Features and Applications of MEMS Clock Generators

Clock Generators are timing components which integrate the clock functionality of many different discrete devices into one semiconductor component. They offer the traditional semiconductor benefits of integration, lower cost, smaller size, and full customization with minimal additional expenses. Historically, the use of clock generators started with the expansion of the PC motherboard market in the early 1990s. At that time, the functionality of a PC motherboard was increasing dramatically – audio, networking, high-end-graphics, video and various interfaces were being added to a PC. Each of these additional components (in addition to the core processor and memory) required a clock, which necessitated the use of as many as 7 clocking devices on a single PC motherboard. Semiconductor companies started developing clock generators which integrated the clocking function of these 7 devices into one or two clock generators, which resulted in the benefit of lower cost and smaller footprint.

MEMS-based Clock Generators are completely Integrated

Every clock generator requires multiple PLLs (Phase Locked Loops) which are used to generate any specified frequency from a standard fixed frequency reference, which is usually an external clock source such as a quartz crystal or crystal oscillator. With the advent of MEMS resonators (which are available in the form of semiconductor die and can be completely integrated inside a plastic package), the need for having an external crystal or clock source goes away. Thus, a MEMS clock generator provides a completely integrated solution with no external reference clocks. A MEMS clock generator also eliminates the matching of the crystal with the clock generator circuit, which is a time-consuming problem to solve and may sometimes affect the performance of the system.

Features and Benefits of MEMS Clock Generators

* Completely integrated solutions, no external components required. MEMS resonator die (reference) is integrated inside package with analog circuit. 
* Functionality of 3 – 6 clock generators in one 7.0×5.0mm package, results in up to 66% board space savings. 
* Independent operating voltage on each of the PLLs, eliminates the need for external level translators, thus reducing component count and cost 
* Mixed differential and LVCMOS outputs in the same device, addressing the need for different clocking devices in complex systems. 
* Available spread spectrum capability to reduce system EMI and pass compliance testing.

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TCXO Oscillator

Clock Oscillator

Silicon MEMS VCXO Surpasses Quartz

Quartz has been the predominant technology of choice for timing references. Quartz oscillators consist of piezoelectric crystals with analog circuits in ceramic packages. They provide accurate and stable clocks that meet the requirements of most electronic applications. However, they have many inherent limitations, such as:

* Long lead times and lack of easy availability, due to complex manufacturing
* Lack of customization due to inflexibility
* Quality and performance variations over different lots and over different manufacturers
* Lack of integration

As semiconductors have grown in popularity, electronics manufacturers have turned to Silicon MEMS Timing solutions for their clocking needs. Silicon MEMS Timing solutions provide the following benefits:

* Better availability and short lead times through semiconductor manufacturing infrastructure
* Easy customization due to programmability
* Consistently high quality and reliability
* Significant integration
* High performance, particularly for high speed serial interfaces and programmable logic (FPGAs).

In the case of VCXOs (Voltage Controlled Oscillators), the benefits of MEMS solutions become even more evident. Below is a comparison of Quartz based VCXOs vs. Silicon MEMS VCXOs, which shows that MEMS is clearly superior to Quartz.

Quartz VCXO
* Core Technology - Pullable Crystals
* RMS Integrated Phase Jitter (12kHz - 20MHz) - < 1ps
* Frequency Offering - 10-15 standard frequencies (< 60 MHz)
* Pull Range - ±50PPM, ±100PPM, ±200PPM
* Pull Range Linearity - 10%
* Tuning Slope (Kv) Consistency - Poor Consistency
* Drive Strength for Impedance Matching, EMI Reduction - Not Available
* Product Coverage - Limited options for 1.8V, pull range or 3225 package
* Lead Time - 8-12 weeks for standard device & 16 weeks for non-standard device

MEMS VCXO
* Core Technology - All-Silicon MEMS
* Integrated Phase Jitter (12kHz - 20MHz) - < 1ps
* Frequency Offering - Any frequency up to 800MHz
* Pull Range - up to ±1600 PPM
* Pull Range Linearity - <1%
* Tuning Slope (Kv) Consistency - Excellent Consistency
* Drive Strength for Impedance Matching, EMI Reduction - Configurable
* Product Coverage - Any combination of voltage, pull range and package
* Lead Time - Samples in 48 hours & Production in 3-5 weeks

