Features
● Crystal oscillator (SPXO)
● Frequency: 20 standard frequencies
(4 MHz to 72 MHz)
● Output: CMOS
● Supply voltage: 1.6 V to 3.63 V
● Operating temperature: -20 °C to +70 °C
-40 °C to +105 °C
Applications
● IoT, Wearable device
● Data center, Storage
● Medical, Industrial automation
Description
These SPXO have low current consumption, wide operating voltage from 1.6 V to 3.63 V and wide operating
temperature range from -40 °C to 85 °C, in addition operation up to 105 °C is available.
Outline Drawing and Terminal Assignment
SG2016CAN SG-210STF
SG3225CAN SG5032CAN
SG7050CAN Terminal Assignment
Crystal oscillator: SG2016 / 3225 / 5032 / 7050CAN & SG-210STF
SG2016CAN
(2.0 ×1.6 mm) SG-210STF
(2.5 ×2.0 mm)
× SG5032CAN
(5.0 ×3.2 mm) SG7050CAN
(7.0 ×5.0 mm)
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
Output terminal
VCC terminal
Function
#1
terminal
GND terminal
Page 1 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 1 ] Product Name / Product Number
(1-1) SG2016CAN
(1) Product Name (Standard Form)
①Model ②Output (C:CMOS) ③Frequency ④Supply voltage
⑤Frequency tolerance ⑥Operating temperature ⑦Internal identification code ("A" is default)
(2) Product Number / Ordering Code
SG2016
C
AN 25.000000MHz T J
H
A
①
②
③
④
⑤
⑥
⑦
⑤Frequency tolerance / ⑥Operating temperature
DB
±25 × 10-6 / -20 ºC to +70 ºC
JG
±50 × 10-6 / -40 ºC to +85 ºC
JH
±50 × 10-6 / -40 ºC to +105 ºC
T 1.8 V to 3.3 V Typ.
K 2.5 V to 3.3 V Typ.
*Figure 1 is on the next page
④Supply voltage Refer to Figure 1
DB JG JH
±25 × 10-6 ±50 × 10-6 ±50 × 10-6
-20 ºC to +70 ºC -40 ºC to +85 ºC -40 ºC to +105 ºC
4 - X1G004801003000 X1G004801004900
8 - X1G004801004500 X1G004801004600
10 - X1G004801002900 X1G004801002700
12 X1G004801005000 X1G004801000700 X1G004801005100
12.288 X1G004801005200 X1G004801004400 X1G004801005300
14.7456 - X1G004801005400 X1G004801005500
16 - X1G004801001400 X1G004801005600
20 X1G004801005700 X1G004801005800 X1G004801001800
24 X1G004801005900 X1G004801000200 X1G004801004000
24.576 - X1G004801006000 X1G004801003100
25 X1G004801002400 X1G004801001200 X1G004801003500
26 - X1G004801000300 X1G004801003900
27 - X1G004801006100 X1G004801002100
32 - X1G004801006200 X1G004801006300
33.33 - X1G004801006400 X1G004801006500
33.3333 - X1G004801002600 X1G004801006600
40 - X1G004801006700 X1G004801003600
48 X1G004801006800 X1G004801002000 X1G004801006900
50 X1G004801007000 X1G004801001300 X1G004801002800
72 X1G004801007100 X1G004801007200 X1G004801007300
Frequency tolerance / Operating temperature
Frequency [MHz]
Page 2 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(1-2) SG-210STF
(1) Product Name (Standard Form)
①Model ②Function (S:Standby) ③Supply voltage
④Frequency ⑤Frequency tolerance / Operating temperature
(2) Product Number / Ordering Code
SG-210
S
TF 25.000000MHz Y
①
②
③
④
⑤
S L Y
±25 × 10-6 ±50 × 10-6 ±50 × 10-6
-20 ºC to +70 ºC -40 ºC to +85 ºC -40 ºC to +105 ºC
4 - X1G004171000900 X1G004171029900
8 - X1G004171001500 X1G004171006900
10 - X1G004171001600 X1G004171036500
12 X1G004171016300 X1G004171001800 X1G004171028000
12.288 X1G004171006100 X1G004171001900 X1G004171036600
14.7456 - X1G004171002500 X1G004171036700
16 - X1G004171002700 X1G004171015400
20 X1G004171021800 X1G004171002900 X1G004171023800
24 X1G004171015600 X1G004171003100 X1G004171019700
24.576 - X1G004171003200 X1G004171036800
25 X1G004171007700 X1G004171003300 X1G004171005900
26 - X1G004171003400 X1G004171024400
27 - X1G004171003500 X1G004171025000
32 - X1G004171004000 X1G004171012700
33.33 - X1G004171011900 X1G004171030000
33.3333 - X1G004171012000 X1G004171007500
40 - X1G004171004500 X1G004171020600
48 X1G004171007800 X1G004171004600 X1G004171036900
50 X1G004171007900 X1G004171004700 X1G004171012600
72 X1G004171037000 X1G004171012400 X1G004171037100
Frequency [MHz]
Frequency tolerance / Operating temperature
S
±25 × 10-6 / -20 ºC to +70 ºC
L
±50 × 10-6 / -40 ºC to +85 ºC
Y
±50 × 10-6 / -40 ºC to +105 ºC
⑤Frequency tolerance / Operating temperature
T 1.8 V to 3.3 V Typ.
