How to Calculate the Beta of a Private Company

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A company’s beta is a measure of the volatility, or systematic risk, of a security, as it compares to the broader market. The beta of a company measures how the company’s equity market value changes with changes in the overall market. It is used in the capital asset pricing model (CAPM) to estimate the return of an asset.

Investors use different methods for calculating the beta of a public company versus a private company. In this article, we discuss the different approaches you can use to calculate a company’s beta.

Key Takeaways

  • Beta measures the systematic risk or volatility of a portfolio or individual security as it compares to the market as a whole.
  • Because market data is not available for private companies, you cannot estimate beta for private companies using stock prices.
  • One approach for private companies is to determine the industry average levered beta by finding the average beta of the publicly-traded companies that generate income from similar operations as the private company.
  • Another approach is to regress the company’s changes in historical earnings against the market return.

Beta as an Indicator

Beta, specifically, is the slope coefficient obtained through regression analysis of the stock return against the market return. You can use the following regression equation to estimate the beta of the company:


Δ S i = α + β i × Δ M + e where: Δ S i = change in price of stock  i α = intercept value of the regression β i = beta of the  i  stock return Δ M = change in the market price e = residual error term begin{aligned} &Delta S_i = alpha + beta_i times Delta M + e\ &textbf{where:}\ &Delta S_i=text{change in price of stock }i\ &alpha=text{intercept value of the regression}\ &beta_i=text{beta of the }i text{ stock return}\ &Delta M=text{change in the market price}\ &e = text{residual error term} \ end{aligned}
ΔSi=α+βi×ΔM+ewhere:ΔSi=change in price of stock iα=intercept value of the regressionβi=beta of the i stock returnΔM=change in the market pricee=residual error term

You can conduct such a regression analysis for publicly listed companies because you can use historical stock return data to make your calculations. But what about private companies?

Due to the lack of market data on the stock prices of private companies, it is not possible to estimate stock beta. Therefore, you’ll need to use other methods to estimate their beta.

Calculating Beta From Comparable Public Companies

In this approach, we first need to find the average beta of the publicly traded companies that generate income from similar operations as the private company. This will be a proxy for the industry average levered beta. Second, we need to unlever the average beta using the average debt-to-equity (D/E) ratio for these comparable companies. The final step is to re-lever beta, using the private company’s target debt-to-equity ratio.

Assume we want to estimate the beta of an illustrative energy services company with a target debt-to-equity ratio of 0.5, and the following companies are the most comparable companies:

The equity-weighted average beta of the four companies is 1.64. This is close to the arithmetic average of about 1.66. The chosen method to find the average beta may depend on the specifics of the data and size range of the comparable companies.

For instance, if there are three very small companies and one very large company, then a weighted average method will be biased toward the beta of the large company. In this particular example, however, we can take the weighted average beta as it is close to the arithmetic average, which gives equal weight to each company’s equity.

The next step is unlevering the average beta. For this, we need the average debt-to-equity ratio for these companies. The weighted average debt-to-equity ratio is 0.34. 


β u = β L 1 + ( 1 T ) × D E = 1.64 1 + ( 1 0.35 ) × 0.34 = 1.343 begin{aligned} beta_u &= frac{beta_L}{1 + (1 – T) times frac{D}{E}} \ &= frac{1.64}{1 + (1 – 0.35) times 0.34} \ &= 1.343 \ end{aligned}
βu=1+(1T)×EDβL=1+(10.35)×0.341.64=1.343

Thus, we get the unlevered beta of 1.343.

Where D/E is the average debt-to-equity ratio of the comparable companies, T is the tax rateBu the unlevered beta, and BL the levered beta.

In the final step, we need to re-lever the equity using the target debt-to-equity ratio of the private company, which equals 0.5.


β L = β U × [ 1 + ( 1 + T ) × D E ] = 1.343 × [ 1 + ( 1 0.35 ) × 0.5 ] = 1.78 begin{aligned} beta_L &= beta_U times [1 + (1 + T) times frac{D}{E}] \ &= 1.343 times [1 + (1 – 0.35) times 0.5]\ &= 1.78 \ end{aligned}
βL=βU×[1+(1+T)×ED]=1.343×[1+(10.35)×0.5]=1.78

In this example, the beta of the illustrative private company is higher than the average levered beta due to a higher target debt-to-equity ratio.

This method has certain pitfalls, including the fact that it neglects the difference between the size of the private company and that of the public company. Most of the time, publicly-traded companies are much larger in size compared to private ones.

Earnings Beta Approach

Usually, listed companies are large companies that operate in more than one segment. Therefore, it may be problematic to find a comparable firm whose beta would adequately represent the business beta of the private company being valued. For instance, Apple Inc. (AAPL) has a diverse set of operations, including personal computers, smartphones, tablets, and other items. This company would likely be poorly comparable to a private company that has a single operation, such as smartphone production.

When it is difficult to obtain reliable comparable beta, a company’s earnings beta can be used as a proxy for the levered beta. In this method, the company’s historical earnings changes are regressed against the market returns. An appropriate market index can be used as a proxy for the market. For instance, if the company is operating in the U.S. market, the S&P 500 can be used as a proxy.

Beta obtained from historical data needs to be adjusted to make sure that it reflects the company’s expected future performance. To reflect the mean-reverting feature of beta (beta tends to revert to one in the long run), we need to estimate adjusted beta using the following equation:


β adj = α + ( 1 + α ) × β h where: α = smoothing factor β h = historical beta β adj = adjusted beta begin{aligned} &beta_{text{adj}} = alpha + (1 + alpha) times beta_h \ &textbf{where:}\ &alpha=text{smoothing factor}\ &beta_h=text{historical beta}\ &beta_{text{adj}}=text{adjusted beta}\ end{aligned}
βadj=α+(1+α)×βhwhere:α=smoothing factorβh=historical betaβadj=adjusted beta

The smoothing factor can be derived through complex statistical analysis based on historical data, but as a rule of thumb, the value of 0.33 or (1/3) is used as a proxy.

The earnings beta approach also has some pitfalls. First, private companies do not usually have extensive historical earnings data for reliable regression analysis. Second, accounting earnings are subject to smoothing and accounting policy changes. Therefore, these may not be appropriate for statistical analysis, unless necessary adjustments have been made. 

The Bottom Line

The valuation of private companies using CAPM can be problematic because there is no straightforward method for estimating equity beta. To estimate the beta of a private company, there are two primary approaches.

One approach is to obtain a comparable levered beta from an industry average or from a comparable company (or companies) that best mimics the current business of the private company, unlever this beta, and then find the levered beta for the private company using the company’s target debt-to-equity ratio. Alternatively, one can find the beta of the company’s earnings and use it as a proxy for the company after appropriate adjustments are made.

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