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Crystal Oscillator

Silicon MEMS VCXO Surpasses Quartz

Quartz has been the predominant technology of choice for timing references. Quartz oscillators consist of piezoelectric crystals with analog circuits in ceramic packages. They provide accurate and stable clocks that meet the requirements of most electronic applications. However, they have many inherent limitations, such as:

* Long lead times and lack of easy availability, due to complex manufacturing

* Lack of customization due to inflexibility

* Quality and performance variations over different lots and over different manufacturers

* Lack of integration

As semiconductors have grown in popularity, electronics manufacturers have turned to Silicon MEMS Timing solutions for their clocking needs. Silicon MEMS Timing solutions provide the following benefits:

* Better availability and short lead times through semiconductor manufacturing infrastructure

* Easy customization due to programmability

* Consistently high quality and reliability

* Significant integration

* High performance, particularly for high speed serial interfaces and programmable logic (FPGAs).

In the case of VCXOs (Voltage Controlled Oscillators), the benefits of MEMS solutions become even more evident. Below is a comparison of Quartz based VCXOs vs. Silicon MEMS VCXOs, which shows that MEMS is clearly superior to Quartz.

Quartz VCXO

* Core Technology - Pullable Crystals

* RMS Integrated Phase Jitter (12kHz - 20MHz) - < 1ps

* Frequency Offering - 10-15 standard frequencies (< 60 MHz)

* Pull Range - ±50PPM, ±100PPM, ±200PPM

* Pull Range Linearity - 10%

* Tuning Slope (Kv) Consistency - Poor Consistency

* Drive Strength for Impedance Matching, EMI Reduction - Not Available

* Product Coverage - Limited options for 1.8V, pull range or 3225 package

* Lead Time - 8-12 weeks for standard device & 16 weeks for non-standard device

MEMS VCXO

* Core Technology - All-Silicon MEMS

* Integrated Phase Jitter (12kHz - 20MHz) - < 1ps

* Frequency Offering - Any frequency up to 800MHz

* Pull Range - up to ±1600 PPM

* Pull Range Linearity - <1%

* Tuning Slope (Kv) Consistency - Excellent Consistency

* Drive Strength for Impedance Matching, EMI Reduction - Configurable

* Product Coverage - Any combination of voltage, pull range and package

* Lead Time - Samples in 48 hours & Production in 3-5 weeks

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Crystal Oscillator 

What is a VCXO? Why is a VCXO used in Electronics?

A VCXO – Voltage Controlled Oscillator– is a reference timing component that is commonly used in telecom, consumer and industrial electronics. A VCXO differs from an XO (Oscillator) in that it offers an capability to “fine-tune” the output frequency within a certain range, after the device is already populated in a system. This capability is not available on Xos.

Typically, a VCXO is used wherever a clock and data recovery function is performed. Usually, that involves receivers such as wireless base stations and other telecom equipment as well as consumer electronic devices such as Set Top Boxes (STB). The VCXO is part of a control loop that involves a PLL – Phase Locked Loop – that synchronizes the recovered clock on the receiver with the transmitted clock – to ensure that the two devices are locked and data integrity is maintained.

Pull range and Linearity are two key specs for VCXOs. Typically, crystal oscillator based VCXOs will offer a pull range of up to ±200 PPM of the output frequency. The maximum value of this “fine-tuning” capability is limited in a crystal-based VCXO because of the type of crystal and circuit that is used. This control is implemented on the analog oscillator circuit using varactors or switched capacitor arrays, which switch in and out as needed. In addition, a pullable crystal is also required – which is more expensive and not as easily available as a standard crystal resonator.

Pulling is achieved by an analog control voltage that is provided as input into the VCXO. The variation of the output frequency with this control input voltage is measured as linearity – the more linear a VCXO, the better control and characteristics it exhibits.

A silicon based VCXO offers much better pull range and linearity than a crystal-based VCXO. It does so because the “pulling” is done using Phase Locked Loops instead of varactors and pullable crystals – thus achieving a far larger pull range at a far better linearity. VCXOs that are based on Silicon MEMS will offer pull range of up to ±1600 PPM, as well as linearity of less than 1%, at comparable phase noise and jitter as crystal-based VCXOs. Thus, they are becoming the VCXOs of choice in electronics applications.

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Silicon Oscillator