*Figure 1 is on the next page
③Supply voltage Refer to Figure 1
Page 3 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(1-3) SG3225CAN
(1) Product Name (Standard Form)
①Model ②Output (C:CMOS) ③Frequency ④Supply voltage
⑤Frequency tolerance ⑥Operating temperature ⑦Internal identification code ("A" is default)
(2) Product Number / Ordering Code
SG3225
C
AN 25.000000MHz T J
H
A
①
②
③
④
⑤
⑥
⑦
DB JG JH
±25 × 10-6 ±50 × 10-6 ±50 × 10-6
-20 ºC to +70 ºC -40 ºC to +85 ºC -40 ºC to +105 ºC
4 - X1G005961001115 X1G005961001215
8 - X1G005961000415 X1G005961001315
10 - X1G005961000515 X1G005961001415
12 X1G005961001515 X1G005961000615 X1G005961001615
12.288 X1G005961001715 X1G005961001815 X1G005961001915
14.7456 - X1G005961002015 X1G005961002115
16 - X1G005961002215 X1G005961002315
20 X1G005961002415 X1G005961000715 X1G005961002515
24 X1G005961002615 X1G005961000115 X1G005961002715
24.576 - X1G005961000815 X1G005961002815
25 X1G005961002915 X1G005961000215 X1G005961003015
26 - X1G005961003115 X1G005961003215
27 - X1G005961003315 X1G005961003415
32 - X1G005961003515 X1G005961003615
33.33 - X1G005961003715 X1G005961003815
33.3333 - X1G005961003915 X1G005961004015
40 - X1G005961000915 X1G005961004115
48 X1G005961004215 X1G005961000315 X1G005961004315
50 X1G005961004415 X1G005961001015 X1G005961004515
72 X1G005961004615 X1G005961004715 X1G005961004815
Frequency [MHz]
Frequency tolerance / Operating temperature
⑤Frequency tolerance / ⑥Operating temperature
DB
±25 × 10-6 / -20 ºC to +70 ºC
JG
±50 × 10-6 / -40 ºC to +85 ºC
JH
±50 × 10-6 / -40 ºC to +105 ºC
T 1.8 V to 3.3 V Typ.
K 2.5 V to 3.3 V Typ.
*Figure 1 is on the next page
④Supply voltage Refer to Figure 1
Page 4 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(1-4) SG5032CAN
(1) Product Name (Standard Form)
①Model ②Output (C:CMOS) ③Frequency ④Supply voltage
⑤Frequency tolerance ⑥Operating temperature ⑦Internal identification code ("A" is default)
(2) Product Number / Ordering Code
SG5032
C
AN 25.000000MHz T J
H
A
①
②
③
④
⑤
⑥
⑦
DB JG JH
±25 × 10-6 ±50 × 10-6 ±50 × 10-6
-20 ºC to +70 ºC -40 ºC to +85 ºC -40 ºC to +105 ºC
4 - X1G004451003400 X1G004451019600
8 - X1G004451002100 X1G004451019700
10 - X1G004451001300 X1G004451017800
12 X1G004451019800 X1G004451002800 X1G004451019900
12.288 X1G004451020000 X1G004451000100 X1G004451020100
14.7456 - X1G004451001900 X1G004451020200
16 - X1G004451000200 X1G004451020300
20 X1G004451020400 X1G004451001100 X1G004451020500
24 X1G004451017200 X1G004451000300 X1G004451020600
24.576 - X1G004451002900 X1G004451020700
25 X1G004451009700 X1G004451000400 X1G004451020800
26 - X1G004451008200 X1G004451020900
27 - X1G004451000500 X1G004451021000
32 - X1G004451001400 X1G004451021100
33.33 - X1G004451021200 X1G004451021300
33.3333 - X1G004451016700 X1G004451021400
40 - X1G004451001200 X1G004451021500
48 X1G004451014900 X1G004451000700 X1G004451011200
50 X1G004451011500 X1G004451000800 X1G004451003600
72 X1G004451021600 X1G004451021700 X1G004451021800
Frequency [MHz]
Frequency tolerance / Operating temperature
⑤Frequency tolerance / ⑥Operating temperature
DB
±25 × 10-6 / -20 ºC to +70 ºC
JG
±50 × 10-6 / -40 ºC to +85 ºC
JH
±50 × 10-6 / -40 ºC to +105 ºC
T 1.8 V to 3.3 V Typ.
K 2.5 V to 3.3 V Typ.
