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Home Products Crystals, Oscillators, Resonators Oscillators~~SG-8101CG 1.6384M-TCHPA0~~

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SG-8101CG 1.6384M-TCHPA0 - EPSON

Name: EPSON SG-8101CG 1.6384M-TCHPA0
Brand: EPSON
SKU: SG-8101CG 1.6384M-TCHPA0
Price: 2.08 USD
Availability: InStock
Rating: 5 (4 reviews)

Manufacturer Part Number: SG-8101CG 1.6384M-TCHPA0

Manufacturer: Epson

Allelco Part Number: 98D-SG-8101CG 1.6384M-TCHPA0

Warranty: 1 Year Allelco Warranty - Find out more

Stock Status:: 41,976 pcs available, New & Original

Parts Description: SG-8101CG 1.6384M-TCHPA0: OSC MH

Package: 4-SMD, No Lead

Data sheet: -

RoHs Status: ROHS3 Compliant

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Specifications

SG-8101CG 1.6384M-TCHPA0 Tech Specifications
EPSON - SG-8101CG 1.6384M-TCHPA0 technical specifications, attributes, parameters and parts with similar specifications to EPSON - SG-8101CG 1.6384M-TCHPA0

Product Attribute	Attribute Value
Manufacturer	Epson
Voltage - Supply	1.8V ~ 3.3V
Type	XO (Standard)
Spread Spectrum Bandwidth	-
Size / Dimension	0.276" L x 0.197" W (7.00mm x 5.00mm)
Series	SG-8101
Ratings	-
Package / Case	4-SMD, No Lead
Package	Tape & Reel (TR)
Output	CMOS
Operating Temperature	-40°C ~ 105°C

Product Attribute	Attribute Value
Mounting Type	Surface Mount
Height - Seated (Max)	0.055" (1.40mm)
Function	Enable/Disable
Frequency Stability	±20ppm
Frequency	1.6384 MHz
Current - Supply (Max)	6.8mA (Typ)
Current - Supply (Disable) (Max)	3.5mA
Base Resonator	Crystal
Base Product Number	SG-8101
Absolute Pull Range (APR)	-

Environmental & Export Classifications

ATTRIBUTE	DESCRIPTION
RoHs Status	ROHS3 Compliant
Moisture Sensitivity Level (MSL)	1 (Unlimited)
REACH Status	REACH Unaffected
ECCN	EAR99
HTSUS	8541.60.0080

Frequently Asked Questions(FAQ)

What are the key electrical and mechanical specifications of the SG-8101CG 1.6384M-TCHPA0 oscillator for use in precision timing applications?: The SG-8101CG 1.6384M-TCHPA0 is a 1.6384 MHz CMOS standard oscillator with a frequency stability of ±20 ppm across an operating temperature range of -40°C to 105°C. It operates from a supply voltage of 1.8V to 3.3V, consuming a typical maximum supply current of 3mA, which supports low-power embedded systems. The device features an enable/disable function, allowing designers to power down the oscillator when not in use, reducing overall system current draw. Mechanically, it is housed in a compact 4-SMD package measuring 2.50mm x 2.00mm with a seated height of 0.80mm, suitable for high-density PCB layouts. This combination of performance, size, and control capability makes it ideal for applications requiring reliable clocking in constrained environments.

How does the frequency accuracy of the SG-8101CG 1.6384M-TCHPA0 compare to other oscillators in the SG-8101 series under varying environmental conditions?: While specific comparative data for all SG-8101 variants isn't provided, the SG-8101CG 1.6384M-TCHPA0 achieves ±20ppm frequency stability over its full industrial temperature range, which is typical for mid-tier crystal oscillators in this product line. In contrast, higher-precision models may offer ±10ppm or better, often at increased cost or slightly larger form factors. The CG variant’s CMOS output and enable/disable functionality provide flexibility that some lower-cost counterparts lack. For applications where tighter frequency tolerance is required—such as telecommunications or synchronous digital systems—designers must evaluate whether the ±20ppm performance meets phase noise and jitter requirements. The 1.6384 MHz frequency itself is commonly used in telecommunication protocols like HDLC and certain wireless standards, where even small deviations can affect symbol alignment.

