SHARP LH540235U-25

LH540235/45
2048 × 18 / 4096 × 18 Synchronous FIFOs
• May be Cascaded for Increased Depth, or
FEATURES
Paralleled for Increased Width
• Fast Cycle Times: 20/25/35 ns
• Pin-Compatible Drop-In Replacements for
• 16 mA-IOL High-Drive Three-State Outputs
• Five Status Flags: Full, Almost-Full, Half-Full,
IDT72235B/45B FIFOs
• Choice of IDT-Compatible or Enhanced Operating
Mode; Selected by an Input Control Signal
• Device Comes Up into One of Two Known Default
States at Reset Depending on the State of the
EMODE Control Input: Programming is Allowed, but
is not Required
• Internal Memory Array Architecture Based on CMOS
Dual-Port SRAM Technology, 2048 × 18 or 4096 × 18
• ‘Synchronous’ Enable-Plus-Clock Control at Both
Almost-Empty, and Empty; ‘Almost’ Flags are
Programmable
• In Enhanced Operating Mode, Almost-Full,
Half-Full, and Almost-Empty Flags can be Made
Completely Synchronous
• In Enhanced Operating Mode, Duplicate Enables
for Interlocked Paralleled FIFO Operation, for
36-Bit Data Width, when Selected and
Appropriately Connected
• In Enhanced Operating Mode, Disabling
Input Port and Output Port
• Independently-Synchronized Operation of Input Port
and Output Port
• Control Inputs Sampled on Rising Clock Edge
• Most Control Signals Assertive-LOW for
Noise Immunity
Three-State Outputs May be Made to Suppress
Reading
• Data Retransmit Function
• TTL/CMOS-Compatible I/O
• Space-Saving 68-Pin PLCC Package; Even-Smaller
64-Pin TQFP Package
RS
FL/RT
WXI/WEN2
WXO/HF
RXI/REN2
RXO/EF2
RESET
LOGIC
FIFO
MEMORY ARRAY
2048 x 18/4096 x 18
EXPANSION
LOGIC
WRITE
POINTER
WCK
WEN
READ
POINTER
RCK
INPUT
PORT
CONTROL
LOGIC
OUTPUT
PORT
CONTROL
LOGIC
WXI/WEN2
RXI/REN2
FF
PAF
WXO/HF
D0 - D17
REN
EF
PAE
RXO/EF2
DEDICATED AND
PROGRAMMABLE
STATUS FLAGS
INPUT
PORT
OUTPUT
PORT
PROGRAMMABLE
REGISTERS
LD
OE
Q0 - Q17
EMODE
BOLD ITALIC = Enhanced Operating Mode.
540235-1
Figure 1. LH540235/45 Block Diagram
BOLD ITALIC = Enhanced Operating Mode
1
LH540235/45
FUNCTIONAL DESCRIPTION
NOTE: Throughout this data sheet, a BOLD ITALIC type
font is used for all references to Enhanced Operating
Mode features which do not function in IDT-Compatible
Operating Mode; and also for all references to the retransmit facility (which is not an IDT72235B/45B FIFO
feature), even though it may be used – subject to some
restrictions – in either of these two operating modes.
Thus, readers interested only in using the LH540235/45
FIFOs in IDT-Compatible Operating Mode may skip over
BOLD ITALIC sections, if they wish.
The LH540235/45 parts are FIFO (First-In, First-Out)
memory devices, based on fully-static CMOS dual-port
SRAM technology, capable of containing up to 2048 or 4096
18-bit words respectively. They can replace two or more
byte-wide FIFOs in many applications, for microprocessorto-microprocessor or microprocessor-to-bus communication. Their architecture supports synchronous operation, tied
to two independent free-running clocks at the input and
output ports respectively. However, these ‘clocks’ also may
be aperiodic, asynchronous ‘demand’ signals. Almost all
control-input signals and status-output signals are synchronized to these clocks, to simplify system design.
The input and output ports operate altogether independently of each other, unless the FIFO becomes either
totally full or else totally empty. Data flow is initiated at a
port by the rising edge of its corresponding clock, and is
gated by the appropriate edge-sampled enable signals.
The following FIFO status flags monitor the extent to
which the internal memory has been filled: Full, AlmostFull, Half-Full, Almost-Empty, and Empty. The Almost-Full
and Almost-Empty flag offsets are programmable over the
entire FIFO depth; but, during a reset operation, each of
these is initialized to a default offset value of 12710
FIFO-memory words, from the respective FIFO boundary.
If this default offset value is satisfactory, no further programming is required.
After a reset operation during which the EMODE control
input was not asserted (was HIGH), these FIFOs operate
in the IDT-Compatible Operating Mode. In this mode,
each part is pin-compatible and functionally-compatible
with the IDT72235B/45B part of similar depth and speed
grade; and the Control Register is not even accessible
or visible to the external-system logic which is controlling
the FIFO, although it still performs the same control
functions.
However, assertion of the EMODE control input
during a reset operation leaves Control Register bits
00-05 set, and causes the FIFO to operate in the
Enhanced Operating Mode. In essence, asserting
EMODE chooses a different default state for the Con-
BOLD ITALIC = Enhanced Operating Mode
2
2048 x 18/4096 x 18 Synchronous FIFOs
trol Register. The system optionally then may program the Control Register in any desired manner to
activate or deactivate any or all of the Enhanced-Operating-Mode features which it can control, including
selectable-clock-edge flag synchronization, and read
inhibition when the data outputs are disabled.
Whenever EMODE is being asserted, interlockedoperation paralleling also is available, by appropriate
interconnection of the FIFO’s expansion inputs.
The retransmit facility is available during standalone
operation, in either IDT-Compatible Operating Mode or
Enhanced Operating Mode (see Tables 1 and 2). It is
inoperative if the FL/RT input signal is grounded. It is not
an IDT72235B/45B feature. The Retransmit control
signal causes the internal FIFO read-address pointer
to be set back to zero, without affecting the internal
FIFO write-address pointer. Thus, the Retransmit
control signal also provides a mechanism whereby a
block of data delimited by the zero physical address
and the current write-address-pointer address may
be read out repeatedly, an arbitrary number of times.
The only restrictions are that neither the read-address pointer nor the write-address pointer may
‘wrap around’ during this entire process, and that the
retransmit facility is not available during depth-cascaded operation, either in IDT-Compatible Operating
Mode or in Enhanced Operating Mode (see Tables 1
and 2). Also, the flags behave differently for a short
time after a retransmit operation. Otherwise, the retransmit facility is available during standalone operation, in either IDT-Compatible Operating Mode or
Enhanced Operating Mode.
Note that, when FL/RT is being used as RT, RT is
an assertive-HIGH signal, rather than assertive-LOW
as it is in most other FIFOs having a retransmit
facility.
Programming the programmable-flag offsets, the timing synchronization of the various status flags, the
optional read-suppression functionality of OE, and
the behavior of the pointers which access the offsetvalue registers and the Control Register may be individually controlled by asserting the signal LD, without any
reset operation. When LD is being asserted, and writing
is being enabled by asserting WEN, some portion of the
input bus word D0 – D17 is used at the next rising edge of
WCLK to program one or more of the programmable
registers on successive write clocks. Likewise, the values
programmed into these programmable registers may be
read out for verification by asserting LD and REN, with
the outputs Q0 – Q17 enabled. Reading out these programmable registers should not be initiated while they are
being written into. Table 3 defines the possible modes of
operation for loading and reading out the contents of
programmable registers.
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
In the Enhanced Operating Mode, coordinated operation of two 18-bit FIFOs as one 36-bit FIFO may be
ensured by ‘interlocked’ crosscoupling of the statusflag outputs from each FIFO to the expansion inputs
of the other one; that is, FF to WXI/WEN2, and EF to
RXI/REN2, in both directions between two paralleled
FIFOs. This ‘interlocked’ operation takes effect
automatically, if two paralleled FIFOs are crossconnected in this manner, with the EMODE control input
being asserted (LOW) (see Tables 1 and 2, also Figures 28 and 31). IDT-compatible depth cascading no
longer is available when operating in this ‘interlocked-paralleled’ mode; however, pipelined depth
cascading remains available.
1
68 67 66 65 64 63 62 61
60
Q16
Q15
2
VSS
3
Q17
VCC
4
VCC
RS
5
EF
OE
6
VSS
LD
7
REN
D17
8
VSS
D16
9
RCLK
D15
TOP VIEW
D14
10
VCC
D13
11
59
Q14
D12
12
58
Q13
D11
13
57
VSS
D10
14
56
Q12
D9
15
55
Q11
VCC
16
54
VCC
D8
17
53
Q10
VSS
18
52
Q9
D7
19
51
VSS
D6
20
50
Q8
D5
21
49
Q7
D4
22
48
EMODE
D3
23
47
Q6
BOLD ITALIC = Enhanced Operating Mode.
Q4
VCC
Q3
Q2
VSS
Q1
Q0
WXO/HF
RXO/EF2
FF
RXI/REN2
PAF
26
44
27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43
VCC
D0
WXI/WEN2
VSS
WEN
Q5
45
WCLK
46
25
FL/RT
24
PAE
D2
D1
540235-2
Figure 2. Pin Connections for PLCC Package
BOLD ITALIC = Enhanced Operating Mode
3
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
VCC
Q15
VSS
Q16
Q17
EF
VSS
VCC
RS
OE
LD
REN
RCLK
VSS
D17
TOP VIEW
D16
64-PIN TQFP
64 63 62 61 60 59 58 57 56 55 54 53 52 51 50 49
D15
1
48
Q14
D14
2
47
Q13
D13
3
46
VSS
D12
4
45
Q12
D11
5
44
Q11
D10
6
43
VCC
D9
7
42
Q10
D8
8
41
Q9
D7
9
40
VSS
D6
10
39
Q8
D5
11
38
Q7
D4
12
37
Q6
D3
13
36
Q5
D2
14
35
VSS
D1
15
34
Q4
D0
16
33
EMODE
Q3
Q2
VSS
Q1
Q0
RXO/EF2
WXO/HF
FF
RXI/REN2
VCC
PAF
WXI/WEN2
WEN
WCLK
FL/RT
PAE
17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32
NOTE: BOLD ITALIC = Enhanced operating mode.
540235-34
Figure 3. Pin Connections for Thin Quad Flat Package
SUMMARY OF SIGNALS/PINS
PIN
NAME
NAME
Data Inputs
WXI/WEN2
RS
Reset
FF
Full Flag
EMODE
Enhanced Operating Mode
PAF
Programmable Almost-Full Flag
WCLK
Write Clock
WXO/HF
Write Expansion Output/Half-Full Flag
WEN
Write Enable
PAE
Programmable Almost-Empty Flag
RCLK
Read Clock
EF
Empty Flag
REN
Read Enable
RXO/EF2
Read Expansion Output/Empty Flag 2
OE
Output Enable
Q0 – Q17
Data Outputs
LD
Load
VCC
Power
FL/RT
First Load/Retransmit
VSS
Ground
RXI/REN2
Read Expansion Input/Read Enable 2
D0 – D17
BOLD ITALIC = Enhanced Operating Mode
4
PIN
Write Expansion Input/Write Enable 2
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
PIN LIST
SIGNAL NAME
PLCC PIN NO.
TQFP PIN NO.
RS
1
57
OE
2
LD
SIGNAL NAME
PLCC PIN NO.
TQFP PIN NO.
Q1
39
29
58
Q2
41
31
3
59
Q3
42
32
REN
4
60
Q4
44
34
RCLK
5
61
Q5
46
36
D17
7
63
Q6
47
37
D16
8
64
EMODE
48
33
D15
9
1
Q7
49
38
D14
10
2
Q8
50
39
D13
11
3
Q9
52
41
D12
12
4
Q10
53
42
D11
13
5
Q11
55
44
D10
14
6
Q12
56
45
D9
15
7
Q13
58
47
D8
17
8
Q14
59
48
D7
19
9
Q15
61
50
63
52
D6
20
10
Q16
D5
21
11
Q17
64
53
D4
22
12
EF
66
54
D3
23
13
VSS
6
62
D2
24
14
VCC
16
NC
D1
25
15
VSS
18
NC
D0
26
16
VCC
32
22
PAE
27
17
VSS
40
30
FT/RT
28
18
VCC
43
NC
WCLK
29
19
VSS
45
35
WEN
30
20
VSS
51
40
WXI/WEN2
31
21
VCC
54
43
PAF
33
23
VSS
57
46
RXI/REN2
34
24
VCC
60
49
FF
35
25
VSS
62
51
WXO/HF
36
26
VCC
65
NC
RXO/EF2
37
27
VSS
67
55
Q0
38
28
VCC
68
56
BOLD ITALIC = Enhanced Operating Mode
5
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
PIN DESCRIPTIONS
PIN
D0 – D17
RS
EMODE
WCLK
WEN
RCLK
REN
OE
NAME
PIN
TYPE 1
Data Inputs
Reset
Enhanced
Operating
Mode
Write Clock
Write Enable
Read Clock
Read Enable
Output Enable
BOLD ITALIC = Enhanced Operating Mode
6
DESCRIPTION
I
Data inputs from an 18-bit bus.
