GMT G569CS8U

Global Mixed-mode Technology Inc.
G569C
CD-RW Laser Diode Current Driver
Features
General Description
„
The G569C is a single chip solution for the various
functions relating to laser diode operation in a CD-RW
drive. The G569C integrates nine functional blocks in
one chip. It has five voltage-to-current converters, one
current-to-voltage converters which is called FSA, one
OP-AMP, one eight-channels D/A converter, and one
voltage subtracter with output clamping capability
called Dalpha.
„
„
„
„
„
„
„
„
„
„
Single +5V supply
Laser diode read current driver
Laser diode write current driver
Laser diode Erase current driver
Deltap circuit to control write current
FSA circuit to integrate photo diode current
Cagain circuit to convert Vcagain into current
Dalpha circuit to perform voltage subtraction
and limiting
3-wire interface to control internal DAC
A build-in OP-AMP
48-pin SSOP package
Three of the five V-to-I converters provide the laser
diode currents for Read, Write, and Erase operations,
respectively; another one of the V-I converters
provides the Cagain current; and the other one
provides Deltap current which can selectively shunt a
certain amount of laser diode current for write
operation. For the Write and Erase operations, the
voltage to current conversion ratio can be adjusted
using an external or internal DAC resistor array. The
FSA circuit performs integration on the output current
of an external photo diode, and sample-and-hold the
peak voltage. It is used to monitor the laser diode
power. The internal eight-channel D/A converter is
used to provide the input voltage for above functional
blocks. The G569C is available in a 48-pin SSOP
surface-mount package.
Applications
„
CD-RW Drive
Pin configuration
Ordering Information
G569C
IW_IN
1
48
WDB
LS_DELTA
TST1
2
47
3
46
LS_WRITE
PWRITE
LD
PWO
4
45
DALPHA
5
44
DI
PWO_I
6
43
CLK
PWB
7
42
VSS
PWMAX
PWMIN
8
9
41
40
VOUT
VI-
/RESET
10
11
39
38
VI+
VDD
12
13
37
36
FSOF
FSWS
FSCLR
VSS
EDB
LS_ERASE
PERASE
14
35
RECORD
15
34
FSW
CDR
16
33
IFSA
FSR
S2V9
17
32
CAGAIN2
18
31
FSRS
CAGS_I
19
30
VDD
DCAGAIN
20
29
CAGAIN
RCAGAIN1
21
28
SELN4_IN
PR_I
22
27
23
24
26
RCAGAIN2
PRFINE
25
ORDER ORDER NUMBER
NUMBER
(Pb free)
G569CS8U
G569CS8Uf
Note: S8: SSOP-48
U: Tape & Reel
TEMP.
RANGE
PACKAGE
0°C to 85°C
SSOP-48
LS_READ
IR
PRCOARSE
SSOP-48
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
1
G569C
Global Mixed-mode Technology Inc.
Absolute Maximum Ratings
derate .7mW/°C about 70°C)…………….……… 695mW
Operating Temperature Range…….…-10°C to +100°C
Junction Temperature……………………...…….+150°C
Storage temperature Range…….…….-65°C to +165°C
Reflow Temperature (soldering, 10sec)………..+260°C
VCC to GND…………………………….……..-0.3V to +6V
Dalpha to GND………………………………....-3V to +6V
All other pin to GND…………………………-0.3V to +6V
ESD protetion (human body model)………………2000V
Continuous power dissipation (TA=70°C),
Stresses beyond those listed under “Absolute Maximum Ratings” may cause permanent damage to the device. These are
stress ratings only, and functional operation of the device at these or any other conditions beyond those indicated in the
operational sections of the specifications is not implied. Exposure to absolute maximum rating conditions for extended periods
may affect device reliability.
