagram—DDR SDRAM Memory Read Timing
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3.3.5.7
Memory Interface Timing-DDR SDRAM Write Command
Table 21 DDR SDRAM Memory Write Timing
Sym
tmem_clk
Freescale Semiconductor, Inc...
tDQSS
Description
Min
Max
Units SpecID
MEM_CLK period
7.5
—
ns
A5.20
Delay from write command to first rising
edge of MDQS
—
tmem_clk+0.4
ns
A5.21
MEM_CLK
MEM_CLK
Control Signals
Write
Write
Write
Write
MDQS (Data Strobe)
tdqss
MDQ (Data)
NOTE: Control Signals signals are composed of RAS, CAS, MEM_WE, MEM_CS, MEM_CS1 and CLK_EN
Figure 8 DDR SDRAM Memory Write Timing
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Electrical and Thermal Characteristics
3.3.6 PCI
The PCI interface on the MPC5200 is designed to PCI Version 2.2 and supports 33-MHz and 66-MHz PCI
operations. See the PCI Local Bus Specification [4]; the component section specifies the electrical and
timing parameters for PCI components with the intent that components connect directly together whether
on the planar or an expansion board, without any external buffers or other “glue logic.” Parameters apply at
the package pins, not at expansion board edge connectors.
The MPC5200 is always the source of the PCI CLK. The clock waveform must be delivered to each
33-MHz or 66-MHz PCI component in the system. Figure 9 shows the clock waveform and required
measurement points for 3.3 V signaling environments. Table 22 summarizes the clock specifications.
Freescale Semiconductor, Inc...
Tcyc
0.5Vcc
0.4Vcc
PCI CLK
0.3Vcc
T high
0.6Vcc
T low
0.4Vcc, p-to-p
(minimum)
0.2Vcc
Figure 9 PCI CLK Waveform
Table 22 PCI CLK Specifications
66 MHz
Sym
33 MHz
Description
Units
Notes
SpecID
30
ns
1,3
A6.1
11
ns
Min
Max
Min
30
Tcyc
PCI CLK Cycle Time
15
Thigh
PCI CLK High Time
6
t low
PCI CLK Low Time
6
-
PCI CLK Slew Rate
1.5
Max
A6.2
A6.3
4
1
4
V/ns
2
A6.4
NOTES:
1. In general, all 66-MHz PCI components must work with any clock frequency up to 66 MHz. CLK requirements vary depending upon whether the clock frequency is above 33 MHz.
2. Rise and fall times are specified in terms of the edge rate measured in V/ns. This slew rate must be met across the
minimum peak-to-peak portion of the clock waveform as shown in Figure 9.
3. The minimum clock period must not be violated for any single clock cycle, i.e., accounting for all system jitter.
Table 23 PCI Timing Parameters
66 MHz
Sym
33 MHz
Description
Units
Notes
SpecID
11
ns
1,2,3
A6.5
12
ns
1,2,3
A6.6
ns
1
A6.7
ns
1
A6.8
Min
Max
Min
Max
CLK to Signal Valid Delay bused signals
2
6
2
Tval(ptp) CLK to Signal Valid Delay point to point
2
6
2
Tval
T on
Float to Active Delay
T off
Active to Float Delay
MOTOROLA
2
2
14
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Table 23 PCI Timing Parameters (continued)
66 MHz
Sym
Min
T su
Max
Min
Units
Notes
SpecID
Max
Input Setup Time to CLK bused signals
3
7
ns
3,4
A6.9
T su(ptp) Input Setup Time to CLK point to point
5
10,12
ns
3,4
A6.10
Input Hold Time from CLK
0
0
ns
4
A6.11
Th
Freescale Semiconductor, Inc...
33 MHz
Description
NOTES:
1. See the timing measurement conditions in the PCI Local Bus Specification [4]. It is important that all driven signal transitions drive to their Voh or Vol level within one Tcyc.
2. Minimum times are measured at the package pin with the load circuit, and maximum times are measured with the load
circuit as shown in the PCI Local Bus Specification [4].
3. REQ# and GNT# are point-to-point signals and have different input setup times than do bused signals. GNT# and REQ#
have a setup of 5 ns at 66 MHz. All other signals are bused.
4. See the timing measurement conditions in the PCI Local Bus Specification [4].
For Measurement and Test Conditions, see the PCI Local Bus Specification [4].
3.3.7 Local Plus Bus
The Local Plus Bus is the external bus interface of the MPC5200. Eight configurable Chip-selects are
provided. There are two main modes of operation: non-MUXed and MUXED. The reference clock is the
PCI CLK. Refer to PCI CLK specification. The maximum bus frequency is 66 MHz.
The following timing numbers indicate when data will be latched or driven onto the external bus, relative to
the PCI CLK.
PCI CLK
2
3
1
OUTPUT
SIGNALS
1 PCI CLK to Signal hold
2 PCI CLK to Signal valid
3 PCI CLK to Signal Hi Z
Figure 10 Output Signals Timing
3.3.7.1
Non-MUXed Mode
Table 24 Non-MUXed Mode Timing
Sym
26
Description
Min
Max
Units
Notes SpecID
t AV
PCI CLK to ADDR valid
-
2
ns
A7.1
t AH
PCI CLK to ADDR hold
1
-
ns
A7.2
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Electrical and Thermal Characteristics
Table 24 Non-MUXed Mode Timing (continued)
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units
Notes SpecID
t DV
PCI CLK to DATA output valid
-
2
ns
A7.3
t DZ
PCI CLK to DATA output Hi Z
-
2
ns
A7.4
t CSA
PCI CLK to CS assertion
-
1.8
ns
A7.5
t CSN
PCI CLK to CS negation
-
1.8
ns
A7.6
t OEA
PCI CLK to OE assertion
-
1.5
ns
A7.7
t OEN
PCI CLK to OE negation
-
1.5
ns
A7.8
t RWV
PCI CLK to RW valid
-
1
ns
A7.9
t RWH
PCI CLK to RW hold
1
-
ns
A7.10
t TSIZV
PCI CLK to TSIZ valid
-
2
ns
A7.11
t TSIZH
PCI CLK to TSIZ hold
1
-
ns
A7.12
t DS
DATA input to PCI CLK setup
2
-
ns
A7.13
t DH
DATA input to PCI CLK hold
-
1
ns
A7.14
NOTES:
1. Wait states for Reads and Writes can be specified as 0 to 127.
2. Dead cycles can be specified as 0 to 3. Dead cycles will be added to the end of Chip Select read access and will occur
in addition to any cycles which may already exist. These cycles provide a peripheral additional time to tri-state its bus
after a read operation. This is for all access types.
3. Transfer Size TSIZE(1:0) are available in Non-MUXed mode for MOST Graphics or Large Flash Modes only.
For understanding the different hold/valid/assertion/negation times refer to Figure 10.
The timing values in the above table are for a clock ratio of IP_CLK : PCI_CLK = 1 : 1 only.
The values will be different for other IP_CLK : PCI_CLK clock ratios.
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Electrical and Thermal Characteristics
PCI_CLK
Valid Address
ADDR
t
RD
or t
WR
CS[x]
R/W
Freescale Semiconductor, Inc...
DATA (wr)
Valid Write Data
DATA (rd)
t
Valid Read Data
OE
OE
Note: 1. The t RD /t WR is wait states as programmed for corresponding access and chip select.
2. OE is active during Read only, t OE is the Output Enable to Output Delay time
3. Read data has nominal setup/hold requirements around the CS negation.
Figure 11 Timing Diagram—Non-MUXed Mode
3.3.7.2
MUXed Mode
Table 25 MUXed Mode Timing
Sym
Min
Max
Units
Notes SpecID
t AV
PCI CLK to ADDR valid
-
2
ns
A7.15
t AH
PCI CLK to ADDR hold
1
-
ns
A7.16
t DV
PCI CLK to DATA output valid
-
2
ns
A7.17
t DZ
PCI CLK to DATA output Hi Z
-
2
ns
A7.18
t CSA
PCI CLK to CS assertion
-
1.8
ns
A7.19
t CSN
PCI CLK to CS negation
-
1.8
ns
A7.20
t OEA
PCI CLK to OE assertion
-
1.5
ns
A7.21
t OEN
PCI CLK to OE negation
-
1.5
ns
A7.22
t RWV
PCI CLK to RW valid
-
1
ns
A7.23
t RWH
PCI CLK to RW hold
1
-
ns
A7.24
t ALEA
PCI CLK to ALE assertion
-
2
ns
A7.25
t ALEN
PCI CLK to ALE negation
-
2
ns
A7.26
DATA input to PCI CLK setup
2
-
ns
A7.27
t DS
28
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Table 25 MUXed Mode Timing (continued)
Sym
t DH
Description
DATA input to PCI CLK hold
Min
Max
Units
-
1
ns
Notes SpecID
A7.28
Freescale Semiconductor, Inc...
NOTES:
1. Wait states for Reads and Writes can be inserted when configured.
2. Dead cycles can be specified as 0 to 3. Dead cycles will be added to the end of Chip Select read access and will occur
in addition to any cycles which may already exist. These cycles provide a peripheral additional time to tri-state its bus
after a read operation. This is for all access types.