I
When RS is taken LOW, the FIFO’s internal read and write pointers are set to
address the first physical location of the RAM array; FF, PAF, and HF go HIGH;
and PAE and EF go LOW. The programmable-flag-offset registers and the
Control Register are set to their default values. (But see the description of
EMODE, below.) A reset operation is required before an initial read or write
operation after power-up.
I
When EMODE is tied LOW, the default setting for Control Register bits 0005 after a reset operation changes to HIGH rather than LOW, thus enabling
all Control-Register-controllable Enhanced Operating Mode features, and
allowing access to the Control Register for reprogramming or readback
(see Tables 1, 2, and 5). If this behavior is desired, EMODE may be
grounded; however, Control Register bits 00-06 still may be individually
programmed to selectively enable or disable certain of the Enhanced Mode
features, even though those features associated with interlocked-paralleled
operation always are enabled whenever EMODE is being asserted (see
Table 2). Alternatively, EMODE may be tied to VCC, so that the FIFO is
functionally IDT-compatible, and the Control Register is not accessible or
visible, and all of its bits remain LOW. Controlling EMODE dynamically
during system operation is not recommended.
I
Data is written into the FIFO on a LOW-to-HIGH transition of WCLK, whenever
WEN (Write Enable) is being asserted (LOW), and LD is HIGH. If LD is LOW, a
programmable register rather than the internal FIFO memory is written into. In
the Enhanced Operating Mode, whenever Control Register bit 06 is HIGH,
WEN2 is ANDed with WEN to produce an effective internal write-enable
signal. 2
I
When WEN is LOW and LD is HIGH, an 18-bit data word is written into the FIFO
on every LOW-to-HIGH transition of WCLK. When WEN is HIGH, the FIFO
internal memory continues to hold the previous data (see Table 3). Data will not
be written into the FIFO if FF is LOW. In the Enhanced Operating Mode,
whenever Control Register bit 06 is HIGH, WEN2 is ANDed with WEN to
produce an effective internal write-enable signal. 2
I
Data is read from the FIFO on a LOW-to-HIGH transition of RCLK whenever
REN (Read Enable) is being asserted (LOW), and LD is HIGH. If LD is LOW, a
programmable register rather than the internal FIFO memory is read from. In the
Enhanced Operating Mode, whenever Control Register bit 06 is HIGH, REN2
is ANDed with REN (and whenever Control Register bit 05 is HIGH, also
with OE) to produce an effective internal read-enable signal. 2
I
When REN is LOW and LD is HIGH, an 18-bit data word is read from the FIFO
on every LOW-to-HIGH transition of RCLK. When REN is HIGH, and/or also
when EF is LOW, the FIFO’s output register continues to hold the previous data
word, whether or not Q0 – Q17 (the data outputs) are enabled (see Table 3). In
the Enhanced Operating Mode, whenever Control Register bit 06 is HIGH,
REN2 is ANDed with REN (and whenever Control Register bit 05 is HIGH,
also with OE) to produce an effective internal read-enable signal. 2
I
When OE is LOW, the FIFO’s data outputs drive the bus to which they are
connected. If OE is HIGH, the FIFO’s outputs are in high-Z (high-impedance)
state. In the Enhanced Operating Mode, OE not only continues to control
the outputs in this same manner, but also can function as an additional
ANDing input to the combined effective read-enable signal, along with REN
and REN2, whenever Control Register bit 05 is HIGH (see Table 5). 2
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
PIN DESCRIPTIONS (cont’d)
PIN
NAME
PIN
TYPE 1
LD
Load
I
WEN2
Write Enable 2
I
REN2
Read Enable 2
I
FF
Full Flag
O
PAF
Programmable
Almost-Full Flag
O
HF
Half-Full Flag
O
PAE
Programmable
Almost-Empty
Flag
O
EF
Empty Flag
O
EF2
Empty Flag 2
O
Q0 – Q17
VCC
VSS
Data Outputs
Power
Ground
O/Z
V
V
DESCRIPTION
When LD is LOW, the data word on D0 – D17 (the data inputs) is written into a
programmable-flag-offset register, or into the Control Register (when in the
Enhanced Operating Mode), on the LOW-to-HIGH transition of WCLK, whenever
WEN is LOW (see Table 3). Also, when LD is LOW, a word is read to Q0 – Q17 (the
data outputs) from the offset registers and/or the Control Register (when in the
Enhanced Operating Mode) on the LOW-to-HIGH transition of RCLK, whenever
REN is LOW (see again Table 3, and particularly the Notes following this table).
When LD is HIGH, normal FIFO write and read operations are enabled.
Tie LOW in Standard Mode, cascading is not supported. In the Enhanded
Operating Mode, whenever Control Register Bit06 is HIGH, WXI/WEN2
functions as a second write-enable signal, WEN2, which is ANDed with WEN
to produce an effective internal write-enable signal.
Tie LOW in Standard Mode. In the Enhanced Operating Mode, whenever
Control Register Bit06 is HIGH, RXI/REN2 functions as a second read-enable
signal, REN2, which is ANDed with REN to produce an effective internal readenable signal.
When FF is LOW, the FIFO is full; further advancement of its internal write-address
pointer, and further data writes through its Data Inputs into its internal memory
array, are inhibited. When FF is HIGH, the FIFO is not full. FF is synchronized to
WCLK.
When PAF is LOW, the FIFO is ‘almost full,’ based on the almost-full-offset value
programmed into the FIFO’s Almost-Full Offset Register. The default value of this
offset at reset is 12710, measured from ‘full’ (see Table 4). In the IDT-Compatible
Operating Mode, PAF is asynchronous. In the Enhanced Operating Mode, PAF is
synchronized to WCLK after a reset operation, according to the state of
Control Register bit 04 (see Table 5).
In the standalone or paralleled configuration, whenever HF is LOW the device is
more than half full. In IDT-Compatible Operating Mode, HF is asynchronous; in the
Enhanced Operating Mode, HF may be synchronized either to WCLK or to
RCLK after a reset operation, according to the state of Control Register bits
02 and 03 (see Table 5).
When PAE is LOW, the FIFO is ‘almost empty,’ based on the almost-empty-offset
value programmed into the FIFO’s Almost-Empty Offset Register. The default value
of this offset at reset is 12710, measured from ‘empty’ (see Table 4). In IDTCompatible Operating Mode, PAE is asynchronous. In the Enhanced Operating
Mode, PAE is synchronized to RCLK after a reset operation, according to the
state of Control Register bit 01. (See Table 5.)
When EF is LOW, the FIFO is empty; further advancement of its internal readaddress pointer, and further readout of data words from its internal memory array to
its Data Outputs, are inhibited. When EF is HIGH, the FIFO is not empty. EF is
synchronized to RCLK.
In the Enhanced Operating Mode, Control Register bit 06 is HIGH, EF2
behaves as an exact duplicate of EF, but delayed by one full cycle of RCLK
with respect to EF.
Data outputs to drive an 18-bit bus.
+3.3 V power-supply pins.
0 V ground pins.
NOTES:
1 I = Input, O = Output, Z = High-Impedance, V = Power Voltage Level
2 The ostensible differences in signal assertiveness are reconciled before ANDing.
BOLD ITALIC = Enhanced Operating Mode
7
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
ABSOLUTE MAXIMUM RATINGS
PARAMETER
+5 V
RATING
Supply Voltage to VSS Potential
–0.5 V to 7 V
Signal Pin Voltage to VSS Potential
–0.5 V to VCC + 0.5 V
DC Output Current 1
±75 mA
Temperature Range with Power
Applied 2
–55°C to 125°C
Storage Temperature Range
–65°C to 150°C
Power Dissipation (PLCC Package Limit)
2W
1.1 k Ω
DEVICE
UNDER
TEST
680 Ω
30 pF *
* INCLUDES JIG AND SCOPE CAPACITANCES
NOTES:
1. Only one output may be shorted at a time, for a period not
exceeding 30 seconds.
2. Measured with clocks idle.
540235-3
Figure 4. Output Load Circuit
OPERATING RANGE
SYMBOL
PARAMETER
TA
Temperature, Ambient
MIN.
MAX.
UNIT
0
70
C
VCC
Supply Voltage
4.5
5.5
V
VSS
Supply Voltage
0
0
V
VIL
Logic LOW Input Voltage
–0.5
0.8
V
VIH
Logic HIGH Input Voltage
2.0
VCC + 0.5
V
DC ELECTRICAL CHARACTERISTICS (Over Operating Range)
SYMBOL
PARAMETER
TEST CONDITIONS
MIN.
MAX.
UNIT
ILI
Input Leakage
VCC = 5.5 V, VIN = 0 V to VCC
–10
10
µA
ILO
I/O Leakage
OE ≥ VIH, 0 V ≤ VOUT ≤ VCC
–10
10
µA
VOH
Output HIGH Voltage
IOH = –8.0 mA
2.4
VOL
Output LOW Voltage
ICC
ICC2
Average Operating Supply Current
Average Standby Supply Current
2
ICC3
Power-Down Supply Current
ICC4
Power-Down Supply Current 2
2
1,2
V
IOL = 16.0 mA
0.4
V
Measured at fCC = 50 MHz
245
mA
All inputs = VIHMIN (clocks idle)
25
mA
All inputs = VCC – 0.2 V (clocks idle)
1
mA
All inputs = VCC – 0.2 V (clocks at 50 MHz)
1
mA
NOTES:
1. Output load is disconnected.
2. ICC, ICC2, and ICC3 are dependent upon actual output loading, and ICC and ICC4 are also dependent on cycle rates. Specified values are with
outputs open; and, for ICC and ICC4, operating at minimum cycle times.
AC TEST CONDITIONS
PARAMETER
Input Pulse Levels
RATING
VSS to 3 V
Input Rise and Fall Times (10% to 90%)
3 ns
Input Timing Reference Levels
1.5 V
Output Timing Reference Levels
1.5 V
Output Load,
Timing Tests
(Figure 5)
R1 (Top Resistor)
1.1k Ω
R2 (Bottom Resistor)
680 Ω
CL (Load Capacitance)
30 pF
BOLD ITALIC = Enhanced Operating Mode
8
CAPACITANCE
PARAMETER
RATING
CIN (Input Capacitance) VIN = 0 V
9 pF
COUT (Output Capacitance) VOUT = 0 V
9 pF
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
AC ELECTRICAL CHARACTERISTICS
SYMBOL
–20
PARAMETER
MIN.
–25
MAX.
MIN.
-35
MAX.
MIN.
fCC
Clock Cycle Frequency
tA
Data Access Time
2
tCLK
Clock Cycle Time
20
25
35
tCLKH
Clock HIGH Time
8
10
14
tCLKL
Clock LOW Time
8
10
14
tDS
Data Setup Time
5
6
7
tDH
Data Hold Time
2
2
2
tENS
Enable Setup Time
5
6
7
tENH
Enable Hold Time
2
2
2
20
25
35
12
15
20
12
15
20
tRS
tRSS
Reset Pulse Width
Reset Setup Time
50
1
2
2
tRSR
Reset Recovery Time
tRSF
Reset to Flag and Output Time
tOLZ
Output Enable to Output in Low-Z
tOE
Output Enable to Output Valid
12
40
3
30
2
0
28.6
3
35
0
9
2
15
MAX.