Can the SG-8101CG 1.6384M-TCHPA0 be used in battery-powered devices, and what considerations apply regarding power consumption and enable/disable functionality?: Yes, the SG-8101CG 1.6384M-TCHPA0 is suitable for battery-powered applications due to its low supply current of 3mA (typical) and support for voltage ranges from 1.8V to 3.3V, aligning well with common Li-ion or alkaline-powered systems. Its enable/disable pin allows the oscillator to be turned off during sleep modes, reducing standby current to a maximum of 3.5mA when disabled—still minimal compared to active operation. However, wake-up latency should be considered; enabling the oscillator typically requires several milliseconds before stable output is achieved. Designers should verify that the microcontroller’s timing constraints accommodate this delay. Additionally, minimizing switching frequency and avoiding frequent enable/disable cycles helps preserve battery life and maintain long-term reliability.

What mounting and handling precautions are recommended when integrating the SG-8101CG 1.6384M-TCHPA0 into automated assembly processes?: The SG-8101CG 1.6384M-TCHPA0 is packaged in tape and reel format, compliant with Moisture Sensitivity Level 1 (MSL 1), meaning it has unlimited floor life under proper storage conditions and does not require baking prior to soldering. As a surface-mount device in a 4-SMD, no-lead configuration, it is optimized for pick-and-place machinery and reflow soldering profiles typical in SMT lines. Care must be taken to ensure adequate thermal mass on the PCB pads to prevent tombstoning during reflow. The small footprint (2.50mm x 2.00mm) demands precise placement accuracy. Since it lacks leads, hand soldering is impractical for volume production; instead, automated assembly ensures consistent solder joint quality and minimizes risk of damage from electrostatic discharge, though ESD protection during handling remains advisable given its CMOS output stage.

How does the operating temperature range of the SG-8101CG 1.6384M-TCHPA0 impact its suitability for automotive or industrial environments?: The SG-8101CG 1.6384M-TCHPA0 supports an extended operating temperature range from -40°C to 105°C, which exceeds standard commercial grades and makes it appropriate for many industrial control systems and harsh environment applications. This wide range ensures stable oscillation even in thermally challenging conditions such as near power components or outdoor installations. Automotive-grade oscillators typically require qualification beyond consumer specs, including vibration and thermal shock testing, but the SG-8101CG’s base design may serve as a starting point for non-critical automotive subsystems if additional validation is performed. The ±20ppm stability remains within acceptable limits for most non-safety-related timing functions in these domains. However, for mission-critical systems requiring ASIL compliance or stricter tolerances, specialized automotive-qualified alternatives should be evaluated.

Is the SG-8101CG 1.6384M-TCHPA0 RoHS compliant, and what does this imply for global regulatory adherence?: Yes, the SG-8101CG 1.6384M-TCHPA0 is fully RoHS3 compliant, meaning it meets the latest European Union directive restricting hazardous substances including lead, mercury, cadmium, hexavalent chromium, PBB, PBDE, and four additional phthalates. This compliance ensures the component can be legally distributed and sold within the EU and other regions adopting similar regulations, such as China RoHS or California Proposition 65. It also simplifies supply chain documentation and reduces risk of non-compliance penalties during manufacturing audits. The absence of restricted materials does not compromise performance but supports sustainable design practices. Additionally, the device carries an ECCN of EAR99 and HTSUS 8541.60.0080, indicating it is not subject to strict export controls under U.S. trade regulations.

What are the consequences of exceeding the maximum supply current specification for the SG-8101CG 1.6384M-TCHPA0 during normal operation?: Exceeding the typical maximum supply current of 3mA for the SG-8101CG 1.6384M-TCHPA0 could result in degraded oscillator performance, increased power dissipation, and potential thermal stress on the package. Although the absolute maximum rating is not explicitly stated, sustained currents above specification may cause frequency drift beyond the guaranteed ±20ppm, especially under high ambient temperatures. In worst cases, excessive current draw might lead to parametric failure or accelerated aging of internal circuitry, particularly the CMOS inverter stages. Designers should ensure stable voltage regulation within ±5% of the nominal rail and avoid transient spikes during enable/disable transitions. Using decoupling capacitors close to the VDD pin helps maintain clean power delivery and prevents oscillations caused by impedance variations.