*Figure 1 is on the next page
④Supply voltage Refer to Figure 1
Page 5 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(1-5) SG7050CAN
(1) Product Name (Standard Form)
①Model ②Output (C:CMOS) ③Frequency ④Supply voltage
⑤Frequency tolerance ⑥Operating temperature ⑦Internal identification code ("A" is default)
(2) Product Number / Ordering Code
SG7050
C
AN 25.000000MHz T J
H
A
①
②
③
④
⑤
⑥
⑦
DB JG JH
±25 × 10-6 ±50 × 10-6 ±50 × 10-6
-20 ºC to +70 ºC -40 ºC to +85 ºC -40 ºC to +105 ºC
4 - X1G004481005100 X1G004481025200
8 - X1G004481001400 X1G004481025300
10 - X1G004481000500 X1G004481025400
12 X1G004481025500 X1G004481000600 X1G004481025600
12.288 X1G004481025700 X1G004481000100 X1G004481025800
14.7456 - X1G004481002500 X1G004481025900
16 - X1G004481000700 X1G004481026000
20 X1G004481012800 X1G004481000800 X1G004481026100
24 X1G004481002200 X1G004481000200 X1G004481026200
24.576 - X1G004481001600 X1G004481026300
25 X1G004481011600 X1G004481000300 X1G004481026400
26 - X1G004481003500 X1G004481026500
27 - X1G004481000400 X1G004481026600
32 - X1G004481000900 X1G004481026700
33.33 - X1G004481017900 X1G004481026800
33.3333 - X1G004481003300 X1G004481026900
40 - X1G004481001500 X1G004481027000
48 X1G004481022600 X1G004481001100 X1G004481027100
50 X1G004481011200 X1G004481001200 X1G004481016000
72 X1G004481027200 X1G004481018300 X1G004481027300
Frequency [MHz]
Frequency tolerance / Operating temperature
⑤Frequency tolerance / ⑥Operating temperature
DB
±25 × 10-6 / -20 ºC to +70 ºC
JG
±50 × 10-6 / -40 ºC to +85 ºC
JH
±50 × 10-6 / -40 ºC to +105 ºC
T 1.8 V to 3.3 V Typ.
K 2.5 V to 3.3 V Typ.
*Figure 1 is on the next page
④Supply voltage Refer to Figure 1
Page 6 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 2 ] Absolute Maximum Ratings
Min. Typ. Max.
Maximum supply voltage
VCC -0.3 - 4 V
Input voltage Vin -0.3 -
VCC + 0.3 V terminal
-55 - +125 °C SG2016CAN
-40 - +125 °C
All other
[ 3 ] Operating Range
Min. Typ. Max.
1.6 -3.63 V
fo ≤ 50 MHz,
T_use = +105 °C Max.
1.71 -3.63 V
fo = 72 MHz,
T_use = +85 °C Max.
2.25 -3.63 V
fo = 72 MHz,
T_use = +105 °C Max.
Supply voltage GND 0.0 0.0 0.0 V
-20 +25 +70 °C
-40 +25 +85 °C
-40 +25 +105 °C
CMOS load condition L_CMOS - - 15 pF
* Power supply startup time (0 %VCC → 90 %VCC
CC and GND pins located close to the device
[ 4 ] Frequency Characteristics (Unless stated otherwise [ 3 ] Operating Range)
Min. Typ. Max.
Output frequency fo MHz
-50 - +50
×10-6 T_use = -20 °C to +70 °C
-100 +100
×10-6
T_use = -40 °C to +105 °C
T_use = -40 °C to +85 °C *2
Frequency aging f_age -3 +3
×10-6 T_use = +25 °C, First year
*1 Frequency tolerance includes initial frequency tolerance, frequency / temperature characteristics, frequency / voltage coefficient,
and frequency / load coefficient
*2 This temperature range is only for fo = 72 MHz
Supply voltage
Operating temperature range
(Refer to Figure 1)
f_tol
Frequency tolerance *1
Unit
Conditions
Storage temperature range
T_stg
Parameter
Symbol
Parameter
Symbol
Specification
4, 8, 10, 12, 12.288, 14.7456, 16,
20, 24, 24.576, 25, 26, 27, 32,
33.33, 33.3333, 40, 48, 50, 72
Symbol
Specification
Unit
Conditions
Specification
Unit
Conditions
VCC
T_use
Figure 1: The upper limit of Operating temperature and the related conditions
Please note that Supply voltage range (VCC)
depends on Output frequency(fo) and upper
limit of Operating temperature(T_use Max.).
Parameter
f0[MHz]
Vcc[V]
1.60
1.71
3.63
1.2 60 75
105℃
85℃
2.25
3.63
2.25
1.60
4
1.71
50
72
Page 7 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 5 ] Electrical Characteristics (Unless stated otherwise [ 3 ] Operating Range)
Min. Typ. Max.
