PINE LIBRARY

RiskMetrics

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█  OVERVIEW


This library is a tool for Pine programmers that provides functions for calculating risk-adjusted performance metrics on periodic price returns. The calculations used by this library's functions closely mirror those the Broker Emulator uses to calculate strategy performance metrics (e.g., Sharpe and Sortino ratios) without depending on strategy-specific functionality.



█  CONCEPTS


Returns, risk, and volatility

The return on an investment is the relative gain or loss over a period, often expressed as a percentage. Investment returns can originate from several sources, including capital gains, dividends, and interest income. Many investors seek the highest returns possible in the quest for profit. However, prudent investing and trading entails evaluating such returns against the associated risks (i.e., the uncertainty of returns and the potential for financial losses) for a clearer perspective on overall performance and sustainability.

One way investors and analysts assess the risk of an investment is by analyzing its volatility, i.e., the statistical dispersion of historical returns. Investors often use volatility in risk estimation because it provides a quantifiable way to gauge the expected extent of fluctuation in returns. Elevated volatility implies heightened uncertainty in the market, which suggests higher expected risk. Conversely, low volatility implies relatively stable returns with relatively minimal fluctuations, thus suggesting lower expected risk. Several risk-adjusted performance metrics utilize volatility in their calculations for this reason.


Risk-free rate

The risk-free rate represents the rate of return on a hypothetical investment carrying no risk of financial loss. This theoretical rate provides a benchmark for comparing the returns on a risky investment and evaluating whether its excess returns justify the risks. If an investment's returns are at or below the theoretical risk-free rate or the risk premium is below a desired amount, it may suggest that the returns do not compensate for the extra risk, which might be a call to reassess the investment.

Since the risk-free rate is a theoretical concept, investors often utilize proxies for the rate in practice, such as Treasury bills and other government bonds. Conventionally, analysts consider such instruments "risk-free" for a domestic holder, as they are a form of government obligation with a low perceived likelihood of default.

The average yield on short-term Treasury bills, influenced by economic conditions, monetary policies, and inflation expectations, has historically hovered around 2-3% over the long term. This range also aligns with central banks' inflation targets. As such, one may interpret a value within this range as a minimum proxy for the risk-free rate, as it may correspond to the minimum rate required to maintain purchasing power over time.

The built-in Sharpe and Sortino ratios that strategies calculate and display in the Performance Summary tab use a default risk-free rate of 2%, and the metrics in this library's example code use the same default rate. Users can adjust this value to fit their analysis needs.


Risk-adjusted performance

Risk-adjusted performance metrics gauge the effectiveness of an investment by considering its returns relative to the perceived risk. They aim to provide a more well-rounded picture of performance by factoring in the level of risk taken to achieve returns. Investors can utilize such metrics to help determine whether the returns from an investment justify the risks and make informed decisions.

The two most commonly used risk-adjusted performance metrics are the Sharpe ratio and the Sortino ratio.

1. Sharpe ratio
  The Sharpe ratio, developed by Nobel laureate William F. Sharpe, measures the performance of an investment compared to a theoretically risk-free asset, adjusted for the investment risk. The ratio uses the following formula:

  Sharpe Ratio = (𝑅𝑎 − 𝑅𝑓) / 𝜎𝑎

  Where:
   • 𝑅𝑎 = Average return of the investment
   • 𝑅𝑓 = Theoretical risk-free rate of return
   • 𝜎𝑎 = Standard deviation of the investment's returns (volatility)

  A higher Sharpe ratio indicates a more favorable risk-adjusted return, as it signifies that the investment produced higher excess returns per unit of increase in total perceived risk.

2. Sortino ratio
  The Sortino ratio is a modified form of the Sharpe ratio that only considers downside volatility, i.e., the volatility of returns below the theoretical risk-free benchmark. Although it shares close similarities with the Sharpe ratio, it can produce very different values, especially when the returns do not have a symmetrical distribution, since it does not penalize upside and downside volatility equally. The ratio uses the following formula:

  Sortino Ratio = (𝑅𝑎 − 𝑅𝑓) / 𝜎𝑑

  Where:
   • 𝑅𝑎 = Average return of the investment
   • 𝑅𝑓 = Theoretical risk-free rate of return
   • 𝜎𝑑 = Downside deviation (standard deviation of negative excess returns, or downside volatility)

  The Sortino ratio offers an alternative perspective on an investment's return-generating efficiency since it does not consider upside volatility in its calculation. A higher Sortino ratio signifies that the investment produced higher excess returns per unit of increase in perceived downside risk.