Recommended Operating Conditions
PARAMETER
SYMBOL
MIN
TYP
MAX
UNITS
Supply voltage
High-level input voltage
VDD
VIH
4.75
2
5
5.5
V
V
Low-level input voltage
Operating free-air temperature
VIL
TA
0
0.8
70
V
°C
Electrical Characteristics (VCC = 5V, TA = 0°C to +70°C, unless otherwise noted)
MIN
TYP
MAX
UNITS
Supply voltage range
PWO output voltage
Dalpha input voltage
PARAMETER
CONDITIONS
4.75
0
-3.0
5.0
5.5
VS2V9
3.5
V
V
V
PWO_I input voltage
PWB output voltage
0
0
1.5
VS2V9
V
V
PWMAX output voltage
PWMIN output voltage
0
0
VS2V9
VS2V9
V
V
130
mA
IE output current
S2V9 input voltage
0
VS2V9
2.9
Cagain output current
0
V
1.2
mA
PRFine output voltage
0
VS2V9
V
PRCoarse output voltage
0
VS2V9
V
IR output current
0
160
mA
PR_I input voltage
0
2.16
V
FSR output voltage
0
3.0
V
FSW output voltage
0
3.0
V
VI- input voltage
0
3.5
V
VI+ input voltage
0
3.5
V
IW output current
0
160
mA
Operation current
41
mA
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
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Global Mixed-mode Technology Inc.
G569C
Pin Description
PIN NO. PIN NAME I/O
1
IW_IN
I
2
3
4
5
6
7
8
9
10
11,42
12
13
14
15
16
17
LS_DELTA
TST1
PWO
DALPHA
PWO_I
PWB
PWMAX
PWMIN
/RESET
VSS
EDB
LS_ERASE
PERASE
RECORD
CDR
S2V9
O
I
O
I
I
O
O
O
I
I
O
I
O
I
I
I
18
19
20
21
22
23
24
25
26
27
28
29
CAGAIN2
CAGS_I
DCAGAIN
CAGAIN
RCAGAIN1
RCAGAIN2
PRFINE
PRCOARSE
IR
LS_READ
PR_I
SELN4_IN
O
I
O
O
O
O
O
O
O
I
I
I
30,38
31
VDD
FSRS
I
I
32
33
FSR
IFSA
O
I
34
35
36
FSW
FSCLR
FSWS
O
O
I
37
FSOF
I
39
40
41
43
44
45
46
47
48
VI+
VIVOUT
CLK
DI
LD
PWRITE
LS_WRITE
WDB
I
I
O
I
I
I
O
I
O
PIN FUNCTION
A diode of type BAS216 should be connected between this pin and node IW. This pin provides
the path for sinking IW current.
Connect a 10Ω resistor from this pin to VSS
Test pin. Connect to ground for normal operation.
DAC output, connect to PWO_I through a resistor divider
Control voltage input
Control voltage input
Voltage output
Voltage output
Voltage output
Logic input. A Low on this pin reset all DAC latches to 0.
Ground pin
Connect to the base node of external PNP BJT (Type BC808).
Connect a 6.8Ω (1206 type) resistor from this pin to VDD
Connect a DAC resistor array from this pin to VSS
Logic input, a high indicates in recording mode.
Logic input, a high indicates in CD-R mode.
Voltage input. Contribute to current output on CAGAIN pin and provides internal DAC reference
voltage.
Tristate output. Connect 62KΩ to pin CAGAIN.
Logic input, 0~2V swing.
An optional resistor may be added to modify the output current on CAGAIN
Current output
A 16.2KΩ resistor should be connected from this pin to VSS
A 3.9KΩ resistor should be connected from this pin to VSS
DAC output, connect to PR_I through a resistor divider
DAC output, connect to PR_I through a resistor divider
Read current output for laser diode
Connect two 22Ω (1206 type) resistors from this pin to VDD
Voltage input which controls the current on IR pin
Logic input. This pin can be shorted to pin CDR or be connected to the voltage divider formed by
CDR and SELN4.
Supply voltage input. Each VDD pin should have a 0.1µF bypass capacitor to VSS.
Logic input, when FSRS=1, the voltage on pin FSCLR is sampled onto pin FSR, else FSR is in hold
mode.
Sampled voltage output, controlled by FSRS
If internal integration control circuitry is used, connect a photo diode from this pin to +30V. connect it
to VDD otherwise
Sampled voltage output, controlled by FSWS
Sampling capacitors and resistor are connected to this pin.
Logic input, when FSWS=1, the voltage on pin FSCLR is sampled onto pin FSW, else FSW is in
hold mode.
If internal integration control circuitry is used, connect the control signal to this pin. A logic low enable
the current charging on the capacitors on pin FSCLR with the current from IFSA. Connect this pin to
VDD if internal integration control circuitry is not used.