3. Transfer Size TSIZE(1:0) are available in Non-MUXed mode for MOST Graphics or Large Flash Modes only.
For understanding the different hold/valid/assertion/negation times refer to Figure 10.
The timing values in the above table are for a clock ratio of IP_CLK : PCI_CLK = 1 : 1 only.
The values will be different for other IP_CLK : PCI_CLK clock ratios.
Start Bus Tenure
End Bus Tenure
PCI CLK
AD[31,27]
Data or tri-state
tri-state
AD[30:28]
TSIZ[0:2] bits
Data or tri-state
tri-state
AD[26:25]
Bank[0:1] bits
Data or tri-state
tri-state
AD[24:0]
Address[7:31]
Data or tri-state
tri-state
ALE
long short
TS
short long
Wait States Dead Cycles
(0-3)
(0-127)
CSx
RW
ACK Input
Address "tenure"
Data "tenure"
"Dack"
Figure 12 Timing Diagram - MUXed Mode
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3.3.8 ATA
The MPC5200 ATA Controller is completely software programmable. It can be programmed to operate with
ATA protocols using their respective timing, as described in the ANSI ATA-4 specification. The ATA
interface is completely asynchronous in nature. Signal relationships are based on specific fixed timing in
terms of timing units (nano seconds).
ATA data setup and hold times, with respect to Read/Write strobes, are software programmable inside the
ATA Controller. Data setup and hold times are implemented using counters. The counters count the
number of ATA clock cycles needed to meet the ANSI ATA-4 timing specifications. For details, see the
ANSI ATA-4 specification [5] and how to program an ATA Controller and ATA drive for different ATA
protocols and their respective timing. See the MPC5200 User Manual [1].
Freescale Semiconductor, Inc...
The MPC5200 ATA Host Controller design makes data available coincidentally with the active edge of the
WRITE strobe in PIO and Multiword DMA modes.
•
Write data is latched by the drive at the inactive edge of the WRITE strobe. This gives ample
setup-time beyond that required by the ATA-4 specification.
•
Data is held unchanged until the next active edge of the WRITE strobe. This gives ample hold-time
beyond that required by the ATA-4 specification.
All ATA transfers are programmed in terms of system clock cycles (IP bus clocks) in the ATA Host
Controller timing registers. This puts constraints on the ATA protocols and their respective timing modes in
which the ATA Controller can communicate with the drive.
Faster ATA modes (i.e., UDMA 0, 1, 2) are supported when the system is running at a sufficient frequency
to provide adequate data transfer rates. Adequate data transfer rates are a function of the following:
•
The MPC5200 operating frequency (IP bus clock frequency)
•
Internal MPC5200 bus latencies
•
Other system load dependent variables
The ATA clock is the same frequency as the IP bus clock in MPC5200. See the MPC5200 User Manual [1].
NOTE:
All output timing numbers are specified for nominal 50 pF loads.
Table 26 PIO Mode Timing Specifications
Min/Ma
Mode 0 Mode 1 Mode 2 Mode 3 Mode 4
x
SpecID
(ns)
(ns)
(ns)
(ns)
(ns)
(ns)
PIO Timing Parameter
t0
Cycle Time
min
600
383
240
180
120
A8.1
t1
Address valid to DIOR/DIOW
setup
min
70
50
30
30
25
A8.2
t2
DIOR/DIOW pulse width 16-bit
8-bit
min
min
165
290
125
290
100
290
80
80
70
70
A8.3
t2i
DIOR/DIOW recovery time
min
—
—
—
70
25
A8.4
t3
DIOW data setup
min
60
45
30
30
20
A8.5
t4
DIOW data hold
min
30
20
15
10
10
A8.6
t5
DIOR data setup
min
50
35
20
20
20
A8.7
t6
DIOR data hold
min
5
5
5
5
5
A8.8
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Table 26 PIO Mode Timing Specifications (continued)
Min/Ma
Mode 0 Mode 1 Mode 2 Mode 3 Mode 4
x
SpecID
(ns)
(ns)
(ns)
(ns)
(ns)
(ns)
PIO Timing Parameter
t9
IOR/DIOW to address
valid hold
min
20
15
10
10
10
A8.9
tA
IORDY setup
max
35
35
35
35
35
A8.10
tB
IORDY pulse width
max
1250
1250
1250
1250
1250
A8.11
CS[0]/CS[3]/DA[2:0]
Freescale Semiconductor, Inc...
t2
t9
t1
t8
t0
DIOR/DIOW
t3
t4
WDATA
t5
t6
RDATA
tA
tB
IORDY
Figure 13 PIO Mode Timing
Table 27 Multiword DMA Timing Specifications
Multiword DMA Timing Parameters Min/Max Mode 0(ns) Mode 1(ns) Mode 2(ns) SpecID
t0
Cycle Time
min
480
150
120
A8.12
tC
DMACK to DMARQ delay
max
—
—
—
A8.13
tD
DIOR/DIOW pulse width (16-bit)
min
215
80
70
A8.14
tE
DIOR data access
max
150
60
50
A8.15
tG
DIOR/DIOW data setup
min
100
30
20
A8.16
tF
DIOR data hold
min
5
5
5
A8.17
tH
DIOW data hold
min
20
15
10
A8.18
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Table 27 Multiword DMA Timing Specifications (continued)
Multiword DMA Timing Parameters Min/Max Mode 0(ns) Mode 1(ns) Mode 2(ns) SpecID
tI
DMACK to DIOR/DIOW setup
min
0
0
0
A8.19
tJ
DIOR/DIOW to DMACK hold
min
20
5
5
A8.20
tKr
DIOR negated pulse width
min
50
50
25
A8.21
tKw DIOW negated pulse width
min
215
50
25
A8.22
tLr
DIOR to DMARQ delay
max
120
40
35
A8.23
tLw
DIOW to DMARQ delay
max
40
40
35
A8.24
Freescale Semiconductor, Inc...
t0
DMARQ
(Drive)
tL
tC
DMACK
(Host)
tI
tD
tJ
tK
DIOR
DIOW
(Host)
tE
RDATA
(Drive)
tS
tF
WDATA
(Host)
tG
tH
NOTE: The directionof signalassertionis towardsthe
top of the page, and the direction of negation is
towards the bottom of the page, irrespective of the
electrical properties of the signal.
Figure 14 Multiword DMA Timing
Table 28 Ultra DMA Timing Specification
Name
(t) 2CYC
32
MODE 0
(ns)
MODE 1
(ns)
MODE 2
(ns)
Min
Max
Min
Max
Min
Max
240
—
160
—
120
—
Comment
Typical sustained average two cycle time.
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SpecID
A8.25
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Table 28 Ultra DMA Timing Specification (continued)
Freescale Semiconductor, Inc...
Name
MODE 0
(ns)
MODE 1
(ns)
MODE 2
(ns)
Comment
SpecID
Min
Max
Min
Max
Min
Max
(t) CYC
114
—
75
—
55
—
Cycle time allowing for asymmetry and clock
variations from STROBE edge to STROBE
edge
A8.26
(t) 2CYC
235
—
156
—
117
—
Two-cycle time allowing for clock variations,
from rising edge to next rising edge or from falling edge to next falling edge of STROBE.
A8.27
(t) DS
15
—
10
—
7
—
Data setup time at recipient.
A8.28
(t) DH
5
—
5
—
5
—
Data hold time at recipient.
A8.29
(t) DVS
70
—
48
—
34
—
Data valid setup time at sender, to STROBE
edge.
A8.30
(t) DVH
6
—
6
—
6
—
Data valid hold time at sender, from STROBE
edge.
A8.31
(t) FS
0
230
0
200
0
170 First STROBE time for drive to first negate
DSTROBE from STOP during a data-in burst.
A8.32
(t) LI
0
150
0
150
0
150 Limited Interlock time. 1
A8.33
(t) MLI
20
—
20
—
20
—
Interlock time with minimum.1 2
A8.34
(t) UI
0
—
0
—
0
—
Unlimited interlock time. 1 2
A8.35
(t) AZ
—
10
—
10
—
10
Maximum time allowed for output drivers to
release from being asserted or negated
A8.36
(t) ZAH
20
—
20
—
20
—
A8.37
(t) ZAD
0
—
0
—
0
—
Minimum delay time required for output drivers
to assert or negate from released state
(t) ENV
20
70
20
70
20
70
Envelope time—from DMACK to STOP and
HDMARDY during data out burst initiation.
A8.39
(t) SR
—
50
—
30
—
20
STROBE to DMARDY time, if DMARDY is
negated before this long after STROBE edge,
the recipient receives no more than one additional data word.
A8.40
(t) RFS
—
75
—
60
—
50
Ready-to-Final STROBE time—no STROBE
edges are sent this long after negation of
DMARDY.
A8.41
(t) RP
160
—
125
—
100
—
Ready-to-Pause time—the time recipient waits
to initiate pause after negating DMARDY.