20
40
0
12
15
tOHZ
Output Enable to Output in High-Z
tWFF
Write Clock to Full Flag
12
15
20
tREF
Read Clock to Empty Flag
12
15
20
tPAF
Clock to Programmable Almost-Full Flag (IDT-Compatible
Operating Mode)
14
17
23
tPAE
Clock to Programmable Almost-Empty Flag (IDT-Compatible
Operating Mode)
14
17
23
tHF
Clock to Half-Full Flag (IDT-Compatible Operating Mode)
14
17
23
tPAFS
Clock to Programmable Almost-Full Flag (Enhanced
Operating Mode)
14
17
23
tPAES
Clock to Programmable Almost-Empty Flag (Enhanced
Operating Mode)
14
17
23
tHFS
Clock to Half-Full Flag (Enhanced Operating Mode)
14
17
23
tXO
Clock to Expansion-Out
12
15
20
tXI
Expansion-In Pulse Width
8
9
13
tXIS
Expansion-In Setup Time
8
9
14
tSKEW1
Skew Time Between Read Clock and Write Clock for Full Flag 3
9
11
16
9
11
16
tSKEW2
1
Skew Time Between Write Clock and Read Clock for Empty Flag
4
9
1
12
1
15
NOTES:
1. Pulse widths less than the stated minimum values may cause incorrect operation.
2. Values are guaranteed by design; not currently tested.
3. These times also apply to the Programmable-Almost-Full and Half-Full flags when they are synchronized to WCLK.
4. These times also apply to the Half-Full and Programmable-Almost-Empty flags when they are synchronized to RCLK.
BOLD ITALIC = Enhanced Operating Mode
Rev. B, 8/8/96
9
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
DESCRIPTION OF SIGNALS AND OPERATING SEQUENCES
Table 1. Grouping-Mode Determination
During a Reset Operation 5
WXO/HF
USAGE
WXI/WEN2
USAGE
Cascaded
Slave 2
WXO
WXI
RXI
FL
RXO
L
Cascaded
Master 2
WXO
WXI
RXI
FL
RXO
L
X
(Reserved)
–
–
–
–
–
H
X
(Reserved)
–
–
–
–
–
(HF)
(none)
(none)
(RT)
(none)
EMODE
WXI/WEN2
RXI/REN2
FL/RT
H1
H
H
H
H1
H
H
H
H
H
L
MODE
RXI/REN2
USAGE
FL/RT
USAGE
RXO/EF2
USAGE
H
L
L
H3
(Not
Allowed
During
Reset)
H
L
L
L3
Standalone
HF
(none)
(none)
RT
(none)
3
(Not
Allowed
During
Reset)
(HF)
(WEN2)
(REN2)
(RT)
(EF2)
Interlocked
Paralleled 4
HF
WEN2
REN2
RT
EF2
L
X
X
H
L
X
X
L3
NOTES:
1. In IDT-compatible cascading, a reset operation forces WXO/HF and RXO/EF2 HIGH for the nth FIFO, thus forcing WXI/WEN2 and RXI/REN2
HIGH for the (n + 1)st FIFO.
2. The terms ‘master’ and ‘slave’ refer to IDT-compatible cascading. In pipelined cascading4, there is no such distinction.
3. Once grouping mode has been determined during a reset operation, FL/RT then may go HIGH to activate a retransmit operation.
4. EMODE must be asserted for access to the Control Register to be enabled. Also, FIFOs being used in a pipelined-cascading
configuration should be in Interlocked Paralleled mode.
5. Setup-time and recovery-time specifications apply during a reset operation.
Table 2. Expansion-Pin Usage According to
Grouping Mode
ENHANCED
OPERATING MODE
IDT-COMPATIBLE OPERATING MODE
I/O
PIN
DEPTH-CASCADED
MASTER
DEPTH-CASCADED
SLAVE
I
WXI /WEN2
From WXO ((n-1)st FIFO)
From WXO ((n-1)st FIFO)
Grounded
From FF (other FIFO)
O
WXO/HF
To WXI ((n+1)st FIFO)
To WXI ((n+1)st FIFO)
Becomes HF
Becomes HF
I
RXI/REN2
From RXO ((n-1)st FIFO)
From RXO ((n-1)st FIFO)
Grounded
From EF (other FIFO)
O
RXO/EF2
To RXI ((n+1)st FIFO)
To RXI ((n+1)st FIFO)
Unused
I
FL/RT
Grounded (Logic LOW)
Logic HIGH
NOTE:
1. FL/RT may be grounded if the Retransmit facility is not being used.
BOLD ITALIC = Enhanced Operating Mode
10
INTERLOCKED
PARALLELED
STANDALONE
Becomes EF2
1
Becomes RT
Becomes RT1
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
Table 3. Selection of Read and Write Operations
LD
WEN
3,4
REN
3,4
WCLK
RCLK
ACTION
L
X
X
–
–
No operation.
L
L
L
∧
∧
Illegal combination, which will cause errors.
L
L
H
∧
X
Write to a programmable register. 1
L
H
H
∧
X
Hold present value of programmable-register write counter, and do not write. 2
L
H
L
X
∧
Read from a programmable register. 1
L
H
H
X
∧
Hold present value of programmable-register read counter, and do not read. 2
H
L
X
∧
X
Normal FIFO write operation.
H
X
L
X
∧
Normal FIFO read operation.
H
L
X
–
X
No write operation.
H
H
X
X
X
No write operation.
H
X
L
X
–
No read operation.
H
X
H
X
X
No read operation.
H
L
L
–
–
No operation.
H
H
H
X
X
No operation.
KEY:
H = Logic ‘HIGH’; L = Logic ‘LOW’; X = ‘Don’t-care’ (logic ‘HIGH,’ logic ‘LOW,’ or any transition);
∧ = A ‘LOW’-to-‘HIGH’ transition; – = Any condition EXCEPT a ‘LOW’-to-‘HIGH’ transition.
NOTES:
1. The selection of a programmable register to be written or read is controlled by two simple state machines. One state machine controls the selection for writing; the other state machine controls the selection for reading. These two state machines operate independently of each other.
Both state machines are reset to point to Word 0 by a reset operation. In the Enhanced Operating Mode, if Control Register bit 00 is set,
both state machines are also reset to point to Word 0 by deassertion of LD after LD has been asserted (that is, by a rising edge of
LD), followed by a valid memory array write cycle for the writing-control state machine and/or by a valid memory array read cycle
for the reading-control state machine.
2. The order of the two programmable registers which are accessible in IDT-Compatible Operating Mode, as selected by either state machine, is
always:
Word 0: Almost-Empty Offset Register
Word 1: Almost-Full Offset Register
Word 0: Almost-Empty Offset Register
...
(repeats indefinitely)
...
The order of the three programmable registers which are accessible in Enhanced Operating Mode, as selected by either state
machine, is always:
Word 0: Almost-Empty Offset Register
Word 1: Almost-Full Offset Register
Word 2: Control Register
Word 0: Almost-Empty Offset Register
…
(repeats indefinitely)
…
Note that, in IDT-Compatible Operating Mode, Word 2 is not accessed; Word 0 and Word 1 alternate.
3. After normal FIFO operation has begun, writing new contents into either of the offset registers should only be done when the FIFO is empty.
4. WEN2, REN2, and OE may be ANDed terms in the enabling of read and write operations, according to the state of the EMODE control
input and of Control Register bit 05.
BOLD ITALIC = Enhanced Operating Mode
11
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
Table 4. Status Flags
NUMBER OF UNREAD DATA WORDS PRESENT WITHIN FIFO 1, 2
2048 × 18 FIFO
FULL
FLAG
EMPTY
FLAG
MIDDLE FLAGS
4096 × 18 FIFO
FF
PAF
HF
PAE
EF
0
0
H
H
H
L
L
1 to q
1 to q
H
H
H
L
H
(q + 1) to 1024
(q + 1) to 2048
H
H
H
H
H
1025 to (2048 – (p + 1))
2049 to (4096 – (p + 1))
H
H
L
H
H
(2048 – p) to 2047
(4096 – p) to 4095
H
L
L
H
H
2048
4096
L
L
L
H
H
NOTES:
1. q = Programmable-Almost-Empty Offset value. (Default value: q = 127.)
2. p = Programmable-Almost-Full Offset value. (Default value: p = 127.)
3. Only 11 (2048 × 18), or all 12 (4096 × 18), of the 12 offset-value-register bits should be programmed. The unneeded most-significant-end
2048 × 18 bit should be LOW (zero).
4. The flag output is delayed by one full clock cycle in Enhanced Operating Mode, when synchronous operation is specified for intermediate flags.
BOLD ITALIC = Enhanced Operating Mode
12
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
DESCRIPTION OF SIGNALS AND OPERATING SEQUENCES (cont’d)
Table 5. Control-Register Format
COMMAND
REGISTER
BITS
VALUE AFTER RESET
CODE
EMODE = H
EMODE = L
FLAG
AFFECTED,
IF ANY
DESCRIPTION
–
Deassertion of LD does not
reset the programmableregister write pointer and
read pointer.
Deassertion of LD resets
the programmable-register
write pointer and read
pointer to address Word 0,
the Programmable-AlmostEmpty-Flag-Offset Register.
The change takes effect
after a valid write operation
or a valid read operation,
respectively, to the memory
array.
L
00
L
H
H
01
03, 02
H
Set and reset by ↑RCLK.
Synchronous flag clocking.
LL
Set by ↑WCLK, reset by
↑RCLK.
Asynchronous flag
clocking.
Set and reset by ↑RCLK.
Set and reset by ↑WCLK.
Synchronous flag clocking
at output port.
Synchronous flag clocking
at input port.
Set by ↑WCLK, reset by
↑RCLK.
Asynchronous flag
clocking.
Set and reset by ↑WCLK.
OE has no effect on an
internal read operation,
apart from disabling the
outputs.
Deassertion of OE inhibits
a read operation; whenever
the data outputs Q0 – Q17
are in the high-Z state, the
read pointer does not
advance.
Synchronous flag clocking.
Allows the read-address
pointer to advance even
when Q0 – Q17 are not
driving the output bus.
Inhibits the read-address
pointer from advancing
when Q0 – Q17 are not
driving the output bus;
thus, guards against data
loss.
Future use to control depth
cascading and interlocked
paralleling.
LH
H
LL
HH
PAE
HF
L
L
H
PAF
L
05
L
H
–
L
L
–
Reserved.
LLLLL
LLLLL
–
Reserved.
H
L
11, 10,
09, 08, 07
Non-ambiguous
addressing of
programmable registers.
Asynchronous flag
clocking.
L
H
06
IDT-compatible addressing
of programmable registers.
Set by ↑RCLK, reset by
↑WCLK.
L
HL,
HH
04
NOTES
H
LLLLL
Reserved.
NOTES:
1. When EMODE is HIGH, and Control Register bits 00-05 are LOW, the FIFO behaves in a manner functionally equivalent to the
IDT72235B/45B FIFO of similar depth and speed grade. Under these conditions, the Control Register is not visible or accessible to the external system which includes the FIFO.
2. If EMODE is not asserted (is HIGH), Control Register bits 00-05 remain LOW after a reset operation. However, if EMODE is asserted (is
LOW) during a reset operation, Control Register bits 00-05 are forced HIGH, and remain HIGH until changed. Control Register bits
06-11 are unaffected by EMODE.
BOLD ITALIC = Enhanced Operating Mode
13
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
Data Inputs
WRITE CLOCK (WCLK)
DATA IN (D0 – D17)
A rising edge (LOW-to-HIGH transition) of WCLK initiates a FIFO write cycle if LD is HIGH, or a programmable-register write cycle if LD is LOW. The 18 data inputs,
and all input-side synchronous control inputs, must meet
setup and hold times with respect to the rising edge of
WCLK. The input-side status flags are meaningful after
specified time intervals, following a rising edge of WCLK.
Data, programmable-flag-offset values, and ControlRegister codes are input to the FIFO as 18-bit words on
D0 – D17. Unused bit positions in offset-value and Control-Register words should be zero-filled.
Control Inputs
RESET (RS)
The FIFO is reset whenever the asynchronous Reset
(RS) input is taken to a LOW state. A reset operation is
required after power-up, before the first write operation
may occur. The state of the FIFO is fully defined after a
reset operation. If the default values which are entered
into the Programmable-Flag-Offset-Value Registers and
the Control Register by a reset operation are acceptable, then no device programming is required. A reset
operation initializes the FIFO’s internal read-address and
write-address pointers to the FIFO’s first physical memory
location. The five status flags, FF, PAF, HF, PAE, and EF,
are updated to indicate that the FIFO is completely empty;
thus, the first three of these are reset to HIGH, and the
last two are reset to LOW. The flag-offset values for PAF
and PAE each are initialized to 12710. If EMODE is not
being asserted (i.e., if EMODE is HIGH), all Control
Register bits are initialized to LOW, to configure the FIFO
to operate in the IDT72235B/45B-Compatible Operating
Mode. Until a write operation occurs, the data outputs
D0 – D17 all are LOW whenever OE is LOW.