█  CALCULATIONS


Return period detection

Calculating risk-adjusted performance metrics requires collecting returns across several periods of a given size. Analysts may use different period sizes based on the context and their preferences. However, two widely used standards are monthly or daily periods, depending on the available data and the investment's duration. The built-in ratios displayed in the Strategy Tester utilize returns from either monthly or daily periods in their calculations based on the following logic:

 • Use monthly returns if the history of closed trades spans at least two months.
 • Use daily returns if the trades span at least two days but less than two months.
 • Do not calculate the ratios if the trade data spans fewer than two days.

This library's `detectPeriod()` function applies related logic to available chart data rather than trade data to determine which period is appropriate:

 • It returns true if the chart's data spans at least two months, indicating that it's sufficient to use monthly periods.
 • It returns false if the chart's data spans at least two days but not two months, suggesting the use of daily periods.
 • It returns na if the length of the chart's data covers less than two days, signifying that the data is insufficient for meaningful ratio calculations.

It's important to note that programmers should only call `detectPeriod()` from a script's global scope or within the outermost scope of a function called from the global scope, as it requires the time value from the first bar to accurately measure the amount of time covered by the chart's data.


Collecting periodic returns

This library's `getPeriodicReturns()` function tracks price return data within monthly or daily periods and stores the periodic values in an array. It uses a `detectPeriod()` call as the condition to determine whether each element in the array represents the return over a monthly or daily period.

The `getPeriodicReturns()` function has two overloads. The first overload requires two arguments and outputs an array of monthly or daily returns for use in the `sharpe()` and `sortino()` methods. To calculate these returns:

 1. The `percentChange` argument should be a series that represents percentage gains or losses. The values can be bar-to-bar return percentages on the chart timeframe or percentages requested from a higher timeframe.
 2. The function compounds all non-na `percentChange` values within each monthly or daily period to calculate the period's total return percentage. When the `percentChange` represents returns from a higher timeframe, ensure the requested data includes gaps to avoid compounding redundant values.
 3. After a period ends, the function queues the compounded return into the array, removing the oldest element from the array when its size exceeds the `maxPeriods` argument.

The resulting array represents the sequence of closed returns over up to `maxPeriods` months or days, depending on the available data.

The second overload of the function includes an additional `benchmark` parameter. Unlike the first overload, this version tracks and collects differences between the `percentChange` and the specified `benchmark` values. The resulting array represents the sequence of excess returns over up to `maxPeriods` months or days. Passing this array to the `sharpe()` and `sortino()` methods calculates generalized Information ratios, which represent the risk-adjustment performance of a sequence of returns compared to a risky benchmark instead of a risk-free rate. For consistency, ensure the non-na times of the `benchmark` values align with the times of the `percentChange` values.


Ratio methods

This library's `sharpe()` and `sortino()` methods respectively calculate the Sharpe and Sortino ratios based on an array of returns compared to a specified annual benchmark. Both methods adjust the annual benchmark based on the number of periods per year to suit the frequency of the returns:

 • If the method call does not include a `periodsPerYear` argument, it uses `detectPeriod()` to determine whether the returns represent monthly or daily values based on the chart's history. If monthly, the method divides the `annualBenchmark` value by 12. If daily, it divides the value by 365.
 • If the method call does specify a `periodsPerYear` argument, the argument's value supersedes the automatic calculation, facilitating custom benchmark adjustments, such as dividing by 252 when analyzing collected daily stock returns.

When the array passed to these methods represents a sequence of excess returns, such as the result from the second overload of `getPeriodicReturns()`, use an `annualBenchmark` value of 0 to avoid comparing those excess returns to a separate rate.

By default, these methods only calculate the ratios on the last available bar to minimize their resource usage. Users can override this behavior with the `forceCalc` parameter. When the value is true, the method calculates the ratio on each call if sufficient data is available, regardless of the bar index.



Look first. Then leap.