A8.42
(t) IORDYZ
—
20
—
20
—
20
Pull-up time before allowing IORDY to be
released.
A8.43
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Table 28 Ultra DMA Timing Specification (continued)
MODE 0
(ns)
Name
MODE 1
(ns)
MODE 2
(ns)
Comment
SpecID
Max
Min
Max
Min
Max
(t) ZIORDY
0
—
0
—
0
—
Minimum time drive waits before driving
IORDY
A8.44
(t) ACK
20
—
20
—
20
—
Setup and hold times for DMACK, before
assertion or negation.
A8.45
(t) SS
50
—
50
—
50
—
Time from STROBE edge to negation of
DMARQ or assertion of STOP, when sender
terminates a burst.
A8.46
Freescale Semiconductor, Inc...
Min
1
2
t UI, t MLI, t LI indicate sender-to-recipient or recipient-to-sender interlocks. That is, one agent (either sender or recipient) is
waiting for the other agent to respond with a signal before proceeding.
• t UI is an unlimited interlock that has no maximum time value.
• t MLI is a limited time-out that has a defined minimum.
• t LI is a limited time-out that has a defined maximum.
All timing parameters are measured at the connector of the drive to which the parameter applies. For example, the sender
shall stop generating STROBE edges t RFS after negation of DMARDY. Both STROBE and DMARDY timing measurements are taken at the connector of the sender. Even though the sender stops generating STROBE edges, the receiver
may receive additional STROBE edges due to propagation delays. All timing measurement switching points (low to high
and high to low) are taken at 1.5 V.
DMARQ
(device)
t UI
DMACK
(device)
t ACK
t ENV
t FS
t ZAD
STOP
(host)
t ACK
t ENV
t FS
HDMARDY
(host)
t ZIORDY
t ZAD
DSTROBE
(device)
t AZ
t DVS
t DVH
DD(0:15)
t ACK
DA0, DA1, DA2,
CS[0:1]1
Figure 15 Timing Diagram—Initiating an Ultra DMA Data In Burst
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t 2CYC
t CYC
t CYC
t 2CYC
DSTROBE
at device
tDVH
tDVS
tDVH
tDVS
tDVH
DD(0:15)
at device
Freescale Semiconductor, Inc...
DSTROBE
at host
tDH
tDS
tDH
tDS
tDH
DD(0:15)
at host
Figure 16 Timing Diagram—Sustained Ultra DMA Data In Burst
DMARQ
(device)
DMARQ
(host)
t RP
STOP
(host)
t SR
HDMARDY
(host)
t RFS
DSTROBE
(device)
DD[0:15]
(device)
Figure 17 Timing Diagram—Host Pausing an Ultra DMA Data In Burst
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DMARQ
(device)
DMACK
(host)
t LI
t MLI
t LI
t ACK
STOP
(host)
tLI
t ACK
HDMARDY
(host)
t SS
Freescale Semiconductor, Inc...
DSTROBE
(device)
t IORDYZ
t ZAH
t DVS
t AZ
t DVH
CRC
DD[0:15]
t ACK
DA0,DA1,DA2,
CS[0:1]
Figure 18 Timing Diagram—Drive Terminating Ultra DMA Data In Burst
DMARQ
(device)
t MLI
t LI
DMACK
(host)
t RP
t ZAH
t ACK
STOP
(host)
tACK
t AZ
HDMARDY
(host)
t RFS
t LI
t MLI
DSTROBE
(device)
t IORDYZ
t DVS
t DVH
DD[0:15]
CRC
t ACK
DA0,DA1,DA2,
CS[0:1]
Figure 19 Timing Diagram—Host Terminating Ultra DMA Data In Burst
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DMARQ
(device)
tUI
DMACK
(host)
tACK
tENV
STOP
(host)
tLI
tZIORDY
tUI
Freescale Semiconductor, Inc...
DDMARDY
(host)
tACK
HSTROBE
(device)
tDVS
tDVH
DD[0:15]
(host)
tACK
DA0,DA1,DA2,
CS[0:1]
Figure 20 Timing Diagram—Initiating an Ultra DMA Data Out Burst
t 2CYC
t CYC
t CYC
t 2CYC
HSTROBE
(host)
t DVS
t DVH
t DVS
t DVH
t DVH
DD[0:15]
(host)
HSTROBE
(device)
t DH
t DS
t DS
t DH
t DH
DD[0:15]
(device)
Figure 21 Timing Diagram—Sustained Ultra DMA Data Out Burst
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t RP
DMARQ
(device)
DMACK
(host)
STOP
(host)
t SR
DDMARDY
(device)
t RFS
Freescale Semiconductor, Inc...
HSTROBE
DD[0:15]
(host)
Figure 22 Timing Diagram—Drive Pausing an Ultra DMA Data Out Burst
DMARQ
(device)
t LI
t MLI
DMACK
(host)
t SS
t ACK
t LI
STOP
(host)
t LI
t IORDYZ
DDMARDY
(device)
tACK
HSTROBE
(host)
t DVS
DD[0:15]
(host)
t DVH
CRC
t ACK
DA0,DA1,DA2,
CS[0:1]
Figure 23 Timing Diagram—Host Terminating Ultra DMA Data Out Burst
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DMARQ
(device)
DMACK
(host)
t LI
t MLI
t ACK
STOP
(host)
t RP
t IORDYZ
Freescale Semiconductor, Inc...
DDMARDY
(device)
t RFS
t LI
t MLI
t ACK
HSTROBE
(host)
t DVS
DD[0:15]
(host)
t DVH
CRC
t ACK
DA0,DA1,DA2,
CS[0:1]
Figure 24 Timing Diagram—Drive Terminating Ultra DMA Data Out Burst
Table 29 Timing Specification ata_isolation
Sym
Description
Min
Max
Units
SpecID
1
ata_isolation setup time
7
-
IP Bus cycles
A8.47
2
ata_isolation hold time
19
-
IP Bus cycles
A8.48
DIOR
ATA_ISOLATION
1
2
Figure 25 Timing Diagram-ATA-ISOLATION
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Electrical and Thermal Characteristics
3.3.9 Ethernet
AC Test Timing Conditions:
•
Output Loading
All Outputs: 25 pF
Freescale Semiconductor, Inc...
Table 30 MII Rx Signal Timing
Sym
Description
Min
Max
Unit
SpecID
M1
RXD[3:0], RX_DV, RX_ER to RX_CLK setup
10
—
ns
A9.1
M2
RX_CLK to RXD[3:0], RX_DV, RX_ER hold
10
—
ns
A9.2
M3
RX_CLK pulse width high
35%
65%
RX_CLK Period 1
A9.3
M4
RX_CLK pulse width low
35%
65%
RX_CLK Period1
A9.4
1
RX_CLK shall have a frequency of 25% of data rate of the received signal. See the IEEE 802.3 Specification [6].
M3
RX_CLK (Input)
M4
RXD[3:0] (inputs)
RX_DV
RX_ER
M1
M2
Figure 26 Ethernet Timing Diagram—MII Rx Signal
Table 31 MII Tx Signal Timing
Sym
Description
Min
Max
Unit
SpecID
0
25
ns
A9.5
M5
TX_CLK rising edge to TXD[3:0], TX_EN,
TX_ER Delay
M6
TX_CLK pulse width high
35%
65%
TX_CLK Period 1
A9.6
M7
TX_CLK pulse width low
35%
65%
TX_CLK Period1
A9.7
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1
the TX_CLK frequency shall be 25% of the nominal transmit frequency, e.g., a PHY operating at 100 Mb/s must provide
a TX_CLK frequency of 25 MHz and a PHY operating at 10 Mb/s must provide a TX_CLK frequency of 2.5 MHz. See the
IEEE 802.3 Specification [6].
M6
TX_CLK (Input)
M5
M7
Freescale Semiconductor, Inc...
TXD[3:0] (Outputs)
TX_EN
TX_ER
Figure 27 Ethernet Timing Diagram—MII Tx Signal
Table 32 MII Async Signal Timing
Sym
M8
Description
CRS, COL minimum pulse width
Min
Max
Unit
SpecID
1.5
—
TX_CLK Period
A9.8
CRS, COL
M8
Figure 28 Ethernet Timing Diagram—MII Async
Table 33 MII Serial Management Channel Signal Timing
Sym
Description
Min
Max
Unit
SpecID
M9
MDC falling edge to MDIO output delay
0
25
ns
A9.9
M10
MDIO (input) to MDC rising edge setup
10
—
ns
A9.10
M11
MDIO (input) to MDC rising edge hold
10
—
ns
A9.11
M12
MDC pulse width high 1
160
—
ns
A9.12
160
—
ns
A9.13
400
—
ns
A9.14
M13
MDC pulse width
M14
MDC period 2
1
low1
MDC is generated by MPC5200 with a duty cycle of 50% except when MII_SPEED in the FEC MII_SPEED control
register is changed during operation. See the MPC5200 User Manual [1].
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2
The MDC period must be set to a value of less then or equal to 2.5 MHz (to be compliant with the IEEE MII characteristic) by programming the FEC MII_SPEED control register. See the MPC5200 User Manual [1].