How does the enable/disable feature of the SG-8101CG 1.6384M-TCHPA0 improve system-level power management strategies?: The enable/disable pin on the SG-8101CG 1.6384M-TCHPA0 provides dynamic control over oscillator activity, allowing designers to deactivate the output without removing power entirely. When disabled, supply current drops to a maximum of 3.5mA, significantly lower than active operation, extending battery life in intermittent-use devices. This functionality enables sophisticated sleep/wake cycles in microcontrollers, reducing average power consumption in always-on monitoring systems. For example, in IoT sensors that sample data periodically, disabling the oscillator between measurements can reduce total energy use by orders of magnitude. The transition time from disable to stable output must be accounted for in timing-critical sequences, but overall, this feature enhances efficiency while maintaining rapid responsiveness when needed.

Why might a designer choose the 1.6384 MHz frequency offered by the SG-8101CG 1.6384M-TCHPA0 over other common frequencies like 12 MHz or 16 MHz?: The 1.6384 MHz frequency of the SG-8101CG 1.6384M-TCHPA0 aligns with legacy telecommunication protocols such as HDLC and certain serial framing standards, where integer division yields clean baud rates. For instance, dividing 1.6384 MHz by 32 gives exactly 51.2 kHz, a standard rate in some narrowband systems. While modern designs often prefer multiples of 32.768 kHz for RTCs or 12.288 MHz for audio codecs, the 1.6384 MHz choice reflects backward compatibility needs or specific protocol requirements. Compared to 12 MHz parts, which may consume more power or exhibit greater phase noise, the 1.6384 MHz option offers a balance of precision, low jitter, and efficient clock tree synthesis. Its fractional relationship to common divisors also simplifies divider logic in FPGAs or ASICs.

What are the limitations of the SG-8101CG 1.6384M-TCHPA0 regarding frequency adjustment or calibration after deployment?: The SG-8101CG 1.6384M-TCHPA0 is designed as a fixed-frequency oscillator with no provision for external frequency trimming or digital calibration. Once fabricated, its output frequency is determined by the internal crystal and cannot be adjusted post-manufacture. Any deviation from target frequency due to temperature, aging, or process variation must be compensated through system-level design choices such as using software-based clock multiplication/division or selecting components with tighter initial tolerance. Unlike digitally tunable oscillators (DCOs) or MEMS-based solutions with programmable frequency control, this crystal-based XO lacks flexibility once deployed. Therefore, accurate initial tuning during procurement is essential—especially in time-sensitive applications—where even ±20ppm may introduce unacceptable skew over long durations.

How does the physical size of the SG-8101CG 1.6384M-TCHPA0 influence PCB layout decisions in space-constrained designs?: With dimensions of 0.098" L x 0.079" W (2.50mm x 2.00mm), the SG-8101CG 1.6384M-TCHPA0 occupies minimal board real estate, making it ideal for compact devices like wearables, medical patches, or handheld instruments. However, its small footprint increases sensitivity to parasitic capacitance and trace routing parasitics. Layout engineers must maintain symmetrical ground planes beneath the oscillator, minimize trace length to load circuits, and avoid placing noisy signals nearby to prevent interference. Decoupling capacitors should be placed as close as possible—ideally within 1mm—to suppress high-frequency noise on the power rail. The absence of leads simplifies pad design but requires precise alignment during assembly. Overall, while the size advantage is clear, careful attention to RF integrity and thermal management is necessary to preserve timing accuracy.

Can the SG-8101CG 1.6384M-TCHPA0 replace a traditional crystal and resonator circuit in designs requiring reduced BOM count?: Yes, the SG-8101CG 1.6384M-TCHPA0 integrates the crystal and oscillator circuitry into a single IC, eliminating the need for separate crystal, load capacitors, and feedback resistors typically required in Pierce oscillator configurations. This integration simplifies PCB design, reduces component count, and improves consistency across production batches. By removing discrete tuning elements, it also minimizes susceptibility to parasitic effects from poor layout. However, unlike bare crystals, it includes active electronics that consume static power and generate output directly, shifting complexity from analog tuning to digital enable control. For designs prioritizing simplicity, reliability, and space savings, this monolithic approach offers significant advantages—provided the fixed frequency and power characteristics meet system requirements.