ENHANCED OPERATING MODE (EMODE)
Whenever EMODE is asserted during a reset operation, Control Register bits 00-05 remain HIGH
rather than LOW after the completion of the reset
operation. Thus, EMODE has the effect of activating
all of the Enhanced-Operating-Mode features during
a reset operation. Subsequently, they may be individually disabled or re-enabled by changing the setting of Control-Register bits. The behavior of these
Enhanced-Operating-Mode features is described in
Table 5. For permanent Enhanced-Operating-Mode
operation, EMODE must be grounded; dynamic control of EMODE during system operation is not recommended.
Asserting EMODE during a reset operation also
causes WXI/WEN2 to be configured as WEN2, and
RXI/REN2 to be configured as REN2, to support interlocked-paralleled operation of two FIFOs ‘side by
side’ (see Figure 28). Additionally, RXO/EF2 is configured as EF2, which duplicates the EF signal with one
extra RCK cycle delay, in order to provide proper
timing for ‘pipelined’ cascaded operation.
BOLD ITALIC = Enhanced Operating Mode
14
Conceptually, the WCLK input receives a free-running,
periodic ‘clock’ waveform, which is used to control other
signals which are edge-sensitive. However, there actually
is not any absolute requirement that the WCLK waveform
must be periodic. An ‘asynchronous’ mode of operation
is in fact possible, if WEN is continuously asserted (that
is, is continuously held LOW), and WCLK receives aperiodic ‘clock’ pulses of suitable duration. There likewise is
no requirement that WCLK must have any particular
synchronization relation to the read clock RCLK. These
two clock inputs may in fact receive the same ‘clock’
signal; or they may receive totally-different signals, which
are not synchronized to each other in any way.
WRITE ENABLE (WEN)
Whenever WEN is being asserted (is LOW) and LD is
HIGH, and the FIFO is not full, an 18-bit data word is
loaded into the effective input register for the memory
array at every WCLK rising edge (LOW-to-HIGH transition). Data words are stored into the two-port memory
array sequentially, regardless of any ongoing read operation. Whenever WEN is not being asserted (is HIGH), the
input register retains whatever data word it contained
previously, and no new data word gets loaded into the
memory array.
To prevent overrunning the internal FIFO boundaries,
further write operations are inhibited whenever the Full
Flag (FF) is being asserted (is LOW). If a valid read
operation then occurs, upon the completion of that read
cycle FF again goes HIGH after a time tWFF, and another
write operation is allowed to begin whenever WCLK
makes another LOW-to-HIGH transition. Effectively,
WEN is overridden by FF; thus, during normal FIFO
operation, WEN has no effect when the FIFO is full.
In the Enhanced Operating Mode, WXI/WEN2 functions as WEN2, an additional duplicate (albeit assertive-HIGH) write-enable input, in order to provide
an‘interlocking’ mechanism for reliable synchronization of two paralleled FIFOs. To control writing,
WEN2 is ANDed with WEN; this logic-AND function
(WEN • WEN2) then behaves like WEN in the foregoing description.
2048 x 18/4096 x 18 Synchronous FIFOs
DESCRIPTION OF SIGNALS AND
OPERATING SEQUENCES (cont’d)
READ CLOCK (RCLK)
A rising edge (LOW-to-HIGH transition) of RCLK initiates a FIFO read cycle if LD is HIGH, or a programmable-register read cycle if LD is LOW. All output-side
synchronous control inputs must meet setup and hold
times with respect to the rising edge of RCLK. The 18 data
outputs, and the output-side status flags, are meaningful
after specified time intervals, following a rising edge of
RCLK.
Conceptually, the RCLK input receives a free-running,
periodic ‘clock’ waveform, which is used to control other
signals which are edge-sensitive. However, there actually
is not any absolute requirement that the RCLK waveform
must be periodic. An ‘asynchronous’ mode of operation
is in fact possible, if REN is continuously asserted (that
is, is continuously held LOW), and RCLK receives aperiodic ‘clock’ pulses of suitable duration. There likewise is
no requirement that RCLK must have any particular
synchronization relation to the write clock WCLK. These
two clock inputs may in fact receive the same ‘clock’
signal; or they may receive totally-different signals, which
are not synchronized to each other in any way.
READ ENABLE (REN)
Whenever REN is being asserted (is LOW), and the
FIFO is not empty, an 18-bit data word is loaded into the
output register from the memory array at every RCLK
rising edge (LOW-to-HIGH transition). Data words are
read from the two-port memory array sequentially, regardless of any ongoing write operation. Whenever REN is
not being asserted (is HIGH), the output register retains
whatever data word it contained previously, and no new
data word gets loaded into it from the memory array.
To prevent underrunning the internal FIFO boundaries,
further read operations are inhibited whenever the Empty
Flag (EF) is being asserted (is LOW). If a valid write
operation then occurs, upon the completion of that write
cycle EF again goes HIGH after a time tREF, and another
read operation is allowed to begin whenever RCLK
makes another LOW-to-HIGH transition. Effectively, REN
is overridden by EF; thus, during normal FIFO operation,
REN has no effect when the FIFO is empty.
In the Enhanced Operating Mode, one (or, sometimes two) additional read-enable inputs may be
ANDed with REN to control reading, depending on
the state of Control-Register bit 05. The additional
read-enable input(s) are REN2 (and OE).
LH540235/45
Also in the Enhanced Operating Mode, RXI/REN2
functions as REN2, an additional duplicate (albeit
assertive-HIGH) Read-Enable input, in order to provide an ‘interlocking’ mechanism for reliable
synchronization of two paralleled FIFOs.
Also, if Control Register bit 05 is HIGH, OE takes
on the extra role of serving as yet another duplicate
read-enable input, in addition to its usual function of
controlling the FIFO’s data outputs, in order to inhibit
further read operations whenever the FIFO’s data
outputs are disabled, and thereby to prevent data
loss under some circumstances.
OUTPUT ENABLE (OE)
OE is an assertive-LOW, asynchronous, output
enable. In the IDT-Compatible Operating Mode, OE has
only the effect of enabling or disabling the data outputs
Q0 – Q17. That is, disabling Q0 – Q17 does not inhibit a
read operation, for data being transmitted to the output
register; the same data will remain available later, when
the outputs are again enabled, unless subsequently overwritten. When Q0 – Q17 are enabled, each of these 18
data outputs is in a normal HIGH or LOW state, according
to the bit pattern of the data word in the output register.
When Q0 – Q17 are disabled, each of these outputs is in
the high-Z (high-impedance) state.
In the Enhanced Operating Mode, if Control Register bit 05 is HIGH, OE behaves as an additional
read-enable control input, as well as enabling and
disabling the data outputs Q0 – Q17. Under these
circumstances, incrementing the read-address
pointer is inhibited whenever Q0 – Q17 are in the
high-Z state. Thus, ‘reading’ successive words which
fail ever to reach the outputs is prevented, as a
safeguard against data loss.
LOAD (LD)
The Sharp LH540235/45 FIFOs contain three 18-bit
programmable registers. The contents of these three
registers may be loaded with data from the data inputs
D0 – D17, or read out onto the data outputs Q0 – Q17. The
first two registers are the Programmable-Flag-OffsetValue Registers, for the Programmable Almost-Empty
Flag (PAE) and the Programmable Almost-Full Flag (PAF)
respectively. The third register is the Control Register,
which includes several configuration-control bits
for selectively enabling and disabling Sharp’s
Enhanced-Operating-Mode features.
BOLD ITALIC = Enhanced Operating Mode
15
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
3
WORD 0
17
12
PROGRAMMABLE-ALMOST-EMPTY-FLAG-OFFSET VALUE 1, 2
11
10
3
WORD 1
17
12
0
PROGRAMMABLE-ALMOST-FULL-FLAG-OFFSET VALUE 1, 2
11
10
0
CONTROL REGISTER 4, 5
WORD 2
Reserved for
future use.
17
12
6
11
7
6
5
5
4
3
4
1
2
3
2
0
1
0
CONTROL-REGISTER BITS:
6 Future use to control depth cascading and interlocked paralleling.
5 Enables suppressing reading whenever data outputs are disabled.
See Table 5 for a
more complete
description of these
effects.
4 Makes PAF synchronous.
3
2 Makes HF synchronous. (See the Control-Register Format
table for the encoding of bits 02-03.)
1 Makes PAE synchronous.
0 Selects reinitialized addressing of the programmable registers.
NOTES:
1. Default offset values all are 12710 = 7F16.
2. Bits 11-17 (LH540235) or bits 12-17 (LH540245) of both offset-value registers should
in all cases be programmed LOW (zero).
3. This bit position is used for offset values in the LH540245 only. In the LH540235, it
always should be programmed LOW.
4. See the Control-Register Format table for the default states of the Control Register,
for EMODE = HIGH (IDT-Compatible Operating Mode) and for EMODE = LOW (Enhanced Operating Mode).
The Control Register is not accessible or visible in IDT-Compatible Operating Mode.
5. The assertion of EMODE (LOW) forces Control Register bits 00-05 HIGH during a reset operation.
After that, these bits may be programmed at will.
= Reserved. Do not load with non-zero information.
BOLD ITALIC = Enhanced Operating Mode.
540235-4
Figure 5. Programmable Registers
None of these three registers makes use of all of its
available 18 bits. Figure 6 shows which bit positions of
each register are operational. The two ProgrammableFlag-Offset-Value Registers each contain an offset value
in bits 0-10 (LH540235) or bits 0-11 (LH540245); bits
11-17 (LH540235) or bits 12-17 (LH540245) are unused.
The default values for both offsets are 12710.
The Control Register configuration is shown in Figure 6 and in Table 5. For the Control Register, in the
IDT-Compatible Operating Mode, with EMODE deasserted (HIGH), the default value for all Control-Register
bits is zero (LOW). In the Enhanced Operating Mode,
with EMODE asserted (LOW), the default value for
bits 00-05 is HIGH, and the default value for bits 06-11
is LOW.
BOLD ITALIC = Enhanced Operating Mode
16
Whenever LD and WEN are simultaneously being
asserted (are both LOW), the 18-bit data word from the
data inputs D0 – D17 is written into the ProgrammableAlmost-Empty-Flag-Offset-Value Register at the first rising edge (LOW-to-HIGH transition) of the write clock
(WCLK). (See Table 3.) If LD and WEN continue to be
simultaneously asserted, another 18-bit data word from
the data inputs D0 – D17 is written into the Programmable-Almost-Full-Flag-Offset-Value Register at the second
rising edge of WCLK.
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
DESCRIPTION OF SIGNALS AND
OPERATING SEQUENCES (cont’d)
the same three-step reading sequence gets repeated
on subsequent RCLK rising edges.
What happens next is determined by the state of the
EMODE control input. If it is deasserted (HIGH), the next
18-bit word from the data inputs D0 – D17 is written back
into the Programmable-Almost-Empty-Flag-Offset-Value
Register again.
But, if EMODE is asserted (LOW), then still another
18-bit data word from the data inputs D0 – D17 is
written into the Control Register at the third rising
edge of WCLK. At the fourth rising edge of WCLK,
writing again occurs to the Programmable-AlmostEmpty-Flag-Offset-Value Register; and the same
three-step writing sequence gets repeated on subsequent WCLK rising edges.
The lower 11 bits of these offset-value words are made
use of by the 2048-word LH540235, and the lower 12 bits
by the 4096-word LH540245. Six active bits are used
for the Control Register, by both the LH540235 and
the LH540245. There is no restriction on the values which
may occur in these offset-value and Control-Register
fields. However, reserved bit positions must be encoded
LOW, in order to maintain forward compatibility.
Writing contents to these two or three programmable
registers does not have to occur all at one time, or to be
effected by one single sequence of steps. Whenever LD
is being asserted (is LOW) but WEN is not being asserted
(is HIGH), the FIFO’s internal programmable-registerwrite-address pointer maintains its present value, without
any writing actually taking place at each rising edge of
WCLK (see Table 3). Thus, for instance, one or two
programmable registers may be written, after which the
FIFO may be returned to normal FIFO-array-read/write
operation by deasserting LD (to HIGH).
Likewise, whenever LD and REN are simultaneously
being asserted (are both LOW) the 18-bit data word
(zero-filled as necessary) from the Programmable-Almost-Empty-Flag-Offset-Value Register is read to the
data outputs Q0 – Q17 at the first rising edge (LOW-toHIGH transition) of the read clock (RCLK) (see Table 3).
If LD and REN continue to be simultaneously asserted,
another 18-bit data word from the Programmable-AlmostFull-Flag-Offset-Value Register is read to the data outputs
Q0 – Q17 at the second rising edge of RCLK.