M12
M13
MDC (Output)
M14
M9
MDIO (Output)
Freescale Semiconductor, Inc...
MDIO (Input)
M10 M11
Figure 29 Ethernet Timing Diagram—MII Serial Management
3.3.10 USB
Table 34 Timing Specifications—USB Output Line
Sym
Description
Min
Max
Units
SpecID
1
USB Bit width 1
83.3
667
ns
A10.1
2
Transceiver enable time
83.3
667
ns
A10.2
3
Signal falling time
—
7.9
ns
A10.3
4
Signal rising time
—
7.9
ns
A10.4
1
Defined in the USB config register, (12 Mbit/s or 1.5 Mbit/s mode).
NOTE:
Output timing was specified at a nominal 50 pF load.
42
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Electrical and Thermal Characteristics
2
USB_OE
3
4
USB_TXN
1
1
4
3
Freescale Semiconductor, Inc...
USB_TXP
Figure 30 Timing Diagram—USB Output Line
3.3.11 SPI
Table 35 Timing Specifications — SPI Master Mode, Format 0 (CPHA = 0)
Sym
Description
Min
Max
Units
SpecID
1
Cycle time
4
1024
IP-Bus
Cycle 1
A11.1
2
Clock high or low time
2
512
IP-Bus
Cycle1
A11.2
3
Slave select clock delay
15.0
—
ns
A11.3
4
Output Data valid after Slave Select (SS)
—
20.0
ns
A11.4
5
Output Data valid after SCK
—
20.0
ns
A11.5
6
Input Data setup time
20.0
—
ns
A11.6
7
Input Data hold time
20.0
—
ns
A11.7
8
Slave disable lag time
15.0
—
ns
A11.8
9
Sequential transfer delay
1
—
IP-Bus
Cycle1
A11.9
10
Clock falling time
—
7.9
ns
A11.10
11
Clock rising time
—
7.9
ns
A11.11
1
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
NOTE:
Output timing was specified at a nominal 50 pF load.
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Electrical and Thermal Characteristics
1
10
SCK
(CLKPOL=0)
Output
2
2
11
SCK
(CLKPOL=1)
Output
11
10
8
3
9
Freescale Semiconductor, Inc...
SS
Output
5
4
MOSI
Output
6
6
MISO
Input
7
7
Figure 31 Timing Diagram — SPI Master Mode, Format 0 (CPHA = 0)
Table 36 Timing Specifications — SPI Slave Mode, Format 0 (CPHA = 0)
Sym
Description
Min
Max
Units
SpecID
1
Cycle time
4
1024
IP-Bus Cycle 1
A11.12
2
Clock high or low time
2
512
IP-Bus Cycle1
A11.13
3
Slave select clock delay
15.0
—
ns
A11.14
4
Output Data valid after Slave Select (SS)
—
50.0
ns
A11.15
5
Output Data valid after SCK
—
50.0
ns
A11.16
6
Input Data setup time
50.0
—
ns
A11.17
7
Input Data hold time
0.0
—
ns
A11.18
8
Slave disable lag time
15.0
—
ns
A11.19
9
Sequential Transfer delay
1
—
IP-Bus Cycle1
A11.20
1
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
NOTE:
Output timing was specified at a nominal 50 pF load.
44
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Electrical and Thermal Characteristics
1
SCK
(CLKPOL=0)
Input
2
2
SCK
(CLKPOL=1)
Input
8
3
9
Freescale Semiconductor, Inc...
SS
Input
6
7
MOSI
Input
4
5
MISO
Output
Figure 32 Timing Diagram — SPI Slave Mode, Format 0 (CPHA = 0)
Table 37 Timing Specifications — SPI Master Mode, Format 1 (CPHA = 1)
Sym
Description
Min
Max
Units
SpecID
1
Cycle time
4
1024
IP-Bus
Cycle 1
A11.21
2
Clock high or low time
2
512
IP-Bus
Cycle1
A11.22
3
Slave select clock delay
15.0
—
ns
A11.23
4
Output data valid
—
20.0
ns
A11.24
5
Input Data setup time
20.0
—
ns
A11.25
6
Input Data hold time
20.0
—
ns
A11.26
7
Slave disable lag time
15.0
—
ns
A11.27
8
Sequential Transfer delay
1
—
IP-Bus
Cycle1
A11.28
9
Clock falling time
—
7.9
ns
A11.29
10
Clock rising time
—
7.9
ns
A11.30
1
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
NOTE:
Output timing was specified at a nominal 50 pF load.
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1
9
SCK
(CLKPOL=0)
Output
2
2
10
SCK
(CLKPOL=1)
Output
10
9
7
3
8
Freescale Semiconductor, Inc...
SS
Output
4
MOSI
Output
5
MISO
Input
6
Figure 33 Timing Diagram — SPI Master Mode, Format 1 (CPHA = 1)
Table 38 Timing Specifications — SPI Slave Mode, Format 1 (CPHA = 1)
Sym
Description
Min
Max
Units
SpecID
1
Cycle time
4
1024
IP-Bus
Cycle 1
A11.31
2
Clock high or low time
2
512
IP-Bus
Cycle1
A11.32
3
Slave select clock delay
15.0
—
ns
A11.33
4
Output data valid
—
50.0
ns
A11.34
5
Input Data setup time
50.0
—
ns
A11.35
6
Input Data hold time
0.0
—
ns
A11.36
7
Slave disable lag time
15.0
—
ns
A11.37
8
Sequential Transfer delay
1
—
IP-Bus
Cycle1
A11.38
1
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
NOTE:
Output timing was specified at a nominal 50 pF load.
46
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Electrical and Thermal Characteristics
1
SCK
(CLKPOL=0)
Input
2
2
SCK
(CLKPOL=1)
Input
7
3
8
Freescale Semiconductor, Inc...
SS
Input
5
6
MOSI
Input
4
MISO
Output
Figure 34 Timing Diagram — SPI Slave Mode, Format 1 (CPHA = 1)
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3.3.12 MSCAN
The CAN functions are available as RX and TX pins at normal IO pads (I2C1+GPTimer or PSC2). There is
no filter for the WakeUp dominant pulse. Any High-to-Low edge can cause WakeUp, if configured.
3.3.13 I2C
Table 39 I2C Input Timing Specifications—SCL and SDA
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units
SpecID
1
Start condition hold time
2
—
IP-Bus
Cycle 1
A13.1
2
Clock low period
8
—
IP-Bus
Cycle1
A13.2
4
Data hold time
0.0
—
ns
A13.3
6
Clock high time
4
—
IP-Bus
Cycle1
A13.4
7
Data setup time
0.0
—
ns
A13.5
8
Start condition setup time (for repeated start condition only)
2
—
IP-Bus
Cycle1
A13.6
9
Stop condition setup time
2
—
IP-Bus
Cycle1
A13.7
1
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
Table 40 I2C Output Timing Specifications—SCL and SDA
Sym
48
Description
Min
Max
Units
SpecID
11
Start condition hold time
6
—
IP-Bus
Cycle3
A13.8
21
Clock low period
10
—
IP-Bus
Cycle3
A13.9
32
SCL/SDA rise time
—
7.9
ns
A13.10
41
Data hold time
7
—
IP-Bus
Cycle3
A13.11
51
SCL/SDA fall time
—
7.9
ns
A13.12
61
Clock high time
10
—
IP-Bus
Cycle3
A13.13
71
Data setup time
2
—
IP-Bus
Cycle3
A13.14
81
Start condition setup time (for repeated start condition only)
20
—
IP-Bus
Cycle3
A13.15
91
Stop condition setup time
10
—
IP-Bus
Cycle 3
A13.16
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Programming IFDR with the maximum frequency (IFDR=0x20) results in the minimum output timings listed. The I2C
interface is designed to scale the data transition time, moving it to the middle of the SCL low period. The actual position is affected by the prescale and division values programmed in IFDR.
Because SCL and SDA are open-drain-type outputs, which the processor can only actively drive low, the time SCL
or SDA takes to reach a high level depends on external signal capacitance and pull-up resistor values
Inter Peripheral Clock is defined in the MPC5200 User Manual [1].
1
2
3
NOTE:
Output timing was specified at a nominal 50 pF load.
2
6
5
Freescale Semiconductor, Inc...
SCL
1
4
7
3
8
9
SDA
Figure 35 Timing Diagram—I2C Input/Output
3.3.14 J1850
See the MPC5200 User Manual [1].
3.3.15 PSC
3.3.15.1
Codec Mode (8,16,24 and 32-bit) / I2S Mode
Table 41 Timing Specifications—8,16, 24 and 32-bit CODEC / I2S Master Mode
Sym
Description
Min
Typ
Max
1
Bit Clock cycle time, programmed in CCS register
40.0
—
—
ns
A15.1
2
Clock pulse width
—
50
—
%1
A15.2
3
Bit Clock fall time
—
—
7.9
ns
A15.3
4
Bit Clock rise time
—
—
7.9
ns
A15.4
5
FrameSync valid after clock edge
—
—
8.4
ns
A15.5
6
FrameSync invalid after clock edge
—
—
8.4
ns
A15.6
7
Output Data valid after clock edge
—
—
9.3
ns
A15.7
8
Input Data setup time
6.0
—
—
ns
A15.8
1
Units SpecID
Bit Clock cycle time
NOTE:
Output timing was specified at a nominal 50 pF load.