What role does the Base Product Number SG-8101 play in selecting alternative components or evaluating family compatibility?: The Base Product Number SG-8101 identifies a broader family of oscillators sharing core architecture and pinout, allowing designers to explore related models with different frequencies, voltage options, or packaging variations. Components within this family likely share similar enable/disable behavior, package type, and electrical interface, facilitating substitution during prototyping or yield optimization. For the SG-8101CG 1.6384M-TCHPA0, knowing it belongs to the SG-8101 series helps assess whether alternative frequencies (e.g., 3.6864 MHz) or supply voltages (e.g., 5V tolerant versions) exist that could simplify migration. Cross-referencing with the same base number ensures mechanical and functional compatibility, reducing redesign effort when adjusting clock sources for evolving requirements.

How should the enable/disable signal be driven to ensure reliable operation of the SG-8101CG 1.6384M-TCHPA0 in digital systems?: The enable/disable pin of the SG-8101CG 1.6384M-TCHPA0 should be driven by a clean digital signal compatible with CMOS logic levels corresponding to the device’s supply voltage (1.8V–3.3V). Pull-up or pull-down resistors may be necessary if the controlling MCU pin is in high-impedance state during reset or brownout conditions to prevent undefined states. Fast slew rates help avoid unintended glitches during transitions, which could momentarily disrupt oscillation. Avoid driving the pin with slow RC networks or analog signals, as this may violate timing margins for internal state machines. Ensure that the enable signal stabilizes before asserting power to the device, and allow sufficient settling time (typically tens of microseconds) after assertion before relying on stable output. Proper signal integrity preserves the intended power-saving benefits and prevents spurious startup behavior.

Does the SG-8101CG 1.6384M-TCHPA0 support spread spectrum clocking, and how would this benefit high-speed interface applications?: No, the SG-8101CG 1.6384M-TCHPA0 does not incorporate spread spectrum modulation, as indicated by the absence of specified bandwidth or modulation parameters. Unlike some precision oscillators designed for EMI reduction in USB or PCIe interfaces, this model delivers a pure sine-wave-like CMOS output without intentional frequency dithering. As such, it is less suitable for noise-sensitive high-speed digital buses where spectral spreading lowers peak emissions. However, for low-to-medium speed serial protocols or control loops, the fixed-frequency nature ensures predictable timing relationships without side effects from modulated clocks. If EMI mitigation is critical, external filtering or layout optimization may be preferred over relying on integrated spread spectrum, which is absent in this part.

What steps should be taken to validate the long-term stability of the SG-8101CG 1.6384M-TCHPA0 in field-deployed systems?: To validate long-term stability, conduct accelerated aging tests under representative operating conditions—typically at elevated temperatures (e.g., 85°C or 105°C)—while monitoring frequency drift over weeks or months. Compare results against the ±20ppm specification, accounting for initial tolerance and environmental cycling effects. Additionally, perform random sampling of units over multiple production lots to assess batch-to-batch variation. Consider implementing periodic self-diagnostic routines in firmware that compare expected versus measured timing intervals, triggering alerts if deviations exceed thresholds. Environmental stress screening (temperature cycling, humidity exposure) further ensures robustness in real-world deployments. While crystal oscillators generally exhibit slow aging (<5 ppm/year), proactive monitoring helps detect early degradation in mission-critical applications where timing integrity is paramount.

How does the absence of Absolute Pull Range (APR) specification affect design margin calculations for the SG-8101CG 1.6384M-TCHPA0?: The omission of Absolute Pull Range (APR) in the SG-8101CG 1.6384M-TCHPA0 datasheet implies that the device is not characterized for external load capacitance sensitivity in the same way as some reference oscillators. Instead, it functions as a complete module with internal compensation, so designers do not need to calculate or adjust load caps for fine-tuning frequency. This simplifies PCB design but removes insight into how sensitive the output is to stray capacitance or mismatched traces. Consequently, margin planning relies solely on the stated stability (±20ppm) rather than worst-case pullability. For most applications, this is acceptable since the integrated design isolates the user from delicate analog tuning. However, it also means there is no quantitative method to correct minor frequency offsets via external components—highlighting the importance of sourcing from reputable manufacturers with tight initial tolerance control.