Start-up time t_str - - 3 ms
t = 0 at 90 %VCC
- - 1.5 mA
4 MHz ≤ fo ≤ 20 MHz
- - 1.8 mA
20 MHz < fo ≤ 40 MHz
- - 2.1 mA
40 MHz < fo ≤ 50 MHz
VCC = 1.8 V ± 5 % - - 2.4 mA fo = 72 MHz
- - 1.6 mA
4 MHz ≤ fo ≤ 20 MHz
- - 2.0 mA
20 MHz < fo ≤ 40 MHz
- - 2.4 mA
40 MHz < fo ≤ 50 MHz
- - 2.8 mA fo = 72 MHz
- - 1.8 mA
4 MHz ≤ fo ≤ 20 MHz
- - 2.2 mA
20 MHz < fo ≤ 40 MHz
- - 2.6 mA
40 MHz < fo ≤ 50 MHz
- - 3.0 mA fo = 72 MHz
- - 2.1 µA
VCC = 1.8 V ± 10 % or ± 5 %,
= GND
- - 2.5 µA
VCC = 2.5 V ± 10 %, = GND
- - 2.7 µA
VCC = 3.3 V ± 10 %, = GND
VOH 90 % VCC - - V
VOL - - 10 % VCC V
VOH VCC - 0.4 - - V
VOL - - 0.4 V
Symmetry SYM 45 50 55 %
50 % VCC level,
L_CMOS ≤ 15 pF
- - 3 ns
VCC = 2.5 V or 3.3 V ± 10 %,
20 % VCC to 80 % VCC Level,
L_CMOS = 15 pF
- -
3.5 ns
VCC = 1.8 V ± 10 % or ± 5 %,
20 % VCC to 80 % VCC Level,
L_CMOS = 15 pF
VIH 80 % Vcc - - V
VIL - - 20 % Vcc V
Output disable time (ST) tstp_st - - 100 ns
terminal HIGH LOW
Output enable time (ST) tsta_st - - 3 ms
terminal LOW HIGH
[ 6 ] Thermal resistance (For reference only)
Min. Typ. Max.
Junction temperature Tj - - +125 °C
-9.8 - °C/W SG2016CAN
-15.2 - °C/W SG-210STF
-23.1 - °C/W SG3225CAN
-16.1 - °C/W SG5032CAN
-28.0 - °C/W SG7050CAN
-99.6 - °C/W SG2016CAN
-91.9 - °C/W SG-210STF
-103.8 - °C/W SG3225CAN
-82.5 - °C/W SG5032CAN
-78.8 - °C/W SG7050CAN
Parameter
Symbol
Specification
Unit
Conditions
Junction to case
Junction to ambient
Rise time/Fall time
tr / tf
Input voltage
terminal
Stand-by current
I_std
Output voltage
Unit
Conditions
ICC
Current consumption (No load)
VCC = 2.5 V ± 10 %
Current consumption (No load)
VCC = 3.3 V ± 10 %
Parameter
Symbol
Specification
Current consumption (No load)
VCC = 1.8 V ± 10 %
Load current condition
1.8 V ± 10 % 2.5 V ± 10 % 3.3 V ± 10 %
IOH -1.5 mA -3 mA -4 mA
IOL 1.5 mA 3 mA 4 mA
Load current condition
1.8 V ± 10 % 2.5 V ± 10 % 3.3 V ± 10 %
IOH -3 mA -4 mA -6 mA
IOL 3 mA 4 mA 6 mA
Page 8 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 7 ] Typical Performance Characteristics (For reference only)
The following data shows typical performance characteristics
(7-1) Frequency / Temperature Characteristics
fo = 25 MHz, ±25 × 10-6 at -20 °C to +70 °C n = 50 pcs
fo = 25 MHz, ±50 × 10-6 at -40 °C to +85 °C/+105 °C n = 50 pcs
Page 9 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-2) Current Consumption
No load, T_use = +25 °C, Freq. Dependency
L_CMOS = 15 pF, T_use = +25 °C, Freq. Dependency
fo = 20 MHz
L_CMOS = 5 pF, Temperature Characteristic
T_use = +25 °C, Output load(L_CMOS) Characteristics
fo = 40 MHz
L_CMOS = 5 pF, Temperature Characteristic
T_use = +25 °C, Output load(L_CMOS) Characteristics
fo = 72 MHz
L_CMOS = 5 pF, Temperature Characteristic
T_use = +25 °C, Output load(L_CMOS) Characteristics
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
The actual current consumption is the total of the current under the condition of no load and the current to drive the
output load (fo × L_CMOS × VCC). To reduce the current consumption, it is effective to use lower frequency, lower
supply voltage and lower output load.
Page 10 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-3) Rise Time / Fall Time
fo = 20 MHz, Rise Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
fo = 20 MHz, Fall Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
Page 11 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-3) Rise Time / Fall Time [cont'd]
fo = 40 MHz, Rise Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
fo = 40 MHz, Fall Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
Page 12 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-3) Rise Time / Fall Time [cont'd]
fo = 72 MHz, Rise Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
There are some missing data in the graph. It is unmeasurable because of low amplitude under the condition of
L_CMOS > 15 pF.
fo = 72 MHz, Fall Time
20 % - 80 %VCC, L_CMOS = 15 pF, Temp. Char.
20 % - 80 %VCC, T_use = +25 °C, Output load Char.
10 % - 90 %VCC, L_CMOS = 15 pF, Temp. Char.
10 % - 90 %VCC, T_use = +25 °C, Output load Char.
* Output load condition under L_CMOS > 15 pF (dotted line area) is not guaranteed, and the data is for reference.
There are some missing data in the graph. It is unmeasurable because of low amplitude under the condition of
L_CMOS > 15 pF.