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1
BitClk
(CLKPOL=0)
Output
3
2
2
4
BitClk
(CLKPOL=1)
Output
4
Freescale Semiconductor, Inc...
5
Frame
(SyncPol = 1)
Output
Frame
(SyncPol = 0)
Output
3
6
7
TxD
Output
8
RxD
Input
Figure 36 Timing Diagram — 8,16, 24, and 32-bit CODEC / I2S Master Mode
Table 42 Timing Specifications — 8,16, 24, and 32-bit CODEC / I2S Slave Mode
Sym
Description
Min
Typ
Max
Units SpecID
40.0
—
—
ns
A15.9
1
Bit Clock cycle time
2
Clock pulse width
—
50
—
%1
A15.10
3
FrameSync setup time
1.0
—
—
ns
A15.11
4
Output Data valid after clock edge
—
—
14.0
ns
A15.12
5
Input Data setup time
1.0
—
—
ns
A15.13
6
Input Data hold time
1.0
—
—
ns
A15.14
1
Bit Clock cycle time
NOTE:
Output timing was specified at a nominal 50 pF load.
50
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1
BitClk
(CLKPOL=0)
Input
2
2
BitClk
(CLKPOL=1)
Input
Freescale Semiconductor, Inc...
3
Frame
(SyncPol = 1)
Input
Frame
(SyncPol = 0)
Input
4
TxD
Output
5
RxD
Input
6
Figure 37 Timing Diagram — 8,16, 24, and 32-bit CODEC / I2S Slave Mode
3.3.15.2
AC97 Mode
Table 43 Timing Specifications — AC97 Mode
Sym
Description
Min
Typ
Max
Units SpecID
1
Bit Clock cycle time
—
81.4
—
ns
A15.15
2
Clock pulse high time
—
40.7
—
ns
A15.16
3
Clock pulse low time
—
40.7
—
ns
A15.17
4
Frame valid after rising clock edge
—
—
13.0
ns
A15.18
5
Output Data valid after rising clock edge
—
—
14.0
ns
A15.19
6
Input Data setup time
1.0
—
—
ns
A15.20
7
Input Data hold time
1.0
—
—
ns
A15.21
NOTE:
Output timing was specified at a nominal 50 pF load.
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1
BitClk
(CLKPOL=0)
Input
4
Sync
(SyncPol = 1)
Output
5
3
2
Sdata_out
Output
Freescale Semiconductor, Inc...
6
7
Sdata_in
Input
Figure 38 Timing Diagram — AC97 Mode
3.3.15.3
IrDA Mode
Table 44 Timing Specifications — IrDA Transmit Line
Sym
Description
Min
Max
Units SpecID
1
Pulse high time, defined in the IrDA protocol definition
0.125
10000
µs
A15.22
2
Pulse low time, defined in the IrDA protocol definition
0.125
10000
µs
A15.23
3
Transmitter rising time
—
7.9
ns
A15.24
4
Transmitter falling time
—
7.9
ns
A15.25
NOTE:
Output timing was specified at a nominal 50 pF load.
bcfb
4
IrDA_TX
(SIR / FIR / MIR)
3
1
2
Figure 39 Timing Diagram — IrDA Transmit Line
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3.3.15.4
SPI Mode
Table 45 Timing Specifications — SPI Master Mode, Format 0 (CPHA = 0)
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units SpecID
1
SCK cycle time, programable in the PSC CCS register
30.0
—
ns
A15.26
2
SCK pulse width, 50% SCK cycle time
15.0
—
ns
A15.27
3
Slave select clock delay, programable in the PSC CCS
register
30.0
—
ns
A15.28
4
Output Data valid after Slave Select (SS)
—
8.9
ns
A15.29
5
Output Data valid after SCK
—
8.9
ns
A15.30
6
Input Data setup time
6.0
—
ns
A15.31
7
Input Data hold time
1.0
—
ns
A15.32
8
Slave disable lag time
—
8.9
ns
A15.33
9
Sequential Transfer delay, programable in the PSC
CTUR / CTLR register
15.0
—
ns
A15.34
10
Clock falling time
—
7.9
ns
A15.35
11
Clock rising time
—
7.9
ns
A15.36
NOTE:
Output timing was specified at a nominal 50 pF load.
1
10
SCK
(CLKPOL=0)
Output
2
2
11
SCK
(CLKPOL=1)
Output
11
10
8
3
9
SS
Output
5
4
MOSI
Output
6
6
MISO
Input
7
7
Figure 40 Timing Diagram — SPI Master Mode, Format 0 (CPHA = 0)
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Table 46 Timing Specifications — SPI Slave Mode, Format 0 (CPHA = 0)
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units SpecID
1
SCK cycle time, programable in the PSC CCS register
30.0
—
ns
A15.37
2
SCK pulse width, 50% SCK cycle time
15.0
—
ns
A15.38
3
Slave select clock delay
1.0
—
ns
A15.39
4
Input Data setup time
1.0
—
ns
A15.40
5
Input Data hold time
1.0
—
ns
A15.41
6
Output data valid after SS
—
14.0
ns
A15.42
7
Output data valid after SCK
—
14.0
ns
A15.43
8
Slave disable lag time
0.0
—
ns
A15.44
9
Minimum Sequential Transfer delay = 2 * IP Bus clock
cycle time
30.0
—
—
A15.45
NOTE:
Output timing was specified at a nominal 50 pF load.
1
SCK
(CLKPOL=0)
Input
2
2
SCK
(CLKPOL=1)
Input
8
3
9
SS
Input
5
4
MOSI
Input
6
7
MISO
Output
Figure 41 Timing Diagram — SPI Slave Mode, Format 0 (CPHA = 0)
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Table 47 Timing Specifications — SPI Master Mode, Format 1 (CPHA = 1)
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units SpecID
1
SCK cycle time, programable in the PSC CCS register
30.0
—
ns
A15.46
2
SCK pulse width, 50% SCK cycle time
15.0
—
ns
A15.47
3
Slave select clock delay, programable in the PSC CCS
register
30.0
—
ns
A15.48
4
Output data valid
—
8.9
ns
A15.49
5
Input Data setup time
6.0
—
ns
A15.50
6
Input Data hold time
1.0
—
ns
A15.51
7
Slave disable lag time
—
8.9
ns
A15.52
8
Sequential Transfer delay, programable in the PSC
CTUR / CTLR register
15.0
—
ns
A15.53
9
Clock falling time
—
7.9
ns
A15.54
10
Clock rising time
—
7.9
ns
A15.55
NOTE:
Output timing was specified at a nominal 50 pF load.
1
9
SCK
(CLKPOL=0)
Output
2
2
10
SCK
(CLKPOL=1)
Output
10
9
7
3
8
SS
Output
4
MOSI
Output
5
MISO
Input
6
Figure 42 Timing Diagram — SPI Master Mode, Format 1 (CPHA = 1)
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Table 48 Timing Specifications — SPI Slave Mode, Format 1 (CPHA = 1)
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units SpecID
1
SCK cycle time, programable in the PSC CCS register
30.0
—
ns
A15.56
2
SCK pulse width, 50% SCK cycle time
15.0
—
ns
A15.57
3
Slave select clock delay
0.0
—
ns
A15.58
4
Output data valid
—
14.0
ns
A15.59
5
Input Data setup time
2.0
—
ns
A15.60
6
Input Data hold time
1.0
—
ns
A15.61
7
Slave disable lag time
0.0
—
ns
A15.62
8
Minimum Sequential Transfer delay = 2 * IP-Bus clock
cycle time
30.0
—
ns
A15.63
NOTE:
Output timing was specified at a nominal 50 pF load.
1
SCK
(CLKPOL=0)
Input
2
2
SCK
(CLKPOL=1)
Input
7
3
8
SS
Input
5
6
MOSI
Input
4
MISO
Output
Figure 43 Timing Diagram — SPI Slave Mode, Format 1 (CPHA = 1)
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3.3.16 GPIOs and Timers
3.3.16.1
General and Asynchronous Signals
The MPC5200 contains several sets if I/Os that do not require special setup, hold, or valid requirements.
Most of these are asynchronous to the system clock. The following numbers are provided for test and
validation purposes only, and they assume a 133 MHz internal bus frequency.
Figure 44 shows the GPIO Timing Diagram. Table 49 gives the timing specifications.
Table 49 Asynchronous Signals
Freescale Semiconductor, Inc...
