Texas Instruments TMS320C6452 DSP 사용자 설명서
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2.11.2
DDR2 SDRAM Initialization After Reset
2.11.3
DDR2 SDRAM Initialization After Register Configuration
2.12 Interrupt Support
2.13 EDMA Event Support
2.14 Emulation Considerations
Peripheral Architecture
Table 10. DDR2 SDRAM Extended Mode Register 1 Configuration (continued)
Mode
Mode Register
Register Bit
Field
Init Value
Description
2
ODT Value (Rtt)
1
On-die termination effective resistance (Rtt) bits. Together
with bit 2, this bit selects the value for Rtt as 75
with bit 2, this bit selects the value for Rtt as 75
Ω
.
1
Output Driver
SDCFG.DDR_DRIVE
Output driver impedance control bits. Initialized using the
Impedance
DDR_DRIVE bit of the SDRAM configuration register
(SDCFG).
(SDCFG).
0
DLL Enable
0
DLL enable/disable bits. DLL is always enabled.
After a hard or a soft reset, the DDR2 memory controller will automatically start the initialization sequence.
The DDR2 memory controller will use the default values in the SDRAM timing 1 and timing 2 registers and
the SDRAM configuration register to configure the mode registers of the DDR2 SDRAM device(s). Note
that since a soft reset does not reset the DDR2 memory controller registers, an initialization sequence
started by a soft reset would use the register values from a previous configuration.
The DDR2 memory controller will use the default values in the SDRAM timing 1 and timing 2 registers and
the SDRAM configuration register to configure the mode registers of the DDR2 SDRAM device(s). Note
that since a soft reset does not reset the DDR2 memory controller registers, an initialization sequence
started by a soft reset would use the register values from a previous configuration.
The initialization sequence can also be initiated by performing a write to the two least-significant bytes in
the SDRAM configuration register (SDCFG). Using this approach, data and commands stored in the
DDR2 memory controller FIFOs are not lost and the DDR2 memory controller ensures read and write
commands are completed before starting the initialization sequence.
the SDRAM configuration register (SDCFG). Using this approach, data and commands stored in the
DDR2 memory controller FIFOs are not lost and the DDR2 memory controller ensures read and write
commands are completed before starting the initialization sequence.
Perform the following steps to start the initialization sequence:
1. Set the BOOT_UNLOCK bit in the SDRAM configuration register (SDCFG).
2. Write a 0 to the BOOT_UNLOCK bit along with the desired value for the DDR_DRIVE bit.
3. Program the rest of the SDCFG to the desired value with the TIMUNLOCK bit set (unlocked).
4. Program the SDRAM timing 1 register (SDTIM1) and SDRAM timing register 2 (SDTIM2) with the
2. Write a 0 to the BOOT_UNLOCK bit along with the desired value for the DDR_DRIVE bit.
3. Program the rest of the SDCFG to the desired value with the TIMUNLOCK bit set (unlocked).
4. Program the SDRAM timing 1 register (SDTIM1) and SDRAM timing register 2 (SDTIM2) with the
value needed to meet the DDR2 SDRAM device timings.
5. Program the REFRESH_RATE bits in the SDRAM refresh control register (SDRFC) to a value that
meets the refresh requirements of the DDR2 SDRAM device.
6. Program SDCFG with the desired value and the TIMUNLOCK bit cleared (locked).
7. Program the read latency (RL) bit in the DDR2 memory controller control register (DMCCTL) to the
7. Program the read latency (RL) bit in the DDR2 memory controller control register (DMCCTL) to the
desired value.
The DDR2 memory controller does not generate any interrupts.
The DDR2 memory controller is a DMA slave peripheral and therefore does not generate EDMA events.
Data read and write requests may be made directly by masters including the EDMA controller.
Data read and write requests may be made directly by masters including the EDMA controller.
The DDR2 memory controller will remain fully functional during emulation halts to allow emulation access
to external memory.
to external memory.
DSP DDR2 Memory Controller
28
SPRUF85 – October 2007