Page 13 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-4) Symmetry
fo = 20 MHz
50 %VCC, L_CMOS = 15 pF, Temp. Char.
fo = 40 MHz
50 %VCC, L_CMOS = 15 pF, Temp. Char.
fo = 72 MHz
50 %VCC, L_CMOS = 15 pF, Temp. Char.
Page 14 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-5) Output Voltage
fo = 20 MHz
VOH, L_CMOS = 15 pF, Temp. Char. VOL, L_CMOS = 15 pF, Temp. Char.
fo = 40 MHz
VOH, L_CMOS = 15 pF, Temp. Char. VOL, L_CMOS = 15 pF, Temp. Char.
fo = 72 MHz
VOH, L_CMOS = 15 pF, Temp. Char. VOL, L_CMOS = 15 pF, Temp. Char.
Page 15 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-6) Phase Noise, Phase Jitter, and Jitter
fo = 20 MHz
VCC = 3.3 V, T_use = +25 °C
VCC = 2.5 V, T_use = +25 °C
VCC = 1.8 V, T_use = +25 °C
Phase Jitter (Offset frequency: 12 kHz to 5 MHz)
VCC
3.3 V
2.5 V
1.8 V
Jitter (T_use = +25 °C, VCC = 3.3 V)
31.3 ps
1.8 ps
15 ps
fo = 40 MHz
VCC = 3.3 V, T_use = +25 °C
VCC = 2.5 V, T_use = +25 °C
VCC = 1.8 V, T_use = +25 °C
Phase Jitter (Offset frequency: 12 kHz to 20 MHz)
VCC
3.3 V
2.5 V
1.8 V
Jitter (T_use = +25 °C, VCC = 3.3 V)
22.3 ps
1.8 ps
16 ps
Peak to peak jitter
Phase Jitter
0.24 ps
0.26 ps
0.32 ps
Total jitter (BER = 10-12)
RMS jitter
Peak to peak jitter
Phase Jitter
0.31 ps
0.31 ps
0.32 ps
Total jitter (BER = 10-12)
RMS jitter
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
Page 16 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-6) Phase Noise and Phase Jitter [cont'd]
fo = 72 MHz
VCC = 3.3 V, T_use = +25 °C
VCC = 2.5 V, T_use = +25 °C
VCC = 1.8 V, T_use = +25 °C
Phase Jitter (Offset frequency: 12 kHz to 20 MHz)
VCC
3.3 V
2.5 V
1.8 V
Jitter (T_use = +25 °C, VCC = 3.3 V)
21.8 ps
1.8 ps
16 ps
0.17 ps
0.20 ps
Total jitter (BER = 10-12)
RMS jitter
Peak to peak jitter
Phase Jitter
0.16 ps
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
-180
-160
-140
-120
-100
-80
-60
-40
-20
0
110 100 1k 10k 100k 1M 10M 100M
Page 17 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-7) Output Waveform
fo = 20 MHz
VCC = 3.3 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 2.5 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 1.8 V, L_CMOS = 15 pF, T_use = +25 °C
fo = 40 MHz
VCC = 3.3 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 2.5 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 1.8 V, L_CMOS = 15 pF, T_use = +25 °C
Page 18 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(7-7) Output Waveform [cont'd]
fo = 72 MHz
VCC = 3.3 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 2.5 V, L_CMOS = 15 pF, T_use = +25 °C
VCC = 1.8 V, L_CMOS = 15 pF, T_use = +25 °C
Page 19 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 8 ] Test Circuit
(8-1) Waveform Observation
(8-2) Current Consumption Test
*Standby current test should be = GND.
(8-3) Condition
(1) Oscilloscope
The bandwidth should be minimum 5 times wider than measurement frequency
The probe ground should be placed closely to the test point and the lead length should be
as short as possible
(2) L_CMOS includes probe capacitance.
CC and GND pins located
close to the device
(4) Use a current meter with a low internal impedance
(5) Power Supply
Power supply startup time (0 %VCC 90 %VCC
Power supply impedance should be as low as possible
VCC
ST
OUT
GND
Switch
supply
by-pass
capacitor
L_CMOS
Test Point
VCC
ST
OUT
GND
Switch
supply
by-pass
capacitor
Test
Point
A
Page 20 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(8-4) Timing Chart
(1) Output Waveform and Level
(2) Output Frequency Timing
(3) Function and Timing
*1 The period from = VIL to OUT = High impedance (Disable)
*2 The period from = VIH to OUT = Enable
* Judge of starting output: VOH ≥ 80 %VCC, VOL ≤ 20 %Vcc, fout is within fo ± 1 000 × 10-6
* terminal voltage level should not exceed supply voltage when using function.
Please note that rise time should not exceed supply voltage rise time at the start-up.
Terminal Osc. circuit Output status
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
VCC
OUT
Output Stable
t_str
90 %VCC
0 V
VIH
VIL
Enable
OUT
High impedance
tstp_st
tsta_st
*1
*2
Page 21 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 9 ] Outline Drawing and Recommended Footprint
(9-1) SG2016CAN
Units: mm
For stable operation, it is recommended that
0.01 µF to 0.1 µF bypass capacitors should be
connected between VCC and GND and placed
as close to the VCC pin as possible.