What happens next is determined by the state of the
EMODE control input. If it is deasserted (HIGH), the next
18-bit word again comes from the Programmable-AlmostEmpty-Flag-Offset-Value Register; it is read to the data
outputs Q0 – Q17.
But, if EMODE is asserted (LOW), then the next
18-bit data word instead comes from the Control
Register; it is read to the data outputs Q0 – Q17 at the
third rising edge of RCLK. At the fourth rising edge
of RCLK, reading again occurs from the Programmable-Almost-Empty-Flag-Offset-Value Register; and
Reading contents from these two or three programmable registers does not have to occur all at one time, or
to be effected by one single sequence of steps. Whenever
LD is being asserted (is LOW) but REN is not being
asserted (is HIGH), the FIFO’s internal programmableregister-read-address pointer maintains its present value,
without any reading actually taking place at each rising
edge of RCLK. (See Table 3.) Thus, for instance, one or
two programmable registers may be read, after which the
FIFO may be returned to normal FIFO-array-read/write
operation by deasserting LD (to HIGH).
To ensure correct operation, the simultaneous reading
and writing of a register should be avoided.
FIRST LOAD/RETRANSMIT (FL/RT)
FL/RT is a dual-purpose signal. It is one of four input
signals which select the grouping mode in which the FIFO
operates after being reset; the other three of these input
signals are WXI/WEN2, RXI/REN2, and EMODE. There
are four possible grouping modes: standalone, interlocked paralleled, cascaded ‘master’ or ‘first-load,’ and
cascaded ‘slave.’ The designations ‘master’ and ‘slave’
pertain to IDT-compatible depth cascading. Tables 1 and
2 show the signal encodings which select each grouping
mode.
In standalone or paralleled operation, the FL/RT pin
should be grounded for strict IDT72235B/45B-compatible
operation. However, if it is taken HIGH, regardless of
the state of the EMODE control input, the FIFO’s
internal read-address pointer is reset to address the
FIFO’s first physical memory location, without the
other usual reset actions being taken; in particular,
the FIFO’s internal write-address pointer is unaffected. Subsequent read operations may then again
read out the same block of data, delimited by the
FIFO’s first physical memory location and the current
value of the write pointer, as was read out previously.
There is no limit on the number of times that a block
of data may be retransmitted. The only restrictions
are that neither the read-address pointer nor the
write-address pointer may ‘wrap around’ and address
the FIFO’s first physical memory location a second
time during the retransmission process, and that the
retransmit facility is unavailable during cascaded operation.
In IDT-compatible cascaded operation, FL/RT is
grounded for the ‘master’ or ‘first-load’ FIFO, to distinguish
it from the other ‘slave’ FIFOs in the cascade, which must
all have their FL/RT inputs HIGH during a reset operation
(see again Tables 1 and 2). The cascade will not operate
correctly either without any ‘master’ FIFO, or with more
than one ‘master’ FIFO.
BOLD ITALIC = Enhanced Operating Mode
17
LH540235/45
WRITE EXPANSION INPUT/WRITE ENABLE 2
(WXI/WEN2)
WXI/WEN2 is a dual-purpose signal. It is one of four
input signals which select the grouping mode in which the
FIFO operates after being reset; the other three of these
input signals are FL/RT, RXI/REN2, and EMODE. There
are four possible grouping modes: standalone, interlocked paralleled, cascaded ‘master’ or ‘first-load,’ and
cascaded ‘slave.’ The designations ‘master’ and ‘slave’
pertain to IDT-compatible depth cascading. Tables 1 and
2 show the signal encodings which select each grouping
mode.
In standalone operation, WXI/WEN2 and RXI/REN2
both must be grounded so that the FIFO comes up in the
standalone grouping mode after a reset operation. In
interlocked-paralleled operation, WXI/WEN2 is tied to
FF of the other paralleled FIFO, and RXI/REN2 is tied
to EF of that same other FIFO. This interconnection
scheme ensures that both FIFOs will operate
together, and remain coordinated, regardless of timing skews.
In cascaded operation, WXI/WEN2 is connected to the
WXO (Write Expansion Output; actually WXO/HF) output
of the previous FIFO in the cascade. RXI/REN2 is likewise
connected to the RXO (Read Expansion Output; actually
RXO/EF2) output of that previous FIFO. A reset operation
forces WXO/HF and RXO/EF2 HIGH for each FIFO;
consequently, all FIFOs with their WXI/WEN2 and
RXI/REN2 inputs thus connected come up in one of the
two cascaded grouping modes, according to whether
their FL/RT inputs are grounded or tied HIGH (see Tables
1 and 2).
READ EXPANSION INPUT/READ ENABLE 2
(RXI/REN2)
RXI/REN2 is a dual-purpose signal. It is one of four
input signals which select the grouping mode in which the
FIFO operates after being reset; the other three of these
input signals are FL/RT, WXI/WEN2, and EMODE. There
are four possible grouping modes: standalone, interlocked-paralleled, cascaded ‘master’ or ‘first-load,’ and
cascaded ‘slave.’ The designations ‘master’ and ‘slave’
pertain to IDT-compatible depth cascading. Tables 1 and
2 show the signal encodings which select each grouping
mode.
In standalone operation, WXI/WEN2 and RXI/REN2
both must be grounded, so that the FIFO comes up in the
standalone grouping mode after a reset operation. In
interlocked-paralleled operation, WXI/WEN2 is tied to
FF of the other paralleled FIFO, and RXI/REN2 is tied
to EF of that same other FIFO. This interconnection
scheme ensures that both FIFOs will operate together, and remain coordinated, regardless of timing
skews.
BOLD ITALIC = Enhanced Operating Mode
18
2048 x 18/4096 x 18 Synchronous FIFOs
In cascaded operation, RXI/REN2 is connected to
RXO (Read Expansion Output; actually RXO/EF2)) of the
previous FIFO in the cascade. WXI/WEN2 is likewise
connected to WXO (Write Expansion Output; actually
WXO/HF) output of that previous FIFO. A reset operation
forces RXO/EF2 and WXO/HF HIGH for each FIFO;
consequently, all FIFOs with their RXI/REN2 and
WXI/WEN2 inputs thus connected come up in one of the
two IDT-compatible cascaded grouping modes, according to whether their FL/RT inputs are grounded or tied
HIGH (see again Tables 1 and 2).
Data Outputs
DATA OUT (Q0 – Q17)
Data, programmable-flag-offset values, and ControlRegister codes are output from the FIFO as 18-bit words
on Q0 – Q17. Unused bit positions in offset-value words
and Control-Register words are zero-filled.
Control/Status Outputs
FULL FLAG (FF)
FF goes LOW whenever the FIFO is completely full.
That is, whenever the FIFO’s internal write pointer has
completely caught up with its internal read pointer; so that,
if another word were to be written, it would have to
overwrite the unread word which is now in position for
reading out by the next requested read operation. Under
these conditions, the FIFO is filled to its nominal capacity,
which is 2048 18-bit words for the LH540235 or 4096
18-bit words for the LH540245 respectively. Write operations are inhibited whenever FF is LOW, regardless of the
assertion or deassertion of Write Enable (WEN).
If the FIFO has been reset by asserting RS (LOW), FF
initially is HIGH. But, whenever no read operations have
been performed since the completion of the reset operation, FF goes LOW after 2048 write operations for the
LH540235, or after 4096 write operations for the
LH540245 (see Table 4).
FF gets updated after a LOW-to-HIGH transition of the
Write Clock (WCLK).
PROGRAMMABLE ALMOST-FULL FLAG (PAF)
PAF goes LOW whenever the FIFO is ‘almost’ full; that
is, whenever subtracting the value of the FIFO’s internal
read pointer from the value of its internal write pointer
yields a difference which is less than the value of the
Programmable-Almost-Full-Flag Offset ‘p.’ The subtraction is performed using modular arithmetic, modulo the
total nominal number of 18-bit words in the FIFO’s physical memory, which is 2048 for the LH540235 or 4096 for
the LH540245 respectively.
2048 x 18/4096 x 18 Synchronous FIFOs
DESCRIPTION OF SIGNALS AND
OPERATING SEQUENCES (cont’d)
The default value of ‘p’ after the completion of a reset
operation is 12710. However, ‘p’ may be set to any value
which does not exceed this total nominal number of words
for the device, as explained in the description of Load
(LD).
If the FIFO has been reset by asserting RS (LOW), and
no read operations have been performed since the
completion of the reset operation, PAF goes LOW after
(2048-p) write operations for the LH540235, or after
(4096-p) write operations for the LH540245 (see Table 4).
If p is still at its default value, PAF is LOW whenever
the FIFO is from seven-eighths full to completely full.
In the IDT-Compatible Operating Mode, PAF changes
from HIGH to LOW only after a LOW-to-HIGH transition
of the Write Clock WCLK, and from LOW to HIGH only
after a LOW-to-HIGH transition of the Read Clock RCLK.
Thus, in this operating mode, PAF behaves as an ‘asynchronous flag.’
In the Enhanced Operating Mode, on the other
hand, PAF gets updated only after a LOW-to-HIGH
transition of the Write Clock WCLK, and thus behaves
as a ‘synchronous flag,’ whenever Control Register
bit 04 is HIGH (see Table 5).
WRITE EXPANSION OUT/HALF-FULL FLAG
(WXO/HF)
WXO/HF is a dual-purpose signal. In ‘standalone’
operation, it behaves as a Half-Full Flag (HF), in accordance with Table 4. In IDT-compatible ‘cascaded’ operation, it behaves as a Write Expansion Output (WXO)
signal to coordinate writing operations with the next FIFO
in the cascade. Under these same conditions, also, the
dual-purpose WXI/WEN2 and RXI/REN2 inputs behave
as Write Expansion Input (WXI) and Read Expansion
Input (RXI) signals respectively.
When two or more LH540235 or LH540245 FIFOs are
‘cascaded’ to operate as a deeper ‘effective FIFO,’ in an
IDT-style ‘daisy-chain’ ring configuration, the Write Expansion Input (WXI) of each FIFO is connected to WXO
of the previous FIFO in the ring, with WXI of the ‘first-load’
or ‘master’ FIFO being connected to WXO of the last FIFO
so as to complete the ring. Similar connections are made
for each FIFO in the ring, parallel to these WXO-to-WXI
connections, for Read Expansion Input (RXI) and Read
Expansion Output (RXO/EF2, when it is behaving as
RXO).
When the last physical location has been written in a
FIFO operating in cascaded mode, a LOW-going pulse is
emitted by that FIFO on its WXO output, and the FIFO is
deactivated for writing at the next valid WCLK; and the
next FIFO in the ring is simultaneously activated for
LH540235/45
writing. Otherwise, WXO remains constantly HIGH whenever the FIFO is operating in cascaded mode. This LOWgoing WXO pulse serves as a ‘write token’ in the
‘token-passing’ FIFO-cascading scheme; it is passed on
to the next FIFO in the ring via its WXI input. When this
next FIFO receives the write token, it is activated for
writing at the next valid WCLK.
The foregoing description applies both to the ‘first-load’
or ‘master’ FIFO in the ring, and to any and all ‘slave’
FIFOs in the ring. However, WXO has no necessary
function for FIFOs operating in the ‘standalone’ mode.
Consequently, in that mode, the same output pin is used
for HF; it follows that HF is not available as an output from
any FIFO which is operating in the IDT-compatible cascaded mode. A FIFO is initialized into ‘cascaded master’
mode, into ‘cascaded slave’ mode, into interlocked-paralleled mode, or into standalone mode according to the
state of its WXI/WEN2, RXI/REN2, and FL/RT control
inputs during a reset operation, and of EMODE (see
Table 1, Table 2, and Table 5).
In standalone or interlocked-paralleled operation,
HF goes LOW whenever the FIFO is more than half full;
that is, whenever subtracting the value of the FIFO’s
internal read pointer from the value of its internal write
pointer yields a difference which is less than half of the
total nominal number of 18-bit words in the FIFO’s physical memory, which is 1024 for the LH540235 or 2048 for
the LH540245 respectively (see Table 4). The subtraction
is performed using modular arithmetic, modulo this total
nominal number of words, which is 2048 for the
LH540235 or 4096 for the LH540245 respectively.
If the FIFO has been reset by asserting RS (LOW), and
it is operating in standalone mode or in interlocked-paralleled mode, and no read operations have been performed since the completion of the reset operation, HF
goes LOW after 1025 write operations for the LH540235,
or after 2049 write operations for the LH540245 (see
again Table 4).