█  FUNCTIONS & METHODS


This library contains the following functions:

detectPeriod()
  Determines whether the chart data has sufficient coverage to use monthly or daily returns
for risk metric calculations.
  Returns: (bool) `true` if the period spans more than two months, `false` if it otherwise spans more
than two days, and `na` if the data is insufficient.

getPeriodicReturns(percentChange, maxPeriods)
  (Overload 1 of 2) Tracks periodic return percentages and queues them into an array for ratio
calculations. The span of the chart's historical data determines whether the function uses
daily or monthly periods in its calculations. If the chart spans more than two months,
it uses "1M" periods. Otherwise, if the chart spans more than two days, it uses "1D"
periods. If the chart covers less than two days, it does not store changes.
  Parameters:
    percentChange (float): (series float) The change percentage. The function compounds non-na values from each
chart bar within monthly or daily periods to calculate the periodic changes.
    maxPeriods (simple int): (simple int) The maximum number of periodic returns to store in the returned array.
  Returns: (array<float>) An array containing the overall percentage changes for each period, limited
to the maximum specified by `maxPeriods`.

getPeriodicReturns(percentChange, benchmark, maxPeriods)
  (Overload 2 of 2) Tracks periodic excess return percentages and queues the values into an
array. The span of the chart's historical data determines whether the function uses
daily or monthly periods in its calculations. If the chart spans more than two months,
it uses "1M" periods. Otherwise, if the chart spans more than two days, it uses "1D"
periods. If the chart covers less than two days, it does not store changes.
  Parameters:
    percentChange (float): (series float) The change percentage. The function compounds non-na values from each
chart bar within monthly or daily periods to calculate the periodic changes.
    benchmark (float): (series float) The benchmark percentage to compare against `percentChange` values.
The function compounds non-na values from each bar within monthly or
daily periods and subtracts the results from the compounded `percentChange` values to
calculate the excess returns. For consistency, ensure this series has a similar history
length to the `percentChange` with aligned non-na value times.
    maxPeriods (simple int): (simple int) The maximum number of periodic excess returns to store in the returned array.
  Returns: (array<float>) An array containing monthly or daily excess returns, limited
to the maximum specified by `maxPeriods`.

method sharpeRatio(returnsArray, annualBenchmark, forceCalc, periodsPerYear)
  Calculates the Sharpe ratio for an array of periodic returns.
Callable as a method or a function.
  Namespace types: array<float>
  Parameters:
    returnsArray (array<float>): (array<float>) An array of periodic return percentages, e.g., returns over monthly or
daily periods.
    annualBenchmark (float): (series float) The annual rate of return to compare against `returnsArray` values. When
`periodsPerYear` is `na`, the function divides this value by 12 to calculate a
monthly benchmark if the chart's data spans at least two months or 365 for a daily
benchmark if the data otherwise spans at least two days. If `periodsPerYear`
has a specified value, the function divides the rate by that value instead.
    forceCalc (bool): (series bool) If `true`, calculates the ratio on every call. Otherwise, ratio calculation
only occurs on the last available bar. Optional. The default is `false`.
    periodsPerYear (simple int): (simple int) If specified, divides the annual rate by this value instead of the value
determined by the time span of the chart's data.
  Returns: (float) The Sharpe ratio, which estimates the excess return per unit of total volatility.

method sortinoRatio(returnsArray, annualBenchmark, forceCalc, periodsPerYear)
  Calculates the Sortino ratio for an array of periodic returns.
Callable as a method or a function.
  Namespace types: array<float>
  Parameters:
    returnsArray (array<float>): (array<float>) An array of periodic return percentages, e.g., returns over monthly or
daily periods.
    annualBenchmark (float): (series float) The annual rate of return to compare against `returnsArray` values. When
`periodsPerYear` is `na`, the function divides this value by 12 to calculate a
monthly benchmark if the chart's data spans at least two months or 365 for a daily
benchmark if the data otherwise spans at least two days. If `periodsPerYear`
has a specified value, the function divides the rate by that value instead.
    forceCalc (bool): (series bool) If `true`, calculates the ratio on every call. Otherwise, ratio calculation
only occurs on the last available bar. Optional. The default is `false`.
    periodsPerYear (simple int): (simple int) If specified, divides the annual rate by this value instead of the value
determined by the time span of the chart's data.
  Returns: (float) The Sortino ratio, which estimates the excess return per unit of downside
volatility.
Nota Keluaran
v2

This version's release includes updated calculations to align the library with recent changes to the Strategy Tester. The library now uses monthly periodic returns exclusively in its Sharpe and Sortino ratio calculations. Previously, the calculations would use returns from either daily or monthly periods, depending on the span of the chart's data. By using monthly periods consistently, irrespective of the chart's span, the ratios provide a more uniform assessment of risk-adjusted performance across different trading intervals.


Removed:

detectPeriod()
  Determines whether the chart data has sufficient coverage to use monthly or daily returns for risk metric calculations.


ratioriskriskadjustedreturnsriskmangementriskmetricsharpesortinostatisticsvolatilty

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