Sym
Description
Min
Max
Units
SpecID
7.52
—
ns
A16.1
tCK
Clock Period
tIS
Input Setup for Async Signal
12
—
ns
A16.2
tIH
Input Hold for Async Signals
1
—
ns
A16.3
tDV
Output Valid
—
15.33
ns
A16.4
tDH
Output Hold
1
—
ns
A16.5
tCK
tDH
tDV
Output
valid
tIH
tIS
Input
valid
Figure 44 Timing Diagram—Asynchronous Signals
3.3.17 IEEE 1149.1 (JTAG) AC Specifications
Table 50 JTAG Timing Specification
Sym
Characteristic
Min
Max
Unit
SpecID
—
TCK frequency of operation.
0
25
MHz
A17.1
1
TCK cycle time.
40
—
ns
A17.2
2
TCK clock pulse width measured at 1.5V.
1.08
—
ns
A17.3
3
TCK rise and fall times.
0
3
ns
A17.4
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Electrical and Thermal Characteristics
Table 50 JTAG Timing Specification (continued)
Freescale Semiconductor, Inc...
Sym
Characteristic
Min
Max
Unit
SpecID
4
TRST setup time to tck falling edge 1.
10
—
ns
A17.5
5
TRST assert time.
5
—
ns
A17.6
6
Input data setup time 2.
5
—
ns
A17.7
15
—
ns
A17.8
0
30
ns
A17.9
0
30
ns
A17.10
time2
7
Input data hold
8
TCK to output data valid 3.
.
impedance3
9
TCK to output high
10
TMS, TDI data setup time.
5
—
ns
A17.11
11
TMS, TDI data hold time.
1
—
ns
A17.12
12
TCK to TDO data valid.
0
15
ns
A17.13
13
TCK to TDO high impedance.
0
15
ns
A17.14
1
2
3
.
TRST is an asynchronous signal. The setup time is for test purposes only.
Non-test, other than TDI and TMS, signal input timing with respect to TCK.
Non-test, other than TDO, signal output timing with respect to TCK.
1
2
TCK
VM
VM
3
3
2
VM
VM = Midpoint Voltage
Numbers shown reference Table 50.
Figure 45 Timing Diagram—JTAG Clock Input
TCK
4
TRST
5
Numbers shown reference Table 50.
Figure 46 Timing Diagram—JTAG TRST
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Freescale Semiconductor, Inc.
Electrical and Thermal Characteristics
TCK
6
DATA INPUTS
7
INPUT DATA VALID
8
DATA OUTPUTS
OUTPUT DATA VALID
Freescale Semiconductor, Inc...
9
DATA OUTPUTS
Numbers shown reference Table 50.
Figure 47 Timing Diagram—JTAG Boundary Scan
TCK
10
TDI, TMS
11
INPUT DATA VALID
12
TDO
OUTPUT DATA VALID
13
TDO
Numbers shown reference Table 50.
Figure 48 Timing Diagram—Test Access Port
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Package Description
4
Package Description
4.1
Package Parameters
The MPC5200 uses a 27 mm x 27 mm TE-PBGA package. The package parameters are as provided in the
following list:
•
Package outline27 mm x 27 mm
•
Interconnects272
•
Pitch1.27 mm
Freescale Semiconductor, Inc...
4.2
Mechanical Dimensions
Figure 49 provides the mechanical dimensions, top surface, side profile, and pinout for the MPC5200, 272
TE-PBGA package.
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Freescale Semiconductor, Inc.
Package Description
PIN A1
INDEX
D
C
0.2
4X
A
272X
0.2 A
Freescale Semiconductor, Inc...
E
0.35 A
E2
D2
0.2
M
NOTES:
1. DIMENSIONS AND TOLERANCING PER ASME
Y14.5M, 1994.
2. DIMENSIONS IN MILLIMETERS.
3. DIMENSION IS MEASURED AT THE MAXIMUM
SOLDER BALL DIAMETER PARALLEL TO
PRIMARY DATUM A.
4. PRIMARY DATUM A AND THE SEATING PLANE
ARE DEFINED BY THE SPHERICAL CROWNS OF
THE SOLDER BALLS.
A B C
B
TOP VIEW
DIM
A
A1
A2
A3
b
D
D1
D2
E
E1
E2
e
(D1)
19X
19X
e
Y
W
V
U
T
R
P
N
M
L
K
J
H
G
F
E
D
C
B
A
e
(E1)
4X
e /2
A1
A3
A2
A
SIDE VIEW
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20
b 3
272X
BOTTOM VIEW
MILLIMETERS
MIN
MAX
2.05
2.65
0.50
0.70
0.50
0.70
1.05
1.25
0.60
0.90
27.00 BSC
24.13 REF
23.30
24.70
27.00 BSC
24.13 REF
23.30
24.70
1.27 BSC
0.3
M
A B C
0.15
M
A
CASE 1135A–01
ISSUE B
DATE 10/15/1997
Figure 49 Mechanical Dimensions and Pinout Assignments for the MPC5200, 272
TE-PBGA
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Package Description
5.3
Pinout Listings
See details in the MPC5200 User Manual [1].
Table 51 MPC5200 Pinout Listing
Name
Alias
Type
Power
Supply
Output
Driver Type
Input
Type
Pull-up/
down
SDRAM
MEM_CAS
MEM_CLK_EN
CAS
I/O
VDD_MEM_IO
DRV16_MEM
TTL
CLK_EN
I/O
VDD_MEM_IO
DRV16_MEM
TTL
I/O
VDD_MEM_IO
DRV16_MEM
TTL
Freescale Semiconductor, Inc...
MEM_CS
MEM_DQM[3:0]
DQM
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_MA[12:0]
MA
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_MBA[1:0]
MBA
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_MDQS[3:0]
MDQS
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_MDQ[31:0]
MDQ
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_CLK
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_CLK
I/O
VDD_MEM_IO
DRV16_MEM
TTL
I/O
VDD_MEM_IO
DRV16_MEM
TTL
I/O
VDD_MEM_IO
DRV16_MEM
TTL
MEM_RAS
MEM_WE
RAS
PCI
EXT_AD[31:0]
I/O
VDD_IO
PCI
PCI
PCI_CBE_0
I/O
VDD_IO
PCI
PCI
PCI_CBE_1
I/O
VDD_IO
PCI
PCI
PCI_CBE_2
I/O
VDD_IO
PCI
PCI
PCI_CBE_3
I/O
VDD_IO
PCI
PCI
PCI_CLOCK
I/O
VDD_IO
PCI
PCI
PCI_DEVSEL
I/O
VDD_IO
PCI
PCI
PCI_FRAME
I/O
VDD_IO
PCI
PCI
PCI_GNT
I/O
VDD_IO
DRV8
TTL
PCI_IDSEL
I/O
VDD_IO
DRV8
TTL
PCI_IRDY
I/O
VDD_IO
PCI
PCI
PCI_PAR
I/O
VDD_IO
PCI
PCI
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Type
Power
Supply
Output
Driver Type
Input
Type
PCI_PERR
I/O
VDD_IO
PCI
PCI
PCI_REQ
I/O
VDD_IO
DRV8
TTL
PCI_RESET
I/O
VDD_IO
PCI
PCI
PCI_SERR
I/O
VDD_IO
PCI
PCI
PCI_STOP
I/O
VDD_IO
PCI
PCI
PCI_TRDY
I/O
VDD_IO
PCI
PCI
Freescale Semiconductor, Inc...
Name
Alias
Pull-up/
down
Local Plus
LP_ACK
I/O
VDD_IO
DRV8
TTL
LP_ALE
I/O
VDD_IO
DRV8
TTL
LP_OE
I/O
VDD_IO
DRV8
TTL
LP_RW
I/O
VDD_IO
DRV8
TTL
LP_TS
I/O
VDD_IO
DRV8
TTL
LP_CS0
I/O
VDD_IO
DRV8
TTL
LP_CS1
I/O
VDD_IO
DRV8
TTL
LP_CS2
I/O
VDD_IO
DRV8
TTL
LP_CS3
I/O
VDD_IO
DRV8
TTL
LP_CS4
I/O
VDD_IO
DRV8
TTL
LP_CS5
I/O
VDD_IO
DRV8
TTL
PULLUP
ATA
ATA_DACK
I/O
VDD_IO
DRV8
TTL
ATA_DRQ
I/O
VDD_IO
DRV8
TTL
PULLDOWN
ATA_INTRQ
I/O
VDD_IO
DRV8
TTL
PULLDOWN
ATA_IOCHRDY
I/O
VDD_IO
DRV8
TTL
PULLUP
ATA_IOR
I/O
VDD_IO
DRV8
TTL
ATA_IOW
I/O
VDD_IO
DRV8
TTL
ATA_ISOLATION
I/O
VDD_IO
DRV8
TTL
DRV4
TTL
Ethernet
ETH_0
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TX, TX_EN
I/O
VDD_IO
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Alias
Type
Power
Supply
Output
Driver Type
Input
Type
ETH_1
RTS, TXD[0]
I/O
VDD_IO
DRV4
TTL
ETH_2
USB_TXP, TX,
TXD[1]
I/O
VDD_IO
DRV4
TTL
ETH_3
USB_PRTPWR,
TXD[2]
I/O
VDD_IO
DRV4
TTL
ETH_4
USB_SPEED,
TXD[3]
I/O
VDD_IO
DRV4
TTL
ETH_5
USB_SUPEND,
TX_ER
I/O
VDD_IO
DRV4
TTL
ETH_6
USB_OE, RTS,
MDC
I/O
VDD_IO
DRV4
TTL
ETH_7
TXN, MDIO
I/O
VDD_IO
DRV4
TTL
ETH_8
RX_DV
I/O
VDD_IO
DRV4
TTL
ETH_9
CD, RX_CLK
I/O
VDD_IO
DRV4
Schmitt
ETH_10
CTS, COL
I/O
VDD_IO
DRV4
TTL
ETH_11
TX_CLK
I/O
VDD_IO
DRV4
Schmitt
ETH_12
RXD[0]
I/O
VDD_IO
DRV4
TTL
ETH_13
USB_RXD,
CTS, RXD[1]
I/O
VDD_IO
DRV4
TTL
ETH_14
USB_RXP,
UART_RX,
RXD[2]
I/O
VDD_IO
DRV4
TTL
ETH_15
USB_RXN, RX,
RXD[3]
I/O
VDD_IO
DRV4
TTL
ETH_16
USB_OVRCNT,
CTS, RX_ER
I/O
VDD_IO
DRV4
TTL
ETH_17
CD, CRS
I/O
VDD_IO
DRV4
TTL
Freescale Semiconductor, Inc...