Reference Weight Typ.: 9.9 mg
Terminal Assignment
Marking
Terminal coating : Au plating
Frequency tolerance /
Operating temperature
Frequency [MHz]
Production lot number
Model
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
GND terminal
Output terminal
VCC terminal
Function
#1
terminal
Page 22 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(9-2) SG-210STF
Units: mm
For stable operation, it is recommended that
0.01 µF to 0.1 µF bypass capacitors should be
connected between VCC and GND and placed
as close to the VCC pin as possible.
Reference Weight Typ.: 14 mg
Terminal Assignment
Marking
Terminal coating : Au plating
Model
Production lot number
Location of Pin #1
Frequency [MHz]
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
GND terminal
Output terminal
VCC terminal
Function
#1
terminal
Page 23 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(9-3) SG3225CAN
Units: mm
For stable operation, it is recommended that
0.01 µF to 0.1 µF bypass capacitors should be
connected between VCC and GND and placed
as close to the VCC pin as possible.
Reference Weight Typ.: 25 mg
Terminal Assignment
Marking
Lot code /
Operating temperature
Frequency [MHz]
Location of Pin #1
Model
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
GND terminal
Output terminal
VCC terminal
Function
#1
terminal
Page 24 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(9-4) SG5032CAN
Units: mm
For stable operation, it is recommended that
0.01 µF to 0.1 µF bypass capacitors should be
connected between VCC and GND and placed
as close to the VCC pin as possible.
Reference Weight Typ.: 52 mg
Terminal Assignment
Marking
Terminal coating : Au plating
Location of Pin #1
Model
Symbol
Frequency [MHz]
Production lot number
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
GND terminal
Output terminal
VCC terminal
Function
#1
terminal
Page 25 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(9-5) SG7050CAN
Units: mm
For stable operation, it is recommended that
0.01 µF to 0.1 µF bypass capacitors should be
connected between VCC and GND and placed
as close to the VCC pin as possible.
Reference Weight Typ.: 147 mg
Terminal Assignment
Marking
Model
Symbol
Frequency [MHz]
Production lot number
Terminal coating : Au plating
Pin # Connection
function Osc. Circuit Output
Oscillation Specified frequency: Enable
Oscillation stop High impedance: Disable
#2 GND
#3 OUT
#4 VCC
GND terminal
Output terminal
VCC terminal
Function
#1
terminal
Page 26 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 10 ] Moisture Sensitivity Level and Electro-Static Discharge Ratings
(10-1) Moisture Sensitivity Level (MSL)
Parameter
MSL
(10-2) Electro-Static Discharge (ESD)
Parameter
HBM
MM
CDM
AEC-Q100-011 (DCDM) * only for SG2016CAN
(10-3) Latch-Up
Parameter
Latch-up
[ 11 ] Reflow Profiles
IPC/JEDEC J-STD-020D.1
Specification
Conditions
100 mA Min.
EIAJ ED-4701-1 C113
Specification
Conditions
2 000 V Min.
200 V Min.
750 V Min
Specification
Conditions
LEVEL 1
IPC/JEDEC J-STD-020D.1
Page 27 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 12 ] Packing Information
(12-1) SG2016CAN
(1) Packing Quantity
The last two digits of the Product Number (X1G004801xxxxxx) are a code that defines the packing
quantity. The standard is "00" for a 3 000 pcs/Reel.
(2) Taping Specification
Subject to EIA-481, IEC-60286 and JIS C0806
1) Tape Dimensions
Carrier Tape Material: PS (Polystyrene)
Top Tape Material: PET (Polyethylene Terephthalate) +PE (Polyethylene)
Units: mm
2) Reel Dimensions
Center Material: PS (Polystyrene)
Reel Material: PS (Polystyrene)
Units: mm
3) Storage Environment
We recommend to keep less than +30 °C and 85 %RH of humidity in a packed condition,
and to use it less than 6 months after delivery.
0
+0 .1
0
+0 .1
1 .85±0 .1
3.5
±0.1
1 .0±0 .1
0 .25±0 .05
8.0
±0.2
1.75
±0.1
2 .0±0 .1
2.25
±0.1
4 .0±0 .1
4 .0 ±0 .1
φ1 .5
φ1 .0
○Epson
○
11.41.0
9.00.3
60.0
13.00.2
2.0
0.5
180.0
User direction of feed
Page 28 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(12-2) SG-210STF
(1) Packing Quantity
The last two digits of the Product Number (X1G004171xxxxxx) are a code that defines the packing
quantity. The standard is "00" for a 3 000 pcs/Reel.
(2) Taping Specification
Subject to EIA-481, IEC-60286 and JIS C0806
1) Tape Dimensions
Carrier Tape Material: PS (Polystyrene)
Top Tape Material: PET (Polyethylene Terephthalate) +PE (Polyethylene)
Units: mm
2) Reel Dimensions
Center Material: PS (Polystyrene)
Reel Material: PS (Polystyrene)
Units: mm
3) Storage Environment
We recommend to keep less than +30 °C and 85 %RH of humidity in a packed condition,
and to use it less than 6 months after delivery.