In the IDT-Compatible Operating Mode, HF changes
from HIGH to LOW only after a LOW-to-HIGH transition
of the Write Clock WCLK, and from LOW to HIGH only
after a LOW-to-HIGH transition of the Read Clock RCLK.
Thus, in this operating mode, HF behaves as an ‘asynchronous flag.’
In the Enhanced Operating Mode, on the other
hand, HF gets updated only after a LOW-to-HIGH
transition of the Read Clock RCLK, or else after a
LOW-to-HIGH transition of the Write Clock WCLK,
according to the setting of bits 03 and 02 of the
Control Register (see Table 5). Thus, in this mode HF
behaves as a ‘synchronous flag,’ and may be synchronized either to the input side of the FIFO (i.e., to
WCLK), or to the output side of the FIFO (i.e., to
RCLK).
BOLD ITALIC = Enhanced Operating Mode
19
LH540235/45
PROGRAMMABLE ALMOST-EMPTY FLAG (PAE)
PAE goes LOW whenever the FIFO is ‘almost empty’;
that is, whenever subtracting the value of the FIFO’s
internal write pointer from the value of its internal read
pointer yields a difference which is less than q + 1, where
‘q’ is the value of the Programmable-Almost-Empty-Flag
Offset. The subtraction is performed using modular arithmetic, modulo the total nominal number of 18-bit words
in the FIFO’s physical memory, which is 2048 for the
LH540235 or 4096 for the LH540245 respectively.
The default value of q after the completion of a reset
operation is 12710. However, q may be set to any value
which does not exceed this total nominal number of words
for the device, as explained in the description of Load
(LD).
If the FIFO has been reset by asserting RS (LOW), and
no write operations have been performed since the completion of the reset operation, then PAE is LOW (see Table
4).
If q is still at its default value, PAE is LOW whenever
the FIFO is from one-eighth full to completely empty.
In the IDT-Compatible Operating Mode, PAE changes
from HIGH to LOW only after a LOW-to-HIGH transition
of the Read Clock RCLK, and from LOW to HIGH only
after a LOW-to-HIGH transition of the Write Clock WCLK.
Thus, in this operating mode, PAE behaves as an ‘asynchronous flag.’
In the Enhanced Operating Mode, on the other
hand, PAE gets updated only after a LOW-to-HIGH
transition of the Read Clock RCLK, and thus behaves
as a ‘synchronous flag,’ whenever Control Register
bit 01 is HIGH (see Table 5).
EMPTY FLAG (EF)
EF goes LOW whenever the FIFO is completely empty.
That is, whenever the FIFO’s internal read pointer has
completely caught up with its internal write pointer; so
that, if another word were to be read out, it would have to
come from the physical memory location which is now in
position to be written into by the next requested write
operation. Read operations are inhibited whenever EF is
LOW, regardless of the assertion or deassertion of Read
Enable (REN).
If the FIFO has been reset by asserting RS (LOW), and
no write operations have been performed since the
completion of the reset operation, then EF is LOW. (See
Table 4.)
EF gets updated after a LOW-to-HIGH transition of the
Read Clock RCLK.
READ EXPANSION OUT/EMPTY FLAG 2 (RXO/EF2)
RXO/EF2 is a dual-purpose signal. In ‘standalone’
operation, it has no function. In IDT-compatible ‘cascaded’ operation, it behaves as a Read Expansion Output
BOLD ITALIC = Enhanced Operating Mode
20
2048 x 18/4096 x 18 Synchronous FIFOs
(RXO) signal to coordinate writing operations with the
next FIFO in the cascade. Under these same conditions,
also, the dual purpose RXI/REN2 and WXI/WEN2 inputs
behave as Read Expansion Input (RXI) and Write Expansion Input (WXI) signals respectively.
When two or more LH540235 or LH540245 FIFOs are
operating in IDT-compatible ‘cascaded’ mode as a deeper
‘effective FIFO,’ the dual-purpose RXI/REN2 and
WXI/WEN2 inputs behave as Read Expansion Input (RXI)
and Write Expansion Input (WXI) signals respectively. An
IDT-style cascade of these FIFO devices has a ‘daisychain’ ring configuration; the Read Expansion Input (RXI)
of each FIFO is connected to RXO (RXO/EF2, behaving
as RXO) of the previous FIFO in the ring, with RXI of the
‘first-load’ or ‘master’ FIFO being connected to RXO of
the last FIFO so as to complete the ring. Similar connections are made for each FIFO in the ring, parallel to these
RXO-to-RXI connections, for Write Expansion Input
(WXI) and Write Expansion Output (WXO).
When the last physical location has been read in a
FIFO operating in IDT-style cascaded mode, a LOW-going pulse is emitted by that FIFO on its RXO output;
otherwise, RXO remains constantly HIGH. This LOW-going RXO pulse serves as a ‘read token’ in the token-passing FIFO-cascading scheme; it is passed on to the next
FIFO in the ring via its RXI input. When this next FIFO
receives the read token, it is activated for reading at the
next valid RCLK.
After a FIFO emits an RXO pulse, the FIFO is deactivated for reading at the next valid RCLK. Also, its data
outputs go into high-Z state, regardless of the assertion
or deassertion of its Output Enable (OE) control input,
until it again receives the token. Simultaneously, the next
FIFO in the ring is activated for reading.
The foregoing description applies both to the ‘first-load’
or ‘master’ FIFO in the ring, and to any and all ‘slave’
FIFOs in the ring. However, RXO has no necessary
function for a FIFO which is operating in ‘standalone’
mode. Consequently, in that mode, RXO is never asserted, and remains constantly HIGH. A FIFO is initialized
into ‘standalone’ mode, into ‘cascaded master’ mode, or
into ‘cascaded slave’ mode according to the state of its
WXI/WEN2, RXI/REN2, and FL/RT control inputs during
a reset operation. It also may be forced into interlocked-paralleled mode by EMODE (see Table 1, Table 2, and Table 5).
In the Enhanced Operating Mode, RXO/EF2 behaves as a second Empty Flag EF2. EF2 is an exact
duplicate of the main Empty Flag EF, except that it is
delayed with respect to EF By one full cycle of the
Read Clock RCLK.
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS
tRS
RS
tRSS
tRSR
REN, WEN, LD
tRSF
EF, PAE
tRSF
FF, PAF, HF
tRSF
OE = HIGH1
Q0 - Q17
OE = LOW
NOTES:
1. After reset, the outputs will be LOW if OE = LOW, and in a high-impedance state if OE = HIGH.
2. The clocks (RCLK, WCLK) may be free-running during a reset operation.
540235-5
Figure 6. Reset Timing
tCLK
tCLKH
tCLKL
WCLK
tDS
tDH
VALID
DATA IN
D0 - D17
tENS
tENH
NO OPERATION
WEN
tWFF
tWFF
FF
tSKEW1(1)
RCLK
REN
NOTE:
1. tSKEW1 is the minimum time between a rising RCLK edge and a
rising WCLK edge for FF to change predictably during the current
clock cycle. If the time between the rising edge of RCLK and the
rising edge of WCLK is less than tSKEW1, then it is not guaranteed
that FF will change state until the next following WCLK edge.
540235-6
Figure 7. Synchronous Write Operation
21
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
tCLK
tCLKH
tCLKL
RCLK
tENS
tENH
NO OPERATION
REN
tREF
tREF
EF
tA
VALID DATA OUT
Q0 - Q17
tOLZ
tOE
tOHZ
OE
tSKEW2 (1)
WCLK
WEN
NOTE:
1. tSKEW2 is the minimum time between a rising WCLK edge and a
rising RCLK edge for EF to change predictably during the current
clock cycle. If the time between the rising edge of WCLK and the
rising edge of RCLK is less than tSKEW2, then it is not guaranteed
that EF will change state until the next following RCLK edge.
Figure 8. Synchronous Read Operation
22
540235-7
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
WCLK
tDS
D0 (FIRST
VALID WRTE)
D0 - D17
D1
D2
D3
tA (3)
tA
D4
tENS
WEN
tFRL (2)
RCLK
tSKEW2 (1)
tREF
EF
REN
D0
Q0 - Q17
D1
tOLZ
tOE
OE
NOTES:
1. tSKEW2 is the minimum time between a rising RCLK edge and a rising
WCLK edge for FF to change predictably during the current clock cycle.
If the time between the rising edge of RCLK and the rising edge of
WCLK is less than tSKEW2, then it is not guaranteed that FF will change
state until the next following WCLK edge.
2. tFRL (First-Read Latency) is the minimum time between a rising WCLK
edge and a rising RCLK edge to assure a correct readout of the first data
word D0 in response to the next RCLK edge. Thus, tFRL = tCLK + tSKEW2.
If tFRL is not met, D0 may be available either at tCLK + tSKEW2, or after
one more clock cycle delay at 2 tCLK + tSKEW2. The First-Read Latency
timing restrictions apply only when the FIFO has been empty (EF = LOW).
3. EF may be used to determine when the first data word D0 may be read.
D0 always is available on the next cycle after EF has gone HIGH.
540235-8
Figure 9. Latency for the First Data Word After a
Reset Operation, With Simultaneous Read and Write
23
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
NO WRITE
NO WRITE
WCLK
tSKEW11
tSKEW11
tDS
tDS
DATA WRITE
D0 - D17
DATA WRITE
tWFF
tWFF
tWFF
FF
WEN
RCLK
tENS
tENS
tENH
tENH
REN
OE
LOW
tA
Q0 - Q17
DATA IN
OUTPUT REGISTER
tA
DATA READ
NOTE:
1. tSKEW1 is the minimum time between a rising RCLK edge and a
rising WCLK edge for FF to change predictably during the current
clock cycle. If the time between the rising edge of RCLK and the
rising edge of WCLK is less than tSKEW1, then it is not guaranteed
that FF will change state until the next following WCLK edge.
Figure 10. Full-Flag Timing
24
NEXT
DATA READ
540235-9
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
WCLK
tDS
D0 - D17
tDS
DATA WRITE 1
DATA WRITE 2
tENS
tENH
tENH
tENS
WEN
tFRL(2)
tFRL(2)
tSKEW2(1)
tSKEW2(1)
RCLK
tREF
tREF
tREF
tREF
tREF
EF
EF2
REN
OE
LOW
tA
Q0 - Q17
DATA IN OUTPUT REGISTER
DATA READ
NOTES:
1. tSKEW2 is the minimum time between a rising WCLK edge and a
rising RCLK edge for EF to change predictably during the current
clock cycle. If the time between the rising edge of WCLK and the
rising edge of RCLK is less than tSKEW2, then it is not guaranteed
that EF will change state until the next following RCLK edge.
2. tFRL (First-Read Latency) is the minimum time between a rising WCLK
edge and a rising RCLK edge to assure a correct readout of the first data
word D0 in response to the next RCLK edge. Thus, tFRL = tCLK + tSKEW2.
If tFRL is not met, D0 may be available either at tCLK + tSKEW2, or after
one more clock cycle delay at 2 tCLK + tSKEW2. The First-Read Latency
timing restrictions apply only when the FIFO has been empty (EF = LOW).
3. EF may be used to determine when the first data word D0 may be read.
D0 always is available on the next cycle after EF has gone HIGH.
BOLD ITALIC = Enhanced Operating Mode.
540235-10
Figure 11. Empty-Flag Timing
25
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
t CLK
tCLKH
tCLKL
WCLK
tENS
tENH
LD
tENS
WEN
tDS
tDH
CONTROL REGISTER
D0 - D15
PAE OFFSET
PAF OFFSET
540235-11
Figure 12. Programmable-Register Write Operation
t CLK
tCLKH
tCLKL
RCLK
tENS
tENH
LD
tENS
REN
tA
CONTROL REGISTER
Q0 - Q15
UNKNOWN
PAE OFFSET
PAF OFFSET
540235-12
Figure 13. Programmable-Register Read Operation
26
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
tCLKH
tCLKL
WCLK
tENS
tENH
WEN
tPAE
q + 1 words
in FIFO
tPAE
PAE
q words in FIFO
RCLK
tENS
REN
NOTE:
1. PAE offset = q. Also, number of data words written into FIFO already = q.
540235-13
Figure 14. Programmable-Almost-Empty Flag Timing,
IDT-Compatible Operating Mode
27
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
Enhanced Operating Mode Timing Diagram
A
C
WCLK
tDS
D0 - D17
tDS
DATA WRITE 1
DATA WRITE 2
tENH
tENS
tENH
tENS
WEN
tSKEW2(1)
tSKEW2(1)
B
RCLK
tPAES
tPAES
tPAES
PAE
REN
OE
LOW
tA
Q0 - Q17
DATA IN OUTPUT REGISTER
DATA READ
NOTES:
1. tSKEW2 is the minimum time between a rising WCLK edge and a
rising RCLK edge for PAE to change predictably during the current
clock cycle. If the time between the rising edge of WCLK and the
rising edge of RCLK is less than tSKEW2, then it is not guaranteed
that PAE will change state until the next following RCLK edge.