Non-inverting input of Op Amp
Inverting input of Op Amp
Op Amp output
Clock input of I2S bus
Data input of I2S bus
Latch data input of I2S bus
Connect a DAC resistor network from this pin to VSS
Connect a 6.8Ω (1206type) from this pin to VDD
Connect to the base node of external PNP BJT. (Type BC807-40)
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
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G569C
Global Mixed-mode Technology Inc.
Detail Description
The typical application circuit of G569C is shown in Fig.
1. The block diagram of G569C is shown in Fig. 2. It
contains nine circuit blocks. The operation of these
blocks is described below.
programming of the OTA's transconductance. An
internal DAC can be enabled through I2S bus to
replace the external DAC resistor array. The maximum
RPWRITE is 7.5KΩ. The maximum IW is 130 mA.
Since IW must flow through the external 6.8Ω resistors
connected between VDD and LS_WRITE pin, type
1206 SMD resistors must be used to handle the power
dissipation.
READ Block
This block is equivalent to an operational
transconductance amplifier (OTA). The voltage on
PR_I pin is the input voltage, VPR_I; the output current,
IR, is delivered on pin IR. The relationship between
VPR_I and IR is given by:
DELTAP Block
This block is a current sink used to selectively sink the
IW current. When DP4 is low, the current sink reduces
the output current on IW by the amount of the
magnitude of the current sink. The magnitude of the
current sink, Is, is given by:
IR = 820 x VPR_I /( R232 ∥R233)
where IR is in mA, VPR_I is in volt, and R is in Ω. The
recommended values for R232 and R233 are 22Ω, the
maximum VPR_I is 2.16 V, thus the maximum IR is
160mA. Since IR must flow through the two external
22Ω resistors connected between VDD and LS_READ
pin, type 1206 SMD resistors must be used to handle
the power dissipation.
Is =
DALPHA Block
The function of this block is a voltage subtracter. The
voltage on pin PWB, VPWB, is given by:
VPWB
1800
x VPWD / RPERASE,
R235
= 2 x VPWO_I - VDALPHA,
where VPWO_I and VDALPHA are the voltages on pins
PWO_I and DALPHA, respectively. In addition, the
magnitude of the output voltage VPWB is limited by
VPWMAX and VPWMIN, which are the voltages on pins
PWMAX and PWMIN.
where IE is in mA, VPWD is in volt, and RPERASE, in KΩ,
is the total resistance from pin PEARSE to ground.
Typically, a digital-to-analog converter (DAC) resistor
array is connected at PERASE pin to allow digital
programming of the OTA's transconductance. The
maximum RPERASE is 7.5KΩ. An internal DAC can
be enabled through I2S bus to replace the external
DAC resistor array. The maximum IE is 130 mA. Since
IE must flow through the external 6.8Ω resistors
connected between VDD and LS_ERASE pin, type
1206 SMD resistors must be used to handle the power
dissipation.
When 2xVPWO_I - VDALPHA < VPWMIN, then VPWB = VPWMIN.
When 2xVPWO_I - VDALPHA, > VPWMAX, then VPWB =
VPWMAX.
The input voltage ranges of VPWMAX and VPWMIN are 0 to
VS2V9 which is the voltage input at S2V9 pin, and the
condition VPWMAX > VPWMIN must hold. Note that the
input voltage range of VDALPHA is -3V to +3.5V.
CAGAIN Block
This block is also an operational transconductance
amplifier (OTA). The voltage on VCAGAIN pin is the
input voltage, VVCAGAIN; the output current, ICAGAIN, is
delivered on pin CAGAIN. Let the voltages on pins
CDR, CAGS, CAGAIN and S2V9 be denoted as VCDR,
VCAGS, VCAGAIN, VS2V9, respectively. The relationship
between VVCAGAIN and ICAGAIN is given by:
WRITE Block
This block is also an operational transconductance
amplifier (OTA). The voltage on PWD node is the input
voltage, VPWD; the output voltage, VWDB, can be used
to drive an external PNP BJT to provides desired IW
current. The relationship between VPWD and IW is
given by:
IW =
x VDELTAP / RLS_DELTA,
where Is is in mA; VDELTAP, in volt, is an internal DAC
output; and RLS_DELTA, in KΩ, is the resistance from pin
LS_DELTA to ground. Type 1206 SMD resistors must
be used for RLS_DELTA to handle the power dissipation.