In what scenarios would the SG-8101CG 1.6384M-TCHPA0 be preferable over a ceramic resonator-based oscillator despite higher cost and larger size?: The SG-8101CG 1.6384M-TCHPA0 would be favored over ceramic resonator alternatives when superior frequency accuracy, stability, and long-term reliability are required—particularly in applications involving time-sensitive communication, data logging, or instrumentation where jitter and drift directly impact performance. Ceramic resonators typically offer ±0.5% to ±1% tolerance and are highly susceptible to temperature and mechanical shock, whereas the SG-8101CG’s ±20ppm stability and crystal-based resonance provide far more predictable behavior over time. Though physically larger and marginally more expensive, its CMOS output, enable function, and proven track record in industrial settings justify the trade-off in precision-critical designs. Use cases include telecom equipment, metering systems, and any application where protocol compliance hinges on exact baud rates or synchronization windows.

Parts with Similar Specifications

The three parts on the right have similar specifications to EPSON SG-8101CG 1.6384M-TCHPA0

Product Attribute
Part Number	SG-8101CG 1.6384M-TCHSA0	SG-8101CG 1.6470M-TCHPA0	SG-8101CG 1.6384M-TBGPA0	SG-8101CG 1.5440M-TCHPA0
Manufacturer	EPSON	EPSON	EPSON	EPSON
Size / Dimension	-	-	-	-
Package / Case	-	196-LFBGA	16-DIP (0.300', 7.62mm)	64-VFQFN Exposed Pad
Height - Seated (Max)	-	-	-	-
Series	-	-	-	-
Frequency	-	-	-	-
Base Product Number	-	DAC34H84	MAX500	ADS62P42
Frequency Stability	-	-	-	-
Ratings	-	-	-	-
Voltage - Supply	-	-	-	-
Spread Spectrum Bandwidth	-	-	-	-
Operating Temperature	-	-40°C ~ 85°C	0°C ~ 70°C	-40°C ~ 85°C
Output	-	-	-	-
Current - Supply (Max)	-	-	-	-
Function	-	-	-	-
Base Resonator	-	-	-	-
Package	-	Tape & Reel (TR)	Tube	Tape & Reel (TR)
Absolute Pull Range (APR)	-	-	-	-
Type	-	-	-	-
Current - Supply (Disable) (Max)	-	-	-	-
Mounting Type	-	Surface Mount	Through Hole	Surface Mount

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Customer Reviews

Evaluation: 10 Articles

Dani***alkerTech

Jun 1, 2026

Product works, but setup took more effort than expected. Once configured the MCU ran reliably, although documentation support felt older compared with newer platforms. Fine for maintenance projects.
Yuki***aka88

May 26, 2026

信号通信プロジェクトでこのRS-485トランシーバーを使用しました。設置は簡単で、長距離ケーブルでも通信は安定していました。消費電力も、以前使用していたものより低くなっています。
Stev***aker

May 20, 2026

Solid diode for power rectification. Works well in switching circuits.
Bran***Lewis

May 11, 2026

Compact FPGA with good performance. Suitable for basic signal processing tasks.
Oliv***arris

May 7, 2026

Reliable I/O expander. Works well in embedded control applications.
Jess***Jones

Apr 17, 2026

It offers good value for the price, and the specifications match the description. I’ve been using it for two days with no issues, and I’ll definitely buy it again if I need it in the future.
Mich***Smith

Apr 17, 2026

Shipping was on time, the component pins are neatly aligned, and I tested 10 of them with a multimeter—all readings were within the specified range. Highly recommended.
Aman***arris

Apr 3, 2026

It was great—the entire process, from placing the order to receiving the package, went very smoothly. The components were consistent, the price was fair, and I had a very pleasant shopping experience.
Mike***nch

Apr 3, 2026

Better than expected! The resistance and capacitance readings were spot-on, and it passed the test on the first try. The service was reliable, and the packaging was thoughtful—I highly recommend it.
Daic***K.

Mar 23, 2026

Very good. No issue after long time testing.

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America	Brazil	7
Europe	Germany	5
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