2. PAE offset = q. Also, number of data words written into FIFO already = q.
3. The internal state of the FIFO:
At A , q+1 words.
At B , q words.
At C , q+1 words again.
540235-23
Figure 15. Programmable-Almost-Empty Flag Timing,
When Synchronous (Enhanced Operating Mode)
28
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
tCLKH
tCLKL
WCLK
tENS (1)
tENH
WEN
tPAF
PAF
2048 - p words
in FIFO (2)
2047 - p words
in FIFO (3)
tPAF
RCLK
tENS
REN
NOTES:
1. PAF offset = p. Number of data words written into FIFO already = 2047 - p for the LH540235 and 4095 - p for the LH540245.
2. 2048 - p words in FIFO for LH540235. 4096 - p words in FIFO for LH540245.
3. 2047 - p words in FIFO for LH540235. 4095 - p words in FIFO for LH540245.
540235-14
Figure 16. Programmable Almost-Full-Flag Timing,
IDT-Compatible Operating Mode
29
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
Enhanced Operating Mode Timing Diagram
NO WRITE
NO WRITE
B
WCLK
tSKEW1(1)
tSKEW1(1)
tDS
tDS
DATA WRITE
D0 - D17
DATA WRITE
tPAFS
tPAFS
tPAFS
PAF
WEN
A
C
tENS
tENS
RCLK
tENH
tENH
REN
OE
LOW
tA
Q0 - Q17
DATA IN
OUTPUT REGISTER
tA
DATA READ
NEXT
DATA READ
NOTES:
1. tSKEW1 is the minimum time between a rising RCLK edge and a
rising WCLK edge for PAF to change predictably during the current
clock cycle. If the time between the rising edge of RCLK and the
rising edge of WCLK is less than tSKEW1, then it is not guaranteed
that PAF will change state until the next following WCLK edge.
2. PAF offset = p. Number of data words written into FIFO already = 2047 - p
for the LH540235 and 4095 - p for the LH540245.
3. The internal state of the FIFO:
At A , 2047 - p words in FIFO for LH540235 and 4095 - p words in FIFO for LH540245.
At B , 2048 - p words in FIFO for LH540235 and 4096 - p words in FIFO for LH540245.
At C , again 2047 - p words in FIFO for LH540235 and 4095 - p words in FIFO for LH540245.
540235-24
Figure 17. Programmable-Almost-Full-Flag Timing,
When Synchronous (Enhanced Operating Mode)
30
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
tCLKH
tCLKL
WCLK
tENS
tENH
WEN
tHF
HF
HALF FULL OR LESS
HALF FULL +1
OR MORE
HALF FULL OR LESS
tHF
RCLK
tENS
REN
540235-15
Figure 18. Half-Full-Flag Timing,
IDT-Compatible Operating Mode
31
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
Enhanced Operating Mode Timing Diagram
NO WRITE
NO WRITE
B
WCLK
tSKEW11
tSKEW11
tDS
tDS
DATA WRITE
D0 - D17
DATA WRITE
tHFS
tHFS
tHFS
HF
WEN
A
C
tENS
tENS
RCLK
tENH
tENH
REN
OE
LOW
tA
Q0 - Q17
DATA IN
OUTPUT REGISTER
tA
DATA READ
NEXT
DATA READ
NOTES:
1. tSKEW1 is the minimum time between a rising RCLK edge and a
rising WCLK edge for HF to change predictably during the current
clock cycle. If the time between the rising edge of RCLK and the
rising edge of WCLK is less than tSKEW1, then it is not guaranteed
that HF will change state until the next following WCLK edge.
2. The internal state of the FIFO:
At A , exactly half full.
At
B , half+1 words.
At C , exactly half full again.
Figure 19. Half-Full-Flag Timing, When Synchronized
to Input Port (Enhanced Operating Mode)
32
540235-25
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
Enhanced Operating Mode Timing Diagram
A
C
tDS
tDS
WCLK
D0 - D17
DATA WRITE 1
DATA WRITE 2
tENH
tENS
tENH
tENS
WEN
tSKEW2(1)
tSKEW2(1)
B
RCLK
tHFS
tHFS
tHFS
HF
tENS tENH
REN
OE
LOW
tA
Q0 - Q17
DATA IN OUTPUT REGISTER
DATA READ
NOTE:
1. tSKEW2 is the minimum time between a rising WCLK edge and a
rising RCLK edge for HF to change predictably during the current
clock cycle. If the time between the rising edge of WCLK and the
rising edge of RCLK is less than tSKEW2, then it is not guaranteed
that HF will change state until the next following RCLK edge.
2. The internal state of the FIFO:
At A , half+1 words.
At B , exactly half full.
At C , half+1 words again.
540235-26
Figure 20. Half-Full-Flag Timing, When Synchronized
to Output Port (Enhanced Operating Mode)
33
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
Q [17:0]
DR1
DRT12
DR2
tA
tA
tA
RCLK
tA
A
R1
R2
RT1
RT2
DRT2
B
RT3
RT4
REN1
FL/RT
tENH
tENS
tENS
tRSF
tWFF
PREVIOUS VALID FF
NEW VALID FF
FF
tPAF
PREVIOUS VALID PAF
UNKNOWN
NEW VALID PAF
PAF
tHF
PREVIOUS VALID HF
UNKNOWN
NEW VALID HF
PREVIOUS VALID PAE
UNKNOWN
NEW VALID PAE
HF
PAE
tPAE
PREVIOUS VALID EF
NEW VALID EF
EF
tREF
NOTES:
1. It is not necessary for REN to be LOW for the device to recognize a retransmit request.
2. In order to actually read data words from the memory arrary, in IDT-Compatible
Operating Mode, REN = LOW; in Enhanced Operating Mode, also REN2 = HIGH
(and OE = LOW, if Control Register bit 05 = HIGH). In any case, LD = HIGH.
3. DRT1 is the data item in physical location zero of the FIFO memory array.
4. The asynchronous intermediate flags (corresponding to LOW Control-Register bits) will
show correct status three RCLK cycles after a retransmit operation, as is shown above.
(RT3, in the above RCLK waveform.)
5. The intermediate flags which have been synchronized to RCLK, by setting the appropriate
Control-Register bits to HIGH will show correct status after B , four RCLK cycles after a
retransmit operation. (RT4, in the above RCLK waveform.)
6. The intermediate flags which have been synchronized to WCLK, by setting the appropriate
Control-Register bits HIGH, will show correct status on the second WCLK rising edge after A ,
assuming that tSKEW1 was satisfied at A ; otherwise the flags will become valid on the third
WCLK rising edge after A .
7. Immediately after a reset operation, before any write operations have taken place, a retransmit
operation is a 'no-op', and does not change the state of any FIFO registers or flags.
8. In the special case that the FIFO memory array contains only one valid data item, the status
of HF and PAF should be ignored on a retransmit.
Figure 21. Retransmit Timing,
IDT-Compatible Operating Mode
34
540235-28
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
TIMING DIAGRAMS (cont’d)
tCLKH
WCLK
(NOTE)
tXO
tXO
WXO
tENS
WEN
NOTE: Write to last physical location.
540235-16
Figure 22. Write-Expansion-Out Timing,
IDT-Compatible Operating Mode
tCLKH
RCLK
(NOTE)
tXO
tXO
RXO
tENS
REN
NOTE: Read from last physical location.
540235-17
Figure 23. Read-Expansion-Out Timing,
IDT-Compatible Operating Mode
tXI
WXI
tXIS
WCLK
540235-18
Figure 24. Write-Expansion-In Timing,
35
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
TIMING DIAGRAMS (cont’d)
tXI
RXI
tXIS
RCLK
540235-19
Figure 25. Read-Expansion-In Timing,
IDT-Compatible Operating Mode
APPLICATIONS INFORMATION
Width Expansion
Standalone Configuration
Word-width expansion is implemented by placing multiple LH540235/45 devices in parallel. Each device should
be configured for standalone mode, unless the depth of
one single FIFO is not adequate for the application. In this
event, word-width expansion may in principle be used
with either of the two depth-cascading schemes supported by the LH540235/45 architecture. In practice, the
reliability benefits of interlocked-paralleled operation are
available only with the pipelining scheme, making it the
preferred alternative. (Refer to discussion in a later section.)
When depth cascading is not required for a given
application, the LH540235/45 is placed in standalone
mode by tying the two Expansion In pins WXI/WEN2 and
RXI/REN2 to ground, while also holding the First
Load/Retransmit pin FL/RT LOW for the duration of any
reset operation. (See Table 1.) Subsequently, FL/RT may
be taken HIGH at will, whenever a retransmit operation is
desired. If not being used, FL/RT also may be tied to
ground, as shown in Figure 27.
RESET (RS)
ENHANCED
MODE (EMODE)
WRITE CLOCK (WCLK)
READ CLOCK (RCLK)
WRITE ENABLE (WEN)
READ ENABLE (REN)
LOAD (LD)
DATA IN
OUTPUT ENABLE (OE)
LH540235/45
18
D[17:0]
Q[17:0]
18
FULL FLAG (FF)
DATA OUT
EMPTY FLAG (EF)
PROGRAMMABLE
ALMOST-EMPTY FLAG (PAE)
PROGRAMMABLE
ALMOST-FULL FLAG (PAF)
HALF-FULL FLAG (WXO/HF)
FIRST LOAD (FL/RT)
(MUST BE LOW
DURING A RESET
OPERATION)
WRITE EXPANSION IN (WXI/WEN2)
READ EXPANSION IN (RXI/REN2)
BOLD ITALIC = Enhanced Operating Mode.
540235-21
Figure 26. Standalone FIFO
(2048 × 18 / 4096 × 18)
BOLD ITALIC = Enhanced Operating Mode
36
2048 x 18/4096 x 18 Synchronous FIFOs
When standalone-mode LH540235/45 devices are
paralleled, the behavior of the status flags is identical for
all devices; so, in principle, a representative value for
each of these flags could be derived from any one device.
In practice, it is better to derive ‘composite’ flag values
using external logic, since there may be minor speed
variations between different actual devices. After writing
or reading have been in a disabled state, the process of
re-enabling should be gated by the slowest FIFO.
For m paralleled FIFOs, the form of this external
composite-flag logic may be an OR gate with m assertive-LOW inputs and an assertive-LOW output. In keeping with deMorgan’s Theorem, such a gate may be
implemented as an AND gate with m assertive-HIGH
inputs and an assertive-HIGH output. Figure 28 illustrates
the case m = 2.
The LH540235/45 architecture supports two very different methods of depth cascading:
Token passing, which follows the scheme used in the
pin-compatible and functionally-compatible Integrated
Device Technology IDT72205B/15B/25B/35B/45B
FIFOs, which the LH540235/45 can directly replace.
Pipelining, which follows the scheme used in the Texas
Instruments SN74ACT7801/11/81/82/84 FIFOs, and also in
the Sharp LH543620 1024 × 36 FIFO. The
SN74ACT7801/11/81/82/84 pinout closely resembles the
LH540235/45 pinout, but is not identical.
Depth Cascading Using Token Passing
Using the token-passing approach, depth cascading
is implemented by configuring the required number of
LH540235/45s in a circular ‘ring’ fashion, with the Expansion Out outputs (WXO/HF and RXO/EF2) of each device
tied to the Expansion In inputs (WXI/WEN2 and
RXI/REN2) of the next device (see Figure 29). Because
a reset operation forces the WXO/HF and RXO/EF2
outputs HIGH for each device, the WXI/WEN2 and
RXI/REN2 inputs for the next device are HIGH during the
reset operation; thus, these two inputs are HIGH for all
devices in the ring. (See Tables 1 and 2, and also Figure
29.) All devices in the cascade must be in the IDT-Compatible Operating Mode; thus, their EMODE inputs must
be tied to Vcc.
LH540235/45
One FIFO in the cascade must be designated as the
‘first-load’ device, by tying its First Load input (FL/RT) to
ground. All other devices must have their FL/RT inputs
tied HIGH. Under these circumstances, the Retransmit
function is not available for use.