When DP4 is high, the current output on IW current is
not affected.
ERASE Block
This block is also equivalent to an operational
transconductance amplifier (OTA). The voltage on
PWD node is the input voltage, VPWD; the output
voltage, VEDB, can be used to drive an external PNP
BJT to provides desired IE current. The relationship
between VPWD and IE is given by:
IE =
3
20
1800
x VPWD / RPWRITE,
R234
When VCDR = 5V, VCAGS = 5V
ICAGAIN = 1.2 x VCAGAIN / (R108 ∥ R109) + (VS2V9 VCAGAIN) / R195,
where IW is in mA, VPWD is in volt, and RPWRITE, in KΩ
is the total resistance from pin PWRITE to ground.
Typically, a digital-to-analog converter (DAC) resistor
array is connected at PWRITE pin to allow digital
When VCDR = 5V, VCAGS = 0V
ICAGAIN = (VS2V9 - VCAGAIN) / R195
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Ver: 1.0
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Global Mixed-mode Technology Inc.
G569C
When VFSOF = 0V, the FSCLR pin is charged by IFSA.
When VCDR = 0V, VCAGS = 5V, VRECORD = 0V
ICAGAIN = 1.2 x VCAGAIN / R108 + (VS2V9 - VCAGAIN) / R195,
When VFSOF = 5V, the FSCLR pin is not charged by IFSA.
When VCDR = 0V, VCAGS = 5V, VRECORD = 5V
ICAGAIN = 1.2 x VCAGAIN / R108
The FSCLR, RDGAIN1, RDGAIN2, and RDGAIN3
pins are driven by an open-drain buffer, i.e., the
voltages on these pins are either 0V or Hi-Z. The
capacitance values of the three capacitors connecting
to the FSCLR may need to be changed if loader other
than CDL4800 is used.
When VCDR = 0V, VCAGS = 0V, VRECORD = 0V
ICAGAIN = (VS2V9 - VCAGAIN) / R195,
When VCDR = 0V, VCAGS = 0V, VRECORD = 5V
ICAGAIN = 0 mA,
When VFSCLR = 0V, the charges on the capacitors are
discharged to 0V.
Where ICAGAIN is in mA; all voltages are in volt, and all
resistance are in KΩ.
When VFSCLR = Hi-Z, the charging of FSCLR node is
allowed.
FSA Block
The FSOF/FSON control the integration of the
photodiode current, IFSA, on the capacitors connected
on pin FSCLR to obtain a voltage. The voltage on
FSCLR pin is connected to two sample-and-hold
circuit. The voltages sampled by the control voltage on
FSWS and FSRS pins are output on FSW and FSR
pins, respectively. Namely,
When VRDGAIN1 = 0V, the VFSCLR is given by:
VFSCLR = IFSA x R187.
When VRDGAIN1 = Hi-Z, the charging of FSCLR node is
allowed.
When VRDGAIN2 = 0V, the capacitor C123 is in parallel
with C116.
When VFSWS = 5V, VFSW = VFSCLR,
When VRDGAIN2 = Hi-Z, the capacitor C123 has no effect.
When VFSWS = 0V, VFSW = the previously sampled
value;
When VRDGAIN3 = 0V, the capacitor C117 is in parallel
with C116.
When VFSRS = 5V, VFSR = VFSCLR,
When VRDGAIN3 = Hi-Z, the capacitor C117 has no effect.
When VFSRS = 0V, VFSR = the previously sampled
value.
The charging of FSCLR node is controlled by signals
VFSOF and VFSON.
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
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G569C
Global Mixed-mode Technology Inc.