10 P: 400.1
2.00.1
4.00.1
1.0+0.1/-0
4.00.1
2.30.1
1.750.1
3.50.1
8.00.2
2.80.1
0.250.005
1.150.1
1.5
+0.1
-0
○
Epson
○
Epson
11.41.0
9.00.3
60.0
13.00.2
2.0
+0.3
-0
180.0
+0
-3.0
User direction of feed
Page 29 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(12-3) SG3225CAN
(1) Packing Quantity
The last two digits of the Product Number (X1G005961xxxxxx) are a code that defines the packing
quantity. The standard is "15" for a 2 000 pcs/Reel.
(2) Taping Specification
Subject to EIA-481, IEC-60286 and JIS C0806
1) Tape Dimensions
Carrier Tape Material: PS (Polystyrene)
Top Tape Material: PET (Polyethylene Terephthalate) +PE (Polyethylene)
Units: mm
2) Reel Dimensions
Center Material: PS (Polystyrene)
Reel Material: PS (Polystyrene)
Units: mm
3) Storage Environment
We recommend to keep less than +30 °C and 85 %RH of humidity in a packed condition,
and to use it less than 6 months after delivery.
10 P: 400.1
1.55
+0.
1
-0
2.00.1
4.00.1
1.00.1
4.00.1
2.80.1
1.750.1
3.50.1
8.00.2
3.50.1
0.250.05
1.40.1
User direction of feed
11.41.0
9.00.3
60.0
13.00.2
2.0
+0.3
-0
180.0
+0
-3.0
○
Epson
○
Page 30 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(12-4) SG5032CAN
(1) Packing Quantity
The last two digits of the Product Number (X1G004451xxxxxx) are a code that defines the packing
quantity. The standard is "00" for a 1 000 pcs/Reel.
(2) Taping Specification
Subject to EIA-481, IEC-60286 and JIS C0806
1) Tape Dimensions
Carrier Tape Material: PS (Polystyrene)
Top Tape Material: PET (Polyethylene Terephthalate) +PE (Polyethylene)
Units: mm
2) Reel Dimensions
Center Material: PS (Polystyrene)
Reel Material: PS (Polystyrene)
Units: mm
3) Storage Environment
We recommend to keep less than +30 °C and 85 %RH of humidity in a packed condition,
and to use it less than 6 months after delivery.
User direction of feed
Symbol A B C D E F
Value 4.0±0.1 8.0±0.1 7.25±0.2 12.0±0.2 1.40±0.1
+0.1/-0
13.0±1.0
60±1
180±2
2±0.2
A
B
D
E
C
F
Top tape
Carrier tape
○Epson
○Epson
Page 31 / 34
Spec No : SGxxxxCAN_E_Ver1.95
(12-5) SG7050CAN
(1) Packing Quantity
The last two digits of the Product Number (X1G004481xxxxxx) are a code that defines the packing
quantity. The standard is "00" for a 1 000 pcs/Reel.
(2) Taping Specification
Subject to EIA-481, IEC-60286 and JIS C0806
1) Tape Dimensions
Carrier Tape Material: PS (Polystyrene)
Top Tape Material: PET (Polyethylene Terephthalate) +PE (Polyethylene)
Units: mm
2) Reel Dimensions
Center Material: PS (Polystyrene)
Reel Material: PS (Polystyrene)
Units: mm
3) Storage Environment
We recommend to keep less than +30 °C and 85 %RH of humidity in a packed condition,
and to use it less than 6 months after delivery.
Φ1.5
4.0
9.25
16.0
8.0
2.3
Top tape
Carrier tape
User direction of feed
〇
〇
Epson
Page 32 / 34
Spec No : SGxxxxCAN_E_Ver1.95
[ 13 ] Handling Precautions
(https://www5.epsondevice.com/en/information/#precaution) for instructions on how to handle and use
the product properly to ensure optimal performance of the product in your equipment.
Before using the product under any conditions other than those specified therein,
please consult with us to verify and confirm that the performance of the product will not be negatively
affected by use under such conditions.
In addition to the foregoing precautions, in order to avoid the deteriorating performance of the product,
we strongly recommend that you DO NOT use the product under ANY of the following conditions:
(1) Mounting the product on a board using water-soluble solder flux and using the product without
removing the residue of the flux completely from the board. The residue of such flux that is soluble
in water or water-soluble cleaning agent, especially the residues which contains active halogens,
will negatively affect the performance and reliability of the product.
(2) Using the product in any manner that will result in any shock or impact to the product.
(3) Using the product in places where the product is exposed to water, chemicals, organic solvent,
sunlight, dust, corrosive gasses, or other materials.
(4) Using the product in places where the product is exposed to static electricity or electromagnetic waves.
(5) Applying ultrasonic cleaning without advance verification and confirmation that the product will
not be affected by such a cleaning process, because it may damage the crystal,
(6) Using the product under any other conditions that may negatively affect the performance and/or
reliability of the product.
(7) Power supply with ripple may cause of incorrect operation or degradation of phase noise characteristics,
so please evaluate before use.