In this mode, the control inputs which govern writing
(WCLK and WEN) and the control inputs which govern
reading (RCLK and REN) are shared by all devices, while
logic within each LH540235/45 governs the steering of
data. The common Data Inputs of all devices are tied
together; but only one LH540235/45 is enabled during
any given write cycle. Likewise, the common three-state
Data Outputs of all devices are wire-ORed together; but
only one LH540235/45 is enabled, including its threestate outputs, during any given read cycle. A data word is
handled only by one device as it passes through the
cascade of FIFOs, regardless of how many FIFOs are
being cascaded together.
In the token-passing depth-cascaded mode, external
logic should be used to generate a composite Full Flag
and a composite Empty Flag, by ANDing the FF outputs
of all LH540235/45 devices together and by ANDing the
EF outputs of all devices together, using AND gates with
assertive-LOW inputs and an assertive-LOW output.
Here, the meaning of these composite flags is direct: the
cascade of FIFOs is full, if and only if all k FIFOs belonging
to the cascade are individually full; and similarly for empty.
In keeping with deMorgan’s Theorem, these k-input assertive-LOW AND gates are implemented physically as
k-input assertive-HIGH OR gates. Figure 29 illustrates the
case k = 3.
Similar external logic also may be used to generate a
composite Programmable Almost-Full Flag and a composite Programmable Almost-Empty Flag, by ANDing the
PAF outputs of all LH540235/45 devices together and by
ANDing the PAE outputs of all devices together. Here,
however, some careful analysis is required, to determine
exactly what the resulting composite flags mean. Their
significance may vary widely, depending on the number
of FIFOs in the cascade, and on the ‘offset’ values which
are present in the offset registers for these FIFOs. More
complex logical combinations of PAF outputs with FF
outputs, and of PAE outputs with EF outputs, may be
found useful in particular applications.
In any case, the Half-Full Flag and the Retransmit
function are not available for devices being used in tokenpassing depth-cascaded mode.
BOLD ITALIC = Enhanced Operating Mode
37
38
Figure 27. Interlocked-Paralleled Word-Width Expansion
36
NOTE: BOLD ITALIC = Enhanced Operating Mode.
RETRANSMIT (MUST BE LOW
DURING A RESET OPERATION
PAFC
RESET
DATA IN
FFC
LOAD
WRITE ENABLE
WRITE CLOCK
18
18
EF2
EF
FF
EF2
EF
FF
FL/RT WEN2 REN2
PAE
PAF
Q[17:0]
OE
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
HF
FL/RT WEN2 REN2
PAE
PAF
Q[17:0]
OE
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
HF
HFC
18
18
36
PAEC
DATA OUT
EFC
540235-32
OUTPUT ENABLE
READ ENABLE
READ CLOCK
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
WRITE-TOKEN PULSE
READ-TOKEN PULSE
WXO RXO
WCLK RCLK
REN
WEN
18
LD
EMODE
RS
OE
D[17:0]
VCC
18
Q[17:0]
PAF
PAE
FF
FL
EF
WXI RXI
VCC
WXO RXO
WCLK RCLK
REN
WEN
18
18
DATA IN
LD
EMODE
RS
OE
D[17:0]
Q[17:0]
PAF
PAE
FF
FL
EF
WXI RXI
VCC
DATA OUT
18
18
VCC
WXO RXO
WCLK RCLK
WRITE CLOCK
WRITE ENABLE
RESET
LOAD
18
WEN
LD
EMODE
RS
OE
D[17:0]
PAF
FF
REN
READ CLOCK
READ ENABLE
VCC
OUTPUT ENABLE
Q[17:0]
18
PAE
EF
FF
FL WXI RXI
(COMPOSITE
FLAGS)
EF
(COMPOSITE
FLAGS)
PAF
PAE
FIRST LOAD
NOTES:
Grounding FL designates the 'first-load' FIFO ('master' FIFO). The remaining FIFOs are 'slave' FIFOs.
BOLD ITALIC = Enhanced Operating Mode.
540235-27
Figure 28. Synchronous-FIFO Depth-Cascading Using
IDT-Compatible ‘Token-Passing’ Scheme
39
LH540235/45
Depth Cascading Using Pipelining
Using the pipelining approach, depth cascading is
implemented by connecting the required number of
LH540235/45s in series. Within the cascade, the Data
Outputs of each device are connected to the Data Inputs
of the next device. (See Figure 30.) All devices in the
cascade must be in the Enhanced Operating Mode;
thus, their EMODE inputs must be grounded.
Successive devices in the cascade are crosscoupled;
they control each other, using a ‘handclasp’ scheme for
crossconnecting their control inputs and their status outputs. (See again Figure 30.) The input side of the first
device, and the output side of the last device, are not
crosscoupled to other devices. Their control/status and
clock pins are connected to the external system.
For the FIFO devices within the cascade, transferring
data from each device to the next device is governed by
a clock. Preferably, the same clock should be used at
every FIFO-to-FIFO data-transfer interface boundary
within the cascade. This ‘Transfer Clock’ may be either
the external Write Clock, or the external Read Clock. If
both of these two clocks are periodic and free-running,
the faster of the two is the obvious choice for the ‘Transfer
Clock.’ Of course, in principle, the ‘Transfer Clock’ may
even be some other, totally-different clock.
The Empty Flag of each device is used to govern
writing into the next device, and the Full Flag of each
device is used to govern reading from the preceding
device. Since the standard Empty Flag EF occurs one
RCLK cycle too early to properly enable/disable the next
device, the duplicate Empty Flag EF2 is used instead;
EF2 is an exact copy of EF, except that it is delayed
by one full RCLK cycle with respect to EF.
Also, since the usual enable signals WEN and REN
have the wrong polarity to function properly in this ‘handclasp’ mode, they are grounded for all devices within the
cascade. The duplicate but inverted signals WEN2
and REN2 are used instead.
EF2, WEN2, and REN2 are available only in Enhanced Operating Mode. They share the same pins
which in IDT-Compatible Operating Mode are used
respectively for RXO, WXI, and RXI. Hence, for pipelined operation, all devices in the cascade must be in
the Enhanced Operating Mode; their EMODE control
inputs must be grounded.
BOLD ITALIC = Enhanced Operating Mode
40
2048 x 18/4096 x 18 Synchronous FIFOs
When all of the foregoing conditions have been met in
the interconnection of the pipelined array, then: At each
device-to-device interface boundary within the array, a
data word is transferred from the upstream device to the
downstream device after every transfer-clock rising edge,
as long as the upstream device is not empty and the
downstream device is not full.
Width Expansion Along With Depth Cascading
In principle, width expansion may be used with either
of the two possible depth-cascading schemes.
However, when using the token-passing depth-cascading scheme, width expansion reduces simply to placing two or more cascades in parallel. In this mode of
interconnection, no architectural support is available for
interlocked-paralleled operation. Composite-flag logic
may, of course, be designed to fit any complete array
configuration, to determine meaningful full and empty
indications for the entire array. This logic may, for instance, OR the FF and EF signals from the devices at the
same relative position in each of the paralleled cascades,
and then AND all of the rank-FF signals together; and
likewise for all of the rank-EF signals. Then, the entire
array is indicated to be full, if all ranks of devices
(across the paralleled cascades) are individually full;
and, similarly for empty.
When using the pipelined depth-cascading scheme,
on the other hand, the first rank of devices (the one which
receives input data words from the external system) and
the last rank of devices (the one which provides output
data words to the external system) may be operated in an
interlocked-paralleled manner. Figure 31 shows a suggested interconnection scheme for two paralleled cascades, each three devices deep. The entire array of
Figure 31 would comprise a 12288 × 36 ‘effective FIFO,’
if implemented with 4096 × 18 LH540245 devices. Whenever the number of paralleled cascades exceeds two, a
small amount of external logic is necessary to implement
the interlocking.
18
HF
EF2
EF
FF
VCC
FL WEN2 REN2
PAE
PAF
Q[17:0]
OE
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
BOLD ITALIC = Enhanced Operating Mode.
The transfer clock may be any free-running clock. However, it is
recommended that the faster of the Write Clock and the Read Clock
be used, if both of these are free-running clocks.
NOTES:
RESET
FULL
ALMOST FULL
DATA IN
LOAD
WRITE ENABLE
WRITE CLOCK
TRANSFER CLOCK
18
VCC
EF2
EF
FF
FL WEN2 REN2
PAE
PAF
Q[17:0]
OE
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
HF
18
VCC
HF
EF2
EF
PAE
Q[17:0]
OE
EMODE
REN
RCLK
VCC
FL WEN2 REN2
FF
PAF
D[17:0]
RS
LD
WEN
WCLK
18
EMPTY
540235-30
ALMOST EMPTY
DATA OUT
OUTPUT ENABLE
READ ENABLE
READ CLOCK
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
Figure 29. TI-Style Pipelined Depth-Cascading
41
42
Figure 30. Interlocked Paralleling Used Together
With Pipelined Depth-Cascading
RESET
36
18
18
HF
EF2
EF
FF
EF2
OE
EF
FF
FL WEN2 REN2
PAE
PAF
Q[17:0]
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
HF
FL WEN2 REN2
PAE
PAF
Q[17:0]
OE
D[17:0]
EMODE
RS
REN
RCLK
LD
WEN
WCLK
BOLD ITALIC = Enhanced Operating Mode.
The transfer clock may be any free-running clock. However, it is
recommended that the faster of the Write Clock and the Read Clock
be used, if both of these are free-running clocks.
NOTES:
DATA IN
FFC
LOAD
WRITE ENABLE
WRITE CLOCK
TRANSFER CLOCK
18
VCC
18
VCC
EF2
EF2
OE
EF
FF
FL WEN2 REN2
PAE
PAF
Q[17:0]
RS
D[17:0]
EMODE
REN
RCLK
LD
WEN
WCLK
HF
18
VCC
EF2
EF
PAE
Q[17:0]
OE
EMODE
REN
RCLK
EF2
EF
PAE
Q[17:0]
OE
EMODE
REN
RCLK
FL WEN2 REN2
FF
PAF
D[17:0]
RS
LD
WEN
WCLK
HF
FL WEN2 REN2
FF
EF
FF
FL WEN2 REN2
PAF
D[17:0]
RS
LD
WEN
PAE
18
VCC
HF
WCLK
PAF
Q[17:0]
OE
D[17:0]
EMODE
RS
REN
RCLK
LD
WEN
WCLK
HF
18
18
36
540235-33
DATA OUT
EFC
READ ENAB LE
READ CLOCK
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
PACKAGE DIAGRAMS
68PLCC (PLCC68-P-950)
24.23 [0.954]
24.13 [0.950]
25.27 [0.995]
25.02 [0.985]
23.62 [0.930]
22.61 [0.890]
24.23 [0.954]
24.13 [0.950]
25.27 [0.995]
25.02 [0.985]
3.91 [0.154]
3.71 [0.146]
4.57 [0.180]
4.19 [0.165]
0.10 [0.004]
1.27 [0.050]
BSC
0.53 [0.021]
0.33 [0.013]
DIMENSIONS IN MM [INCHES]
0.051 [0.020]
MIN
MAXIMUM LIMIT
MINIMUM LIMIT
68PLCC-1
68-Pin PLCC
43
LH540235/45
2048 x 18/4096 x 18 Synchronous FIFOs
64TQFP (TQFP-64-P-1414)
DETAIL
0.20 [0.008]
0.09 [0.004]
0.75 [0.030]
0.45 [0.018]
0.15 [0.006]
0.05 [0.002]
16.0 [0.630]
BASIC
14.0 [0.551]
BASIC
16.0 [0.630]
BASIC
14.0 [0.551]
BASIC
0.80 [0.031]
BASIC
1.60 [0.063]
MAX.
1.45 [0.057]
1.35 [0.53]
DIMENSIONS IN MM [INCHES]
0.45 [0.018]
0.30 [0.012]
MAXIMUM LIMIT
MINIMUM LIMIT
64TQFP
64-Pin TQFP
44
0.10 [0.004]
2048 x 18/4096 x 18 Synchronous FIFOs
LH540235/45
ORDERING INFORMATION
LH540235/45
Device Type
X
Package
- ##
Speed
20
25 Cycle Time (ns)
35
U 68-Pin Plastic Leaded Chip Carrier (PLCC68-P-S950)
M 64-Pin Thin Quad Flat Package
2048 x 18/4096 x 18 Synchronous FIFO
Example: LH540245U-20 (4096 x 18 Sychronous FIFO, 20 ns, 68-pin PLCC)
540235MD
45
LH540235/45
BOLD ITALIC = Enhanced Operating Mode
46
2048 x 18/4096 x 18 Synchronous FIFOs