5V
5V
IFSA
FSOF
30V
5V
CAGAIN
CAGAIN (pin 21)
R195
RCAGAIN2 (pin 23)
3.9K
CDR
820
R187
IFSA (pin 33)
22K
VRDGAIN1
FSCLR(pin 35)
FSCLR (pin 35)
C123
2.2nF
C116
560pF
SELN4_IN (pin 29)
10K
C117
1.5nF
VRDGAIN3
VRDGAIN2
R67
CAGS
FSON
CDR (pin 16)
100K
SELN4
BF824
820
0.1μF
RCAGAIN1 (pin 22)
16.2K
R109
R70
VDD (pin 30,38)
CAGAIN2 (pin 18)
62K
R108
R69
100
R68
R71
100
CAGS_I (pin 19)
330
12V
C113
330pF
R66
220
R234
(1206)
LS_WRITE (pin 47)
5V
R230
4.7K
R231
PRCOARSE (pin 25)
R210
WDB (pin 48)
PRFINE (pin 24)
150K
R302
2.2K
6.8
47
PR_I (pin 28)
IW_IN (pin 1)
R192
330
R124
270
5V
BC847B
R232
(1206)
22
22
R232
(1206)
DP4
PWRITE (pin 46)
C52
68pF
LS_READ (pin 27)
TST1 (pin 3)
IR
5V
R235
12V
6.8
(1206)
R226
1.5K
BC807_40
IW
BAS216
5V
R229
6.8K
C127
100nF
R191
220
R36
1M
IR (pin 26)
LS_DELTA (pin 2)
R236
10
(1206)
LS_ERASE (pin 13)
R236
R92
220
PWO (pin 4)
C135
100nF
150K
EDB (pin 12)
BC808
150K
PERASE (pin 14)
R127
R211
47
IE
PWO_I (pin 6)
5V
R96
1M
FSOF (pin 37)
C53
1nF
FSOF
VSS (pin 11,42)
Fig 1. Typical application circuit
Note: The circuits in the dotted-line are the suggested circuit when internal integration circuit is not used.
Please refer to pin description for details.
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
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Ver: 1.0
Oct 02, 2000
7
SELN4_IN
CAGAIN2
RCAGAIN2
RCAGAIN1
DCAGAIN
LS_DELTA
TST1
IW_IN
WDB
LS_WRITE
PWRITE
PERASE
LS_ERASE
EDB
LD
DI
CLK
/RESET
(pin 29)
(pin 18)
(pin 23)
(pin 22)
(pin 20)
(pin 2)
(pin 3)
(pin 1)
(pin 48)
(pin 47)
(pin 46)
(pin 14)
(pin 13)
(pin 12)
(pin 45)
(pin 44)
(pin 43)
(pin 10)
DELTAP
WRITE
Internal DAC Resistor
Array (CH9)
Internal DAC Resistor
Array (CH10)
ERASE
CDR
(pin 16)
VDELTAP
D/A
(pin 24)
(pin 25)
(pin 4)
RECORD
(pin 15)
CAGS_I
(pin 19)
CAGAIN
PWD
CAGAIN
(pin 21)
VCAGAIN
LS_READ
(pin 27)
VOUT
(pin 41)
(pin 40)
(pin 39)
(pin 31)
(pin 36)
(pin 37)
(pin 35)
(pin 33)
(pin 32)
IR
(pin 26)
(pin 8)
(pin 9)
REF CH 7 OUT
FSA
(pin 5)
(pin 6)
(pin 34)
READ
DALPHA
PR_I
(pin 28)
PWB (pin 7)
REF CH 8 OUT
REF CH 3 OUT
REF CH 2 OUT
REF CH 1 OUT
REF CH 6 OUT
REF CH 4 OUT
REF CH 5 OUT
S2V9 (pin 17)
VI-
VI+
FSRS
FSWS
FSOF
FSCLR
IFSA
FSR
FSW
PRFINE
PRCOARSE
PWO
PWMIN
PWMAX
PWO_I
DALPHA
Global Mixed-mode Technology Inc.
G569C
Fig 2. Block Diagram of G569C
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G569C
Global Mixed-mode Technology Inc.
