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Flex-MuxOneNAND4G(KFM4GH6Q4M-DEBx)
Flex-MuxOneNAND8G(KFN8GH6Q4M-DEBx)
Flex-MuxOneNAND16G(KFKAGH6Q4M-DEBx)
3.7.2.3 Programmable Burst Read Latency Operation
See Timing Diagrams 6.1 and 6.2
Upon power up, the number of initial clock cycles from Valid Address (AVD) to initial data defaults to four clocks.
The number of clock cycles (n) which are inserted after the clock which is latching the address. The host can read the first data with the
(n+1)th rising edge.
The number of total initial access cycles is programmable from three to seven cycles. After the number of programmed burst clock cycles is
reached, the rising edge of the next clock cycle triggers the next burst data.
Four Clock Burst Read Latency (BRWL=4 case)
CE
CLK
-1
0
AVD
A/DQ0:
Valid
Address
A/DQ15
OE
Hi-Z
RDY
*
NOTE :
BRWL=4, HF=0 is recommended for 40MHz~66MHz. For frequency over 66MHz, BRWL should be 6 or 7 while HF=1.
Also, for frequency under 40MHz, BRWL can be reduced to 3, and HF=0.
3.7.3 Handshaking Operation
The handshaking feature allows the host system to simply monitor the RDY signal from the device to determine when the initial word of burst
data is ready to be read.
To set the number of initial cycles for optimal burst mode, the host should use the programmable burst read latency configuration (see section
2.8.19, "System Configuration1 Register").
The rising edge of RDY which is derived at one cycle prior of data fetch clock indicates the initial word of valid burst data.
3.7.4 Output Disable Mode Operation
When the CE or OE input is at V
The outputs are placed in the high impedance state.
1
2
3
D6
t
IAA
t
RDYA
, output from the device is disabled.
IH
Rising edge of the clock cycle following last read latency
triggers next burst data
4
t
BA
D7
D0
D1
t
RDYS
- 70 -
FLASH MEMORY
D2
D3
D7
D0
Hi-Z
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