Name
Pull-up/
down
IRDA
PSC6_0
IRDA_RX, TxD
I/O
VDD_IO
DRV4
TTL
PSC6_1
RxD
I/O
VDD_IO
DRV4
TTL
PSC6_2
Frame, CTS
I/O
VDD_IO
DRV4
TTL
PSC6_3
IR_USB_CLK,Bi
tClk, RTS
I/O
VDD_IO
DRV4
TTL
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Name
Alias
Type
Power
Supply
Output
Driver Type
Input
Type
Pull-up/
down
Freescale Semiconductor, Inc...
USB
USB_0
USB_OE
I/O
VDD_IO
DRV4
TTL
USB_1
USB_TXN
I/O
VDD_IO
DRV4
TTL
USB_2
USB_TXP
I/O
VDD_IO
DRV4
TTL
USB_3
USB_RXD
I/O
VDD_IO
DRV4
TTL
USB_4
USB_RXP
I/O
VDD_IO
DRV4
TTL
USB_5
USB_RXN
I/O
VDD_IO
DRV4
TTL
USB_6
USB_PRTPWR
I/O
VDD_IO
DRV4
TTL
USB_7
USB_SPEED
I/O
VDD_IO
DRV4
TTL
USB_8
USB_SUPEND
I/O
VDD_IO
DRV4
TTL
USB_9
USB_OVRCNT
I/O
VDD_IO
DRV4
TTL
I2C
I2C_0
SCL
I/O
VDD_IO
DRV4
Schmitt
I2C_1
SDA
I/O
VDD_IO
DRV4
Schmitt
I2C_2
SCL
I/O
VDD_IO
DRV4
Schmitt
I2C_3
SDA
I/O
VDD_IO
DRV4
Schmitt
PSC
PSC1_0
TxD, Sdata_out,
MOSI, TX
I/O
VDD_IO
DRV4
TTL
PSC1_1
RxD, Sdata_in,
MISO, TX
I/O
VDD_IO
DRV4
TTL
PSC1_2
Mclk, Sync, RTS
I/O
VDD_IO
DRV4
TTL
PSC1_3
BitClk, SCK,
CTS
I/O
VDD_IO
DRV4
TTL
PSC1_4
Frame, SS, CD
I/O
VDD_IO
DRV4
TTL
PSC2_0
TxD, Sdata_out,
MOSI, TX
I/O
VDD_IO
DRV4
TTL
PSC2_1
RxD, Sdata_in,
MISO, TX
I/O
VDD_IO
DRV4
TTL
PSC2_2
Mclk, Sync, RTS
I/O
VDD_IO
DRV4
TTL
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Alias
Type
Power
Supply
Output
Driver Type
Input
Type
PSC2_3
BitClk, SCK,
CTS
I/O
VDD_IO
DRV4
TTL
PSC2_4
Frame, SS, CD
I/O
VDD_IO
DRV4
TTL
PSC3_0
USB_OE, TxDS,
TX
I/O
VDD_IO
DRV4
TTL
PSC3_1
USB_TXN, RxD,
RX
I/O
VDD_IO
DRV4
TTL
PSC3_2
USB_TXP,
BitClk, RTS
I/O
VDD_IO
DRV4
TTL
PSC3_3
USB_RXD,
Frame, SS, CTS
I/O
VDD_IO
DRV4
TTL
PSC3_4
USB_RXP, CD
I/O
VDD_IO
DRV4
TTL
PSC3_5
USB_RXN
I/O
VDD_IO
DRV4
TTL
PSC3_6
USB_PRTPWR,
Mclk, MOSI
I/O
VDD_IO
DRV4
TTL
PSC3_7
USB_SPEED.
MISO
I/O
VDD_IO
DRV4
TTL
PSC3_8
USB_SUPEND,
SS
I/O
VDD_IO
DRV4
TTL
PSC3_9
USB_OVRCNT,
SCK
I/O
VDD_IO
DRV4
TTL
Freescale Semiconductor, Inc...
Name
Pull-up/
down
GPIO/TIMER
GPIO_WKUP_6
MEM_CS1
I/O
VDD_MEM_IO
DRV16_MEM
TTL
GPIO_WKUP_7
I/O
VDD_IO
DRV8
TTL
TIMER_0
I/O
VDD_IO
DRV4
TTL
TIMER_1
I/O
VDD_IO
DRV4
TTL
TIMER_2
MOSI
I/O
VDD_IO
DRV4
TTL
TIMER_3
MISO
I/O
VDD_IO
DRV4
TTL
TIMER_4
SS
I/O
VDD_IO
DRV4
TTL
TIMER_5
SCK
I/O
VDD_IO
DRV4
TTL
TIMER_6
I/O
VDD_IO
DRV4
TTL
TIMER_7
I/O
VDD_IO
DRV4
TTL
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PULLUP_MEM
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Name
Alias
Type
Power
Supply
Output
Driver Type
Input
Type
Pull-up/
down
Clock
SYS_XTAL_IN
SYS_XTAL_OUT
RTC_XTAL_IN
RTC_XTAL_OUT
Input
VDD_IO
Output
VDD_IO
Input
VDD_IO
Output
VDD_IO
Freescale Semiconductor, Inc...
Misc
PORRESET
Input
VDD_IO
DRV4
Schmitt
HRESET
I/O
VDD_IO
DRV8_OD 1
Schmitt
SRESET
I/O
VDD_IO
DRV8_OD1
Schmitt
IRQ0
I/O
VDD_IO
DRV4
TTL
IRQ1
I/O
VDD_IO
DRV4
TTL
IRQ2
I/O
VDD_IO
DRV4
TTL
IRQ3
I/O
VDD_IO
DRV4
TTL
Test/Configuration
SYS_PLL_TPA
I/O
VDD_IO
DRV4
TTL
TEST_MODE_0
Input
VDD_IO
DRV4
TTL
TEST_MODE_1
Input
VDD_IO
DRV4
TTL
TEST_SEL_0
I/O
VDD_IO
DRV4
TTL
TEST_SEL_1
I/O
VDD_IO
DRV8
TTL
PULLUP
JTAG_TCK
TCK
Input
VDD_IO
DRV4
TTL
PULLUP
JTAG_TDI
TDI
Input
VDD_IO
DRV4
TTL
PULLUP
JTAG_TDO
TDO
I/O
VDD_IO
DRV8
TTL
JTAG_TMS
TMS
Input
VDD_IO
DRV4
TTL
PULLUP
JTAG_TRST
TRST
Input
VDD_IO
DRV4
TTL
PULLUP
Power and Ground
VDD_IO
-
VDD_MEM_IO
-
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Package Description
Table 51 MPC5200 Pinout Listing (continued)
Name
Alias
Type
VDD_CORE
-
VSS_IO/CORE
-
SYS_PLL_AVDD
-
CORE_PLL_AVDD
-
Output
Driver Type
Input
Type
Pull-up/
down
All “open drain” outputs of the MPC5200 are actually regular three-state output drivers with the output data tied low
and the output enable controlled. Thus, unlike a true open drain, there is a current path from the external system to the
MPC5200 I/O power rail if the external signal is driven above the MPC5200 I/O power rail voltage.
Freescale Semiconductor, Inc...
1
Power
Supply
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System Design Information
6
System Design Information
6.1
Power UP/Down Sequencing
DC Power Supply Voltage
Freescale Semiconductor, Inc...
Figure 50 shows situations in sequencing the I/O VDD (VDD_IO), Memory VDD (VDD_IO_MEM), PLL
VDD (PLL_AVDD), and Core VDD (VDD_CORE).
3.3V
VDD_IO,
VDD_IO_MEM (SDR)
2.5V
VDD_IO_MEM (DDR)
1
VDD_CORE,
PLL_AVDD
1.5V
2
0
Time
Note:
1.