Internal DAC Digital Format
12BIT SERIAL DATA
DATA
1
2
3
4
5
6
7
8
9
10
11
(LSB)
12
D11
D10
D9
D8
D7
D6
D5
D4
D3
D2
D1
D0
D1
D2
D3
D4
D5
D6
D7
: DAC DATA
CLK
Data Assignment
D0
(LSB)
D8
(MSB)
D9
D10
(MSB)
D11
: DAC SELECT DATA
(LSB)
DAC Select Data
D8
D9
D10
D11
0
0
0
0
0
0
0
1
Don’t Care
PRCOARSE Selection
DAC Selection
0
0
0
0
0
1
1
1
0
0
1
0
PRFINE Selection
VCAGAIN Selection
PWMIN Selection
0
1
0
1
PWMAX Selection
0
0
1
1
1
1
0
1
PWO Selection
DELTAP Selection
1
1
1
0
0
0
0
0
1
0
1
0
PWD Selection
WRITE Selection
ERASE Selection
1
1
0
1
1
0
1
0
Don’t Care
Don’t Care
1
1
1
1
0
1
1
0
Don’t Care
Don’t Care
1
1
1
1
Don’t Care
Digital Data Format for Internal DAC
D0
D1
D2
D3
D4
D5
D6
D7
0
0
0
0
0
0
0
0
DAC Output
0
1
0
1
0
1
1
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
0
VIN / 256 × 1
VIN / 256 × 2
VIN / 256 × 3
¦
1
¦
1
¦
1
¦
1
¦
1
¦
1
¦
1
¦
1
¦
VIN / 256 × 255
Digital Data Format for WRITE and ERASE
D0
D1
D2
D3
D4
D5
D6
D7
0
1
×
0/1
×
0/1
×
0/1
×
0/1
×
0/1
×
0/1
×
0/1
Comments
Disable Internal R2R Network
Enable Internal R2R Network D1 is LSB , D7 is MSB
TEL: 886-3-5788833
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Ver: 1.0
Oct 02, 2000
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G569C
Global Mixed-mode Technology Inc.
Timing Chart
R
LSB
MSB
DI
D11
D10
D0
D9
CLK
LD
VO
*Input data carried out LD signal Low besides CLK signal positive edge. CLK, LD is keep generally HIGH level.
AC Characteristics
Symbol
Parameter
Measurement Condition
Limit
Unit
tCKL
Clock “L” Pulse Width
200
nS
tCKH
tCR
Clock “H” Pulse Width
Clock Rise Time
200
nS
tCF
tDCH
tCHD
Clock Fall Time
Data Set Up Time
Data Hold Time
60
100
nS
nS
tCHL
LD Set Up Time
200
nS
tLDC
tLDH
LD Hold Time
LD “H” Pulse Duration Time
100
100
nS
nS
tDo
tLDD
Data Output Delay Time
D-A Output Setting Time
200
CL=100pF
CL ≤ 100pF,VAO:0.1< = > 2.6V
This Time Until The Output Becomes The final Value Of 1/2
LSB
70
nS
350
nS
300
µS
Timing Chart
t CR
t CF
t CKH
CLK
t CKL
t LDC
DI
t DCH
t CHD
t LDH
t CHL
LD
t LDD
D-A OUTPUT
t Do
Do OUTPUT
TEL: 886-3-5788833
http://www.gmt.com.tw
Ver: 1.0
Oct 02, 2000
9
G569C
Global Mixed-mode Technology Inc.
Package Information
C
L
E1 E
h x 45°
θ
D
A
A1
0.004 C
SEATING PLANE
e
b
MIN.
DIMENSION IN MM
NOM.
MAX.
MIN.
DIMENSION IN INCH
NOM.
A
2.413
2.591
2.794
0.095
0.102
0.110
A1
b
0.203
0.203
0.305
0.406
0.343
0.008
0.008
0.012
0.016
0.0135
c
D
0.127
15.75
0.254
16.00
0.005
0.620
e
E
E1
10.033
7.391
10.668
7.595
0.395
0.291
0.635
1.016
θ
0.015
1.020
SYMBOL
h
L
θ
15.88
0.635 BASIC
0.381
0.508
0
7.493
MAX.
0.010
0.630
0.625
0.025 BASIC
0
0.295
0.420
0.289
0.025
0.040
θ
TEL: 886-3-5788833
http://www.gmt.com.tw
Ver: 1.0
Oct 02, 2000
10
Global Mixed-mode Technology Inc.
G569C
Package Description: SSOP-48
Quantity /Reel
Reel Diameter
Carrier Tape (Width)
Carrier Tape (Pitch)
:
:
:
:
1000 / Reel
13”
32mm
16mm
Mechanical Polarization
Top View Shown With Cover Tape Removed
EIA-JEDEC SO Package Outline Style
Termination No.1
User Direction of Feed
GMT Inc. does not assume any responsibility for use of any circuitry described, no circuit patent licenses are implied and GMT Inc. reserves the right at any time without notice to change said circuitry and specifications.
TEL: 886-3-5788833
http://www.gmt.com.tw
Ver: 1.0
Oct 02, 2000
11