(8) Supply voltage should be increased monotonically.
In addition, please do not power on at midpoint potential since that may cause malfunction or not output.
(9) Frequency aging is from environmental tests results to the expectation of the amount
of the frequency variation. This doesn't guarantee the product-life cycle.
Should any customer use the product in any manner contrary to the precautions and/or advice herein,
Page 33 / 34
Spec No : SGxxxxCAN_E_Ver1.95
PROMOTION OF ENVIRONMENTAL MANAGEMENT SYSTEM
CONFORMING TO INTERNATIONAL STANDARDS
At Seiko Epson, all environmental initiatives operate under the
Plan-Do-Check-Action (PDCA) cycle designed to achieve continuous
improvements. The environmental management system (EMS)
operates under the ISO 14001 environmental management standard.
All of our major manufacturing and non-manufacturing sites, in
Japan and overseas, completed the acquisition of ISO 14001 certification.
WORKING FOR HIGH QUALITY
In order provide high quality and reliable products and services
than meet customer needs, Seiko Epson made early efforts towards
obtaining ISO9000 series certification and has acquired ISO9001 for
all business establishments in Japan and abroad. We have also
acquired IATF 16949 certification that is requested strongly by major
manufacturers as standard.
■ Explanation of marks used in this datasheet
1. The content of this document is subject to change without notice. Before purchasing or using Epson products, please contact with sales
3. Information provided in this document including, but not limited to application circuits, programs and usage, is for reference purpose only.
resulting from the information. This document does not grant you any licenses, any intellectual property rights or any other rights with
respect to Epson products owned by Epson or any third parties.
4. Using Epson products, you shall be responsible for safe design in your products; that is, your hardware, software, and/or systems shall be
designed enough to prevent any critical harm or damages to life, health or property, even if any malfunction or failure might be caused by
Epson products. In designing your products with Epson products, please be sure to check and comply with the latest information
Using technical contents such as product data, graphic and chart, and technical information, including programs, algorithms and
application circuit examples under this document, you shall evaluate your products thoroughly both in stand-alone basis and within your
overall systems. You shall be solely responsible for deciding whether to adopt/use Epson products with your products.
5. Epson has prepared this document carefully to be accurate and dependable, but Epson does not guarantee that the information is always
accurate and complete. Epson assumes no responsibility for any damages you incurred due to any misinformation in this document.
6. No dismantling, analysis, reverse engineering, modification, alteration, adaptation, reproduction, etc., of Epson products is allowed.
7. Epson products have been designed, developed and manufactured to be used in general electronic applications and specifically
requires particular quality or extremely high reliability in order to refrain from causing any malfunction or failure leading to critical harm to
Therefore, you are strongly advised to use Epson products only for the Anticipated Purpose. Should you desire to purchase and use
Epson products for Specific Purpose, Epson makes no warranty and disclaims with respect to Epson products, whether express or
implied, including without limitation any implied warranty of merchantability or fitness for any Specific Purpose. Please be sure to
contact our sales representative in advance, if you desire Epson products for Specific Purpose:
Space equipment (artificial satellites, rockets, etc.)/ Transportation vehicles and their control equipment (automobiles, aircraft, trains,
ships, etc.) / Medical equipment/ Relay equipment to be placed on sea floor/ Power station control equipment / Disaster or crime
prevention equipment/Traffic control equipment/ Financial equipment
Other applications requiring similar levels of reliability as the above
8. Epson products listed in this document and our associated technologies shall not be used in any equipment or systems that laws and
regulations in Japan or any other countries prohibit to manufacture, use or sell. Furthermore, Epson products and our associated
technologies shall not be used for the purposes of military weapons development (e.g. mass destruction weapons), military use, or any
other military applications. If exporting Epson products or our associated technologies, please be sure to comply with the Foreign
Exchange and Foreign Trade Control Act in Japan, Export Administration Regulations in the U.S.A (EAR) and other export-related laws
and regulations in Japan and any other countries and to follow their required procedures.
9. Epson assumes no responsibility for any damages (whether direct or indirect) caused by or in relation with your non-compliance with the
terms and conditions in this document or for any damages (whether direct or indirect) incurred by any third party that you give, transfer or
assign Epson products.
10. For more details or other concerns about this document, please contact our sales representative.
11. Company names and product names listed in this document are trademarks or registered trademarks of their respective companies.
NOTICE: PLEASE READ CAREFULLY BELOW BEFORE THE USE OF THIS DOCUMENT ©Seiko Epson Corporation 2020
●Pb free.
●Complies with EU RoHS directive.
*About the products without the Pb-free mark.
Contains Pb in products exempted by EU RoHS directive
(Contains Pb in sealing glass, high melting temperature type solder or other)
ISO 14000 is an international standard for environmental
management that was established by the International Standards
Organization in 1996 against the background of growing concern
regarding global warming, destruction of the ozone layer, and global
deforestation.
IATF 16949 is the international standard that added the sector-
specific supplemental requirements for automotive industry based on
ISO9001.
Page 34 / 34
Spec No : SGxxxxCAN_E_Ver1.95