VDD_CORE should not exceed VDD_IO, VDD_IO_MEM or PLL_AVDD by more than 0.4 V at any time,
including power-up.
2.
It is recommended that VDD_CORE/PLL_AVDD should track VDD_IO/VDD_IO_MEM up to 0.9 V
then separate for completion of ramps.
3.
Input voltage must not be greater than the supply voltage (VDD_IO, VDD_IO_MEM, VDD_CORE, or
PLL_AVDD) by more than 0.5 V at any time, including during power-up.
4.
Use 1 microsecond or slower rise time for all supplies.
Figure 50 Supply Voltage Sequencing
The relationship between VDD_IO_MEM and VDD_IO is non-critical during power-up and power-down
sequences. Both VDD_IO_MEM (2.5 V or 3.3 V) and VDD_IO are specified relative to VDD_CORE.
6.1.1 Power Up Sequence
If VDD_IO/VDD_IO_MEM are powered up with the VDD_CORE at 0V, the sense circuits in the I/O pads
will cause all pad output drivers connected to the VDD_IO/VDD_IO_MEM to be in a high-impedance state.
There is no limit to how long after VDD_IO/VDD_IO_MEM powers up before VDD_CORE must power up.
VDD_CORE should not lead the VDD_IO, VDD_IO_MEM or PLL_AVDD by more than 0.4 V during power
ramp up or there will be high current in the internal ESD protection diodes. The rise times on the power
supplies should be slower than 1 microsecond to avoid turning on the internal ESD protection clamp
diodes.
The recommended power up sequence is as follows:
Use one microsecond or slower rise time for all supplies.
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System Design Information
VDD_CORE/PLL_AVDD and VDD_IO/VDD_IO_MEM should track up to 0.9 V and then separate for the
completion of ramps with VDD_IO/VDD_IO_MEM going to the higher external voltages. One way to
accomplish this is to use a low drop-out voltage regulator.
6.1.2 Power Down Sequence
If VDD_CORE/PLL_AVDD are powered down first, then sense circuits in the I/O pads will cause all output
drivers to be in a high impedance state. There is no limit on how long after VDD_CORE and PLL_AVDD
power down before VDD_IO or VDD_IO_MEM must power down. VDD_CORE should not lag VDD_IO,
VDD_IO_MEM, or PLL_AVDD going low by more than 0.4V during power down or there will be undesired
high current in the ESD protection diodes. There are no requirements for the fall times of the power
supplies.
The recommended power down sequence is as follows:
Freescale Semiconductor, Inc...
Drop VDD_CORE/PLL_AVDD to 0V.
Drop VDD_IO/VDD_IO_MEM supplies.
6.2
System and CPU Core AVDD power supply filtering
Each of the independent PLL power supplies require filtering external to the device. The following drawing
is a recommendation for the required filter circuit.
Power
Supply
source
<1Ω
10 Ω
AVDD device pin
10 µF
200-400 pF
Figure 51 Power Supply Filtering
6.3
Pull-up/Pull-down Resistor Requirements
The MPC5200 requires external pull-up or pull-down resistors on certain pins.
6.3.1 Pull-down Resistor Requirements for TEST pins
The MPC5200 requires pull-down resistors on the test pins TEST_MODE_0, TEST_MODE_1,
TEST_SEL_1.
6.3.2 Pull-up Requirements for the PCI Control Lines
If the PCI interface is NOT used (and internally disabled) the PCI control pins must be terminated as
indicated by the PCI Local Bus specification [4]. This is also required for MOST/Graphics and Large Flash
Mode.
PCI control signals always require pull-up resistors on the motherboard (not the expansion board) to
ensure that they contain stable values when no agent is actively driving the bus. This includes
PCI_FRAME, PCI_TRDY, PCI_IRDY, PCI_DEVSEL, PCI_STOP, PCI_SERR, PCI_PERR, and PCI_REQ.
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System Design Information
6.3.3 Pull-up/Pull-down Requirements for MEM_MDQS pins (SDRAM)
The MEM_MDQS[3:0] signals are not used with SDR memories and require pull-up or pull-down resistors
in SDRAM mode.
6.4
Information about JTAG_TRST
Boundary scan testing is enabled through the JTAG interface signals. The JTAG_TRST signal is optional
in the IEEE 1149.1 specification but is provided on all processors that implement the PowerPC
architecture. To obtain a reliable power-on reset performance, the JTAG_TRST signal must be asserted
during power-on reset.
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6.4.1 JTAG_TRST and PORRESET
The JTAG interface can control the direction of the MPC5200 I/O pads via the boundary scan chain. The
JTAG module must be reset before the MPC5200 comes out of power-on reset; do this by asserting
JTAG_TRST before PORRESET is released.
For more details refer to the Reset and JTAG Timing Specification.
PORRESET
required assertion of JTAG_TRST
optional assertion of JTAG_TRST
JTAG_TRST
Figure 52 PORRESET vs. JTAG_TRST
6.5
Connecting JTAG_TRST
The wiring of the JTAG_TRST is dependent of the existence of a board-related debug interface.
Normally this interface is implemented, using a COP (common on-chip processor) connector. The COP
allows a remote computer system (typically, a PC with dedicated hardware and debugging software) to
access and control the internal operations of the MPC5200. The COP port requires the ability to
independently assert HRESET and JTAG_TRST in order to fully control the processor.
There are two possibilities to connect the JTAG interface: using it with a COP connector and without a
COP connector.
6.5.1 Boards interfacing the JTAG port via a COP connector
For a board with a COP (common on-chip processor) connector, which accesses the JTAG interface and
which needs to reset the JTAG module, simply wiring TRST and PORRESET is not recommended.
To reset the MPC5200 via the COP connector, the HRESET pin of the COP should be connected to the
HRESET pin of the MPC5200.
The circuitry shown in Figure 53 allows the COP to assert HRESET or JTAG_TRST separately, while any
other board sources can drive PORRESET.
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System Design Information
PORRESET
PORRESET
COP Header
13
11
HRESET
Freescale Semiconductor, Inc...
1
2
3
4
5
6
7
8
10
11
12
13
K
15
16
VDD
10Kohm
10Kohm
4
SRESET
TRST
JTAG_TRST
Key 14
9
10Kohm
TMS
VDD
JTAG_TMS
12
62
Key
MPC5200
VDD
7
9
HRESET
VDD
SRESET
16
COP Connector
Physical Pinout
10Kohm
3
10Kohm
TCK
VDD
VDD
JTAG_TCK
10Kohm
TDI
VDD
JTAG_TDI
15
1
CKSTP_OUT
TEST_SEL_0
TDO
JTAG_TDO
53
halted
24
qack
NC
NC
10
NC
8
NC
Figure 53 COP Connector Diagram
6.5.2 Boards without COP connector
If the JTAG interface is not used, JTAG_TRST should be tied to PORRESET, so that it is asserted when
the system reset signal (PORRESET) is asserted. This ensures that the JTAG scan chain is initialized
during power on. Figure 54 shows the connection of the JTAG interface without COP connector.
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System Design Information
PORRESET
PORRESET
HRESET
10Kohm
SRESET
10Kohm
HRESET
MPC5200
VDD
VDD
SRESET
Freescale Semiconductor, Inc...
JTAG_TRST
10Kohm
VDD
JTAG_TMS
10Kohm
VDD
JTAG_TCK
10Kohm
VDD
JTAG_TDI
TEST_SEL_0
JTAG_TDO
Figure 54 JTAG_TRST wiring for boards without COP connector
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Ordering Information
7
Ordering Information
Table 52 Ordering Information
Part Number
400
Qualification
0C to 70C
Commercial
MPC5200CBV266 266
-40C to 85C
Industrial
MPC5200CBV400 400
-40C to 85C
Industrial
SPC5200CBV400 400
-40C to 85C
Automotive - AEC
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MPC5200BV400
Speed Ambient Temp
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Document Revision History
8
Document Revision History
Table 53 provides a revision history for this hardware specification.
Table 53 Document Revision History
Rev.
No.
0.1
First Preliminary release with some TBD’s in spec tables (6/2003)
0.2
Added AC specs for missing modules, power-on sequence, misc other updates (7/2003)
0.2.1
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Substantive Change(s)
Corrected maximum core operating frequency (7/2003)
0.3
Added Memory Interface Timing values, misc other updates (8/2003)
1.0
Added Information about JTAG_TRST (11/2003)
2.0
Added Power Numbers (Section 3.1.5), updated Oscillator and PLL Characteristics (Section
3.2), updated SDRAM AC Characteristics (Section 3.3.5)
For more detailed information, refer to the following documentation:
[1] MPC5200 User Manual MPC5200UM
[2] PowerPC Microprocessor Family: The Programming Environments for 32-bit Microprocessors,
Rev. 2: MPCFPE32B/AD
[3] G2 Core Reference Manual, Rev. 0: G2CORERM/D
[4] PCI Local Bus Specification, Revision 2.2, December 18, 1998
[5] ANSI ATA-4 Specification
[6] IEEE 802.3 Specification (ETHERNET)
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MPC5200/D
